adrpo@ida-liu050 ~/dev/OpenModelicaNoChanges/build/bin $ time ./omc -bench Model.mos > Model-trace-bug-1466.txt 2>&1 real 67m17.806s user 0m0.015s sys 0m0.000s true "function Modelica.SIunits.Conversions.from_degC input Real Celsius(quantity = "ThermodynamicTemperature", unit = "degC") "Celsius value"; output Real Kelvin(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Kelvin value"; algorithm Kelvin := Celsius - -273.15; end Modelica.SIunits.Conversions.from_degC; function Modelica.SIunits.Conversions.to_degC input Real Kelvin(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Kelvin value"; output Real Celsius(quantity = "ThermodynamicTemperature", unit = "degC") "Celsius value"; algorithm Celsius := -273.15 + Kelvin; end Modelica.SIunits.Conversions.to_degC; class Model parameter Real CABI0CabiA001001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013001001.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259997858 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013001001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013001001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013002001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013002001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013002001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0252000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013003001.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259997984 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013003001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013003001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013004001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998488 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013004001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013004001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013005001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998488 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013005001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013005001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176400126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013006001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013006001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013006001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.03528 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0882 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0882 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0881999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0882000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0882000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0881999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0881999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0882000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0881999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.03528 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013007001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013007001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013007001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013008001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013008001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013008001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013009001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998866 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013009001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013009001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013010001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998866 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013010001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013010001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013011001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013011001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013011001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0125999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013012001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998362 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013012001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013012001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013013001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013013001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013013001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0189 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0945000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0945000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0945 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0945000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0945000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0945 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0945 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.094500063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0945 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0378000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013014001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0188999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013014001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013014001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013015001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013015001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013015001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259993448 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996598 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996598 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996724 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996724 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996976 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.0025199874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013016001.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259991054 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013016001.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013016001.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259997858 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001002002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013002002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001003002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013003002.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259997984 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001004002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013004002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998488 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001005002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013005002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998488 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001006002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013006002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001007002.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013007002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001008002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013008002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001009002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013009002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998866 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001010002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013010002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998866 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001011002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013011002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001012002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013012002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998362 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001013002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013013002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001014002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0189 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013014002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0188999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001015002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013015002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259993448 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996598 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996598 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996724 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996724 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996976 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0025199874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013016002.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259991054 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013016002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013016002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013001005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00125999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013001005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013001005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001002005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013002005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001003005.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013003005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0125999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001004005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013004005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0088199811 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001005005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013005005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0088199811 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001006005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013006005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998362 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001007005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013007005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001008005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013008005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001009005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013009005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001010005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013010005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001011005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013011005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001012005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013012005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999811 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001013005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013013005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001014005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0189 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013014005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0188999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001015005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013015005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259992818 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251998488 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996346 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996724 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013016005.C(quantity = "HeatCapacity", unit = "J/K") = 0.00125999055 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013016005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013016005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000504 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013001004.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259997984 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013001004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013001004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001002004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013002004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001003004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013003004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0125999811 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001004004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013004004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001005004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013005004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001006004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013006004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0088199874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001007004.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013007004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001008004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000504 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013008004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001009004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013009004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998866 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001010004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013010004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998866 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001011004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000504 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013011004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001012004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013012004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998488 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001013004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000504 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013013004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001014004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0189 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013014004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0188999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001015004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000504 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013015004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259993574 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0025199874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996724 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996598 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996724 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996724 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996976 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0025199874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013016004.C(quantity = "HeatCapacity", unit = "J/K") = 0.00125999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013016004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013016004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013001003.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259997732 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013001003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013001003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001002003.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013002003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998866 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001003003.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013003003.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259997858 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001004003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013004003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998362 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001005003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013005003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998362 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001006003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013006003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001007003.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013007003.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001008003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013008003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001009003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013009003.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001010003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013010003.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001011003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013011003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001012003.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013012003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998236 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001013003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013013003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001014003.C(quantity = "HeatCapacity", unit = "J/K") = 0.0189 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013014003.C(quantity = "HeatCapacity", unit = "J/K") = 0.0188999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001015003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013015003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00125999307 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996598 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996598 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996598 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996976 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.0025199874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013016003.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259990928 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013016003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013016003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001001002.C(quantity = "HeatCapacity", unit = "J/K") = 0.00126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001001002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001001002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000504 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013001006.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259997984 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013001006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013001006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001002006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013002006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001003006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013003006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0125999811 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001004006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013004006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001005006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013005006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001006006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00882000378 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013006006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0088199874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001007006.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013007006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001008006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000504 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013008006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001009006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013009006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998866 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001010006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0063 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013010006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998866 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001011006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000504 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013011006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001012006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013012006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998488 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001013006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000504 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013013006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001014006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0189 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013014006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0188999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001015006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00630000504 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013015006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259993574 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0025199874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996724 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996598 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996724 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996724 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996976 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0025199874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013016006.C(quantity = "HeatCapacity", unit = "J/K") = 0.00125999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013016006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013016006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.00252000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.00504000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.00504000252 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013001007.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013001007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013001007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001002007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013002007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259997984 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001003007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0252000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013003007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0251999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001004007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013004007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001005007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01764 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013005007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001006007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176400126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013006007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001007007.C(quantity = "HeatCapacity", unit = "J/K") = 0.03528 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013007007.C(quantity = "HeatCapacity", unit = "J/K") = 0.035279937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001008007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013008007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001009007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013009007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259997732 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001010007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013010007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259997732 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001011007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013011007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001012007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013012007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0125999685 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001013007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013013007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001014007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0378000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013014007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0377999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001015007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0126000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013015007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0025199874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.00503997354 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259993448 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259993322 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0125999307 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259993448 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259993448 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0125999307 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0125999307 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259994078 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0125999307 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.0050399748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013016007.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251998236 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013016007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013016007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013001008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00125999685 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013001008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013001008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259998866 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013002008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998488 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013002008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013002008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0251999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0629999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0629999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0629999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0629999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.062999937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0251999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013003008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259996976 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013003008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013003008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013004008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881997732 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013004008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013004008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013005008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881997732 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013005008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013005008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0441 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0440999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013006008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00881997984 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013006008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013006008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0352799622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0881999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0881999244 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0881999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.088199937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.088199937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0881999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0881999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0881999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0881999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0352799748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013007008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0176399496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013007008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013007008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013008008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013008008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013008008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013009008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998362 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013009008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013009008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259998614 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013010008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998362 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013010008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013010008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013011008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013011008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013011008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629998992 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259997732 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.031499937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.031499937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.031499937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.031499937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0125999811 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013012008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629997858 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013012008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013012008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013013008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013013008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013013008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0188999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0377999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.094499937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.094499937 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0944999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0944999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0944999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0944999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0944999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0944999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0944999118 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0377999748 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013014008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0188999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013014008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013014008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999496 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0315000126 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0314999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.01259999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013015008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999874 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013015008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013015008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA001016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259992314 "Heat capacity of element (= cp*m)"; Real CABI0CabiA001016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA001016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA001016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA001016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA002016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251998488 "Heat capacity of element (= cp*m)"; Real CABI0CabiA002016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA002016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA002016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA002016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA003016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996094 "Heat capacity of element (= cp*m)"; Real CABI0CabiA003016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA003016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA003016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA003016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA004016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996094 "Heat capacity of element (= cp*m)"; Real CABI0CabiA004016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA004016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA004016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA004016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA005016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629995968 "Heat capacity of element (= cp*m)"; Real CABI0CabiA005016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA005016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA005016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA005016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA006016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA006016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA006016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA006016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA006016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA007016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.0062999622 "Heat capacity of element (= cp*m)"; Real CABI0CabiA007016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA007016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA007016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA007016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA008016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629995968 "Heat capacity of element (= cp*m)"; Real CABI0CabiA008016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA008016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA008016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA008016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA009016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629995968 "Heat capacity of element (= cp*m)"; Real CABI0CabiA009016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA009016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA009016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA009016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA010016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629996472 "Heat capacity of element (= cp*m)"; Real CABI0CabiA010016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA010016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA010016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA010016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA011016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00629995968 "Heat capacity of element (= cp*m)"; Real CABI0CabiA011016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA011016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA011016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA011016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA012016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.00251998488 "Heat capacity of element (= cp*m)"; Real CABI0CabiA012016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA012016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA012016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA012016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real CABI0CabiA013016008.C(quantity = "HeatCapacity", unit = "J/K") = 0.001259990046 "Heat capacity of element (= cp*m)"; Real CABI0CabiA013016008.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real CABI0CabiA013016008.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real CABI0CabiA013016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real CABI0CabiA013016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA004005002.C(quantity = "HeatCapacity", unit = "J/K") = 0.071225 "Heat capacity of element (= cp*m)"; Real GS0CabiA004005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA004005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA004005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA004005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA005005002.C(quantity = "HeatCapacity", unit = "J/K") = 0.07122497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA005005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA005005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA005005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA005005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA006005002.C(quantity = "HeatCapacity", unit = "J/K") = 0.071225 "Heat capacity of element (= cp*m)"; Real GS0CabiA006005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA006005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA006005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA006005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA007005002.C(quantity = "HeatCapacity", unit = "J/K") = 0.071225 "Heat capacity of element (= cp*m)"; Real GS0CabiA007005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA007005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA007005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA007005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA008005002.C(quantity = "HeatCapacity", unit = "J/K") = 0.07122497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA008005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA008005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA008005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA008005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA009005002.C(quantity = "HeatCapacity", unit = "J/K") = 0.07122497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA009005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA009005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA009005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA009005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA010005002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0712250407 "Heat capacity of element (= cp*m)"; Real GS0CabiA010005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA010005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA010005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA010005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA011005002.C(quantity = "HeatCapacity", unit = "J/K") = 0.07122497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA011005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA011005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA011005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA011005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA004006002.C(quantity = "HeatCapacity", unit = "J/K") = 0.07122502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA004006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA004006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA004006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA004006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA005006002.C(quantity = "HeatCapacity", unit = "J/K") = 0.071225 "Heat capacity of element (= cp*m)"; Real GS0CabiA005006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA005006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA005006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA005006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA006006002.C(quantity = "HeatCapacity", unit = "J/K") = 0.07122502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA006006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA006006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA006006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA006006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA007006002.C(quantity = "HeatCapacity", unit = "J/K") = 0.07122502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA007006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA007006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA007006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA007006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA008006002.C(quantity = "HeatCapacity", unit = "J/K") = 0.071225 "Heat capacity of element (= cp*m)"; Real GS0CabiA008006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA008006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA008006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA008006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA009006002.C(quantity = "HeatCapacity", unit = "J/K") = 0.071225 "Heat capacity of element (= cp*m)"; Real GS0CabiA009006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA009006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA009006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA009006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA010006002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0712250407 "Heat capacity of element (= cp*m)"; Real GS0CabiA010006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA010006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA010006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA010006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA011006002.C(quantity = "HeatCapacity", unit = "J/K") = 0.071225 "Heat capacity of element (= cp*m)"; Real GS0CabiA011006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA011006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA011006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA011006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA004007002.C(quantity = "HeatCapacity", unit = "J/K") = 0.14245 "Heat capacity of element (= cp*m)"; Real GS0CabiA004007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA004007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA004007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA004007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA005007002.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real GS0CabiA005007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA005007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA005007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA005007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA006007002.C(quantity = "HeatCapacity", unit = "J/K") = 0.14245002035 "Heat capacity of element (= cp*m)"; Real GS0CabiA006007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA006007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA006007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA006007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA007007002.C(quantity = "HeatCapacity", unit = "J/K") = 0.14245002035 "Heat capacity of element (= cp*m)"; Real GS0CabiA007007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA007007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA007007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA007007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA008007002.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real GS0CabiA008007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA008007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA008007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA008007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA009007002.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real GS0CabiA009007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA009007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA009007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA009007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA010007002.C(quantity = "HeatCapacity", unit = "J/K") = 0.14245006105 "Heat capacity of element (= cp*m)"; Real GS0CabiA010007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA010007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA010007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA010007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA011007002.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real GS0CabiA011007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA011007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA011007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA011007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA004008002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA004008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA004008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA004008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA004008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA005008002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA005008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA005008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA005008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA005008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA006008002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0508750407 "Heat capacity of element (= cp*m)"; Real GS0CabiA006008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA006008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA006008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA006008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA007008002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0508750407 "Heat capacity of element (= cp*m)"; Real GS0CabiA007008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA007008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA007008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA007008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA008008002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA008008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA008008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA008008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA008008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA009008002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA009008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA009008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA009008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA009008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA010008002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087506105 "Heat capacity of element (= cp*m)"; Real GS0CabiA010008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA010008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA010008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA010008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA011008002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA011008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA011008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA011008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA011008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA004009002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA004009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA004009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA004009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA004009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA005009002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA005009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA005009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA005009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA005009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA006009002.C(quantity = "HeatCapacity", unit = "J/K") = 0.050875 "Heat capacity of element (= cp*m)"; Real GS0CabiA006009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA006009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA006009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA006009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA007009002.C(quantity = "HeatCapacity", unit = "J/K") = 0.050875 "Heat capacity of element (= cp*m)"; Real GS0CabiA007009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA007009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA007009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA007009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA008009002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA008009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA008009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA008009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA008009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA009009002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA009009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA009009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA009009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA009009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA010009002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA010009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA010009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA010009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA010009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA011009002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA011009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA011009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA011009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA011009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA004010002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA004010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA004010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA004010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA004010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA005010002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA005010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA005010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA005010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA005010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA006010002.C(quantity = "HeatCapacity", unit = "J/K") = 0.050875 "Heat capacity of element (= cp*m)"; Real GS0CabiA006010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA006010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA006010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA006010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA007010002.C(quantity = "HeatCapacity", unit = "J/K") = 0.050875 "Heat capacity of element (= cp*m)"; Real GS0CabiA007010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA007010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA007010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA007010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA008010002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA008010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA008010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA008010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA008010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA009010002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA009010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA009010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA009010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA009010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA010010002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA010010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA010010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA010010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA010010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA011010002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA011010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA011010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA011010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA011010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA004011002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA004011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA004011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA004011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA004011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA005011002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA005011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA005011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA005011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA005011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA006011002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0508750407 "Heat capacity of element (= cp*m)"; Real GS0CabiA006011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA006011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA006011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA006011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA007011002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0508750407 "Heat capacity of element (= cp*m)"; Real GS0CabiA007011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA007011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA007011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA007011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA008011002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA008011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA008011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA008011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA008011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA009011002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA009011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA009011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA009011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA009011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA010011002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087506105 "Heat capacity of element (= cp*m)"; Real GS0CabiA010011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA010011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA010011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA010011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA011011002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA011011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA011011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA011011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA011011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA004012002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0508749593 "Heat capacity of element (= cp*m)"; Real GS0CabiA004012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA004012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA004012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA004012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA005012002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087493895 "Heat capacity of element (= cp*m)"; Real GS0CabiA005012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA005012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA005012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA005012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA006012002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0508749593 "Heat capacity of element (= cp*m)"; Real GS0CabiA006012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA006012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA006012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA006012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA007012002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0508749593 "Heat capacity of element (= cp*m)"; Real GS0CabiA007012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA007012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA007012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA007012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA008012002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087493895 "Heat capacity of element (= cp*m)"; Real GS0CabiA008012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA008012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA008012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA008012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA009012002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087493895 "Heat capacity of element (= cp*m)"; Real GS0CabiA009012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA009012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA009012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA009012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA010012002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA010012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA010012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA010012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA010012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA011012002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087493895 "Heat capacity of element (= cp*m)"; Real GS0CabiA011012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA011012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA011012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA011012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA004013002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA004013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA004013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA004013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA004013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA005013002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA005013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA005013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA005013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA005013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA006013002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0508750407 "Heat capacity of element (= cp*m)"; Real GS0CabiA006013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA006013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA006013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA006013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA007013002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0508750407 "Heat capacity of element (= cp*m)"; Real GS0CabiA007013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA007013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA007013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA007013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA008013002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA008013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA008013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA008013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA008013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA009013002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA009013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA009013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA009013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA009013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA010013002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087506105 "Heat capacity of element (= cp*m)"; Real GS0CabiA010013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA010013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA010013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA010013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA011013002.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real GS0CabiA011013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA011013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA011013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA011013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA004004002.C(quantity = "HeatCapacity", unit = "J/K") = 0.071225 "Heat capacity of element (= cp*m)"; Real GS0CabiA004004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA004004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA004004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA004004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA005004002.C(quantity = "HeatCapacity", unit = "J/K") = 0.07122497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA005004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA005004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA005004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA005004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA006004002.C(quantity = "HeatCapacity", unit = "J/K") = 0.071225 "Heat capacity of element (= cp*m)"; Real GS0CabiA006004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA006004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA006004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA006004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA007004002.C(quantity = "HeatCapacity", unit = "J/K") = 0.071225 "Heat capacity of element (= cp*m)"; Real GS0CabiA007004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA007004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA007004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA007004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA008004002.C(quantity = "HeatCapacity", unit = "J/K") = 0.07122497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA008004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA008004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA008004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA008004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA009004002.C(quantity = "HeatCapacity", unit = "J/K") = 0.07122497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA009004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA009004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA009004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA009004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA010004002.C(quantity = "HeatCapacity", unit = "J/K") = 0.0712250407 "Heat capacity of element (= cp*m)"; Real GS0CabiA010004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA010004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA010004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA010004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real GS0CabiA011004002.C(quantity = "HeatCapacity", unit = "J/K") = 0.07122497965 "Heat capacity of element (= cp*m)"; Real GS0CabiA011004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real GS0CabiA011004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real GS0CabiA011004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real GS0CabiA011004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002015007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003015007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004015007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005015007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006015007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007015007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008015007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009015007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010015007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880007056e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011015007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012015007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012015007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012015007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002014007.C(quantity = "HeatCapacity", unit = "J/K") = 7.056e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003014007.C(quantity = "HeatCapacity", unit = "J/K") = 1.764e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004014007.C(quantity = "HeatCapacity", unit = "J/K") = 1.764e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005014007.C(quantity = "HeatCapacity", unit = "J/K") = 1.764e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006014007.C(quantity = "HeatCapacity", unit = "J/K") = 1.764001176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007014007.C(quantity = "HeatCapacity", unit = "J/K") = 1.764001176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008014007.C(quantity = "HeatCapacity", unit = "J/K") = 1.764e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009014007.C(quantity = "HeatCapacity", unit = "J/K") = 1.764e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010014007.C(quantity = "HeatCapacity", unit = "J/K") = 1.764001176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011014007.C(quantity = "HeatCapacity", unit = "J/K") = 1.764e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012014007.C(quantity = "HeatCapacity", unit = "J/K") = 7.056003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012014007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012014007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002007007.C(quantity = "HeatCapacity", unit = "J/K") = 6.5856e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003007007.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004007007.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005007007.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006007007.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007007007.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008007007.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009007007.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010007007.C(quantity = "HeatCapacity", unit = "J/K") = 1.646401176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011007007.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012007007.C(quantity = "HeatCapacity", unit = "J/K") = 6.585602352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012007007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012007007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002008007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003008007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004008007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005008007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006008007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007008007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008008007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009008007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010008007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880007056e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011008007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012008007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012008007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012008007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002009007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003009007.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004009007.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005009007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006009007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007009007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008009007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009009007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010009007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011009007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012009007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012009007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012009007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002010007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003010007.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004010007.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005010007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006010007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007010007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008010007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009010007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010010007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011010007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012010007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012010007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012010007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002011007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003011007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004011007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005011007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006011007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007011007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008011007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009011007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010011007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880007056e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011011007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012011007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012011007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012011007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002012007.C(quantity = "HeatCapacity", unit = "J/K") = 2.351997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003012007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879995296e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004012007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879995296e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005012007.C(quantity = "HeatCapacity", unit = "J/K") = 5.87999412e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006012007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007012007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008012007.C(quantity = "HeatCapacity", unit = "J/K") = 5.87999412e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009012007.C(quantity = "HeatCapacity", unit = "J/K") = 5.87999412e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010012007.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011012007.C(quantity = "HeatCapacity", unit = "J/K") = 5.87999412e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012012007.C(quantity = "HeatCapacity", unit = "J/K") = 2.351998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012012007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012012007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002013007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003013007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004013007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005013007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006013007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007013007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008013007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009013007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010013007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880007056e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011013007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012013007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012013007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012013007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002002007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003002007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004002007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005002007.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006002007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007002007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008002007.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009002007.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010002007.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011002007.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012002007.C(quantity = "HeatCapacity", unit = "J/K") = 2.352001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012002007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012002007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002003007.C(quantity = "HeatCapacity", unit = "J/K") = 4.704001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003003007.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004003007.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005003007.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006003007.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007003007.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008003007.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009003007.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010003007.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011003007.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-07 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012003007.C(quantity = "HeatCapacity", unit = "J/K") = 4.704002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012003007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012003007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002004007.C(quantity = "HeatCapacity", unit = "J/K") = 3.2928e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003004007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004004007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005004007.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006004007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007004007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008004007.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009004007.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010004007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011004007.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012004007.C(quantity = "HeatCapacity", unit = "J/K") = 3.292801176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012004007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012004007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002005007.C(quantity = "HeatCapacity", unit = "J/K") = 3.2928e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003005007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004005007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005005007.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006005007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007005007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008005007.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009005007.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010005007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011005007.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012005007.C(quantity = "HeatCapacity", unit = "J/K") = 3.292801176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012005007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012005007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002006007.C(quantity = "HeatCapacity", unit = "J/K") = 3.292801176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003006007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004006007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005006007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006006007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007006007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008006007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009006007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010006007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232007056e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011006007.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012006007.C(quantity = "HeatCapacity", unit = "J/K") = 3.292801176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012006007.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012006007.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011009006.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012009006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002010006.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003010006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004010006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005010006.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006010006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007010006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011010006.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012010006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002011006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003011006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007011006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011011006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012011006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002012006.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759989416e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003012006.C(quantity = "HeatCapacity", unit = "J/K") = 2.939997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007012006.C(quantity = "HeatCapacity", unit = "J/K") = 2.939997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008012006.C(quantity = "HeatCapacity", unit = "J/K") = 2.939996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009012006.C(quantity = "HeatCapacity", unit = "J/K") = 2.939996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010012006.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011012006.C(quantity = "HeatCapacity", unit = "J/K") = 2.939996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012012006.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759992944e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002013006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003013006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007013006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008013006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009013006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010013006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011013006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012013006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002014006.C(quantity = "HeatCapacity", unit = "J/K") = 3.528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003014006.C(quantity = "HeatCapacity", unit = "J/K") = 8.820002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004014006.C(quantity = "HeatCapacity", unit = "J/K") = 8.820002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005014006.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006014006.C(quantity = "HeatCapacity", unit = "J/K") = 8.820003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007014006.C(quantity = "HeatCapacity", unit = "J/K") = 8.820003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008014006.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009014006.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010014006.C(quantity = "HeatCapacity", unit = "J/K") = 8.82000588e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011014006.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012014006.C(quantity = "HeatCapacity", unit = "J/K") = 3.528001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012014006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012014006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002015006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003015006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004015006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005015006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006015006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007015006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008015006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009015006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010015006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011015006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012015006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012015006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012015006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010005006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011005006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012005006.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002006006.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003006006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004006006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005006006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010006006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011006006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012006006.C(quantity = "HeatCapacity", unit = "J/K") = 1.646401176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002007006.C(quantity = "HeatCapacity", unit = "J/K") = 3.2928e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003007006.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004007006.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005007006.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006007006.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007007006.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008007006.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009007006.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010007006.C(quantity = "HeatCapacity", unit = "J/K") = 8.232004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011007006.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012007006.C(quantity = "HeatCapacity", unit = "J/K") = 3.292801176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012007006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012007006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002008006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003008006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004008006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005008006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006008006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007008006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008008006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009008006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010008006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011008006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012008006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012008006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012008006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002009006.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003009006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004009006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005009006.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006009006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007009006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002002006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003002006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004002006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005002006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006002006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007002006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008002006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009002006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010002006.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011002006.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012002006.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012002006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012002006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002003006.C(quantity = "HeatCapacity", unit = "J/K") = 2.352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003003006.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004003006.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005003006.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006003006.C(quantity = "HeatCapacity", unit = "J/K") = 5.880002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007003006.C(quantity = "HeatCapacity", unit = "J/K") = 5.880002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008003006.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009003006.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010003006.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011003006.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012003006.C(quantity = "HeatCapacity", unit = "J/K") = 2.352001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012003006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012003006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002004006.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003004006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004004006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005004006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010004006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011004006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012004006.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002005006.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003005006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004005006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005005006.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002002005.C(quantity = "HeatCapacity", unit = "J/K") = 1.175999412e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003002005.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004002005.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005002005.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006002005.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007002005.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008002005.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009002005.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010002005.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011002005.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012002005.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012002005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012002005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002003005.C(quantity = "HeatCapacity", unit = "J/K") = 2.351998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012003005.C(quantity = "HeatCapacity", unit = "J/K") = 2.352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002004005.C(quantity = "HeatCapacity", unit = "J/K") = 1.646398824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012004005.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002005005.C(quantity = "HeatCapacity", unit = "J/K") = 1.646398824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012005005.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002006005.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012006005.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002007005.C(quantity = "HeatCapacity", unit = "J/K") = 3.292798824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012007005.C(quantity = "HeatCapacity", unit = "J/K") = 3.292798824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002008005.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012008005.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002009005.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759992944e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012009005.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759995296e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002010005.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759992944e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012010005.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759995296e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002011005.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012011005.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002012005.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759984712e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012012005.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759987064e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002013005.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012013005.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002014005.C(quantity = "HeatCapacity", unit = "J/K") = 3.527998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012014005.C(quantity = "HeatCapacity", unit = "J/K") = 3.528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002015005.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003015005.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004015005.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005015005.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006015005.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007015005.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008015005.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009015005.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010015005.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011015005.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012015005.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012015005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012015005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002002004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003002004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004002004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005002004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006002004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007002004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008002004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009002004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010002004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011002004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012002004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012002004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012002004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002003004.C(quantity = "HeatCapacity", unit = "J/K") = 2.352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003003004.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004003004.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005003004.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006003004.C(quantity = "HeatCapacity", unit = "J/K") = 5.880002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007003004.C(quantity = "HeatCapacity", unit = "J/K") = 5.880002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008003004.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009003004.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010003004.C(quantity = "HeatCapacity", unit = "J/K") = 5.880004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011003004.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012003004.C(quantity = "HeatCapacity", unit = "J/K") = 2.352001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012003004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012003004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002004004.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003004004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008004004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009004004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010004004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011004004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012004004.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002005004.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003005004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008005004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009005004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010005004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011005004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012005004.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002006004.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003006004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008006004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009006004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010006004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011006004.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012006004.C(quantity = "HeatCapacity", unit = "J/K") = 1.646401176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002007004.C(quantity = "HeatCapacity", unit = "J/K") = 3.2928e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003007004.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004007004.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005007004.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006007004.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007007004.C(quantity = "HeatCapacity", unit = "J/K") = 8.232001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008007004.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009007004.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010007004.C(quantity = "HeatCapacity", unit = "J/K") = 8.232004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011007004.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012007004.C(quantity = "HeatCapacity", unit = "J/K") = 3.292801176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012007004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012007004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002008004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003008004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004008004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005008004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006008004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007008004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011008004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012008004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002009004.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003009004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004009004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005009004.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006009004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007009004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011009004.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012009004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002010004.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003010004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004010004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005010004.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006010004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007010004.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011010004.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012010004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002011004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003011004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007011004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008011004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009011004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010011004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011011004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012011004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002012004.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759989416e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003012004.C(quantity = "HeatCapacity", unit = "J/K") = 2.939997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007012004.C(quantity = "HeatCapacity", unit = "J/K") = 2.939997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008012004.C(quantity = "HeatCapacity", unit = "J/K") = 2.939996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009012004.C(quantity = "HeatCapacity", unit = "J/K") = 2.939996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010012004.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011012004.C(quantity = "HeatCapacity", unit = "J/K") = 2.939996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012012004.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759992944e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002013004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003013004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007013004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008013004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009013004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010013004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011013004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012013004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002014004.C(quantity = "HeatCapacity", unit = "J/K") = 3.528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003014004.C(quantity = "HeatCapacity", unit = "J/K") = 8.820002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004014004.C(quantity = "HeatCapacity", unit = "J/K") = 8.820002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005014004.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006014004.C(quantity = "HeatCapacity", unit = "J/K") = 8.820003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007014004.C(quantity = "HeatCapacity", unit = "J/K") = 8.820003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008014004.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009014004.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010014004.C(quantity = "HeatCapacity", unit = "J/K") = 8.82000588e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011014004.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012014004.C(quantity = "HeatCapacity", unit = "J/K") = 3.528001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012014004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012014004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002015004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003015004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004015004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005015004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006015004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007015004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008015004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009015004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010015004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011015004.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012015004.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012015004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012015004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002002003.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003002003.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004002003.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005002003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006002003.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007002003.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008002003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009002003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010002003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011002003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012002003.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012002003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012002003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002003003.C(quantity = "HeatCapacity", unit = "J/K") = 2.352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003003003.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004003003.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005003003.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006003003.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007003003.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008003003.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009003003.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010003003.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011003003.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012003003.C(quantity = "HeatCapacity", unit = "J/K") = 2.352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012003003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012003003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002004003.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003004003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004004003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005004003.C(quantity = "HeatCapacity", unit = "J/K") = 4.115998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006004003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007004003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008004003.C(quantity = "HeatCapacity", unit = "J/K") = 4.115998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009004003.C(quantity = "HeatCapacity", unit = "J/K") = 4.115998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010004003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011004003.C(quantity = "HeatCapacity", unit = "J/K") = 4.115998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012004003.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012004003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012004003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002005003.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003005003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004005003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005005003.C(quantity = "HeatCapacity", unit = "J/K") = 4.115998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006005003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007005003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008005003.C(quantity = "HeatCapacity", unit = "J/K") = 4.115998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009005003.C(quantity = "HeatCapacity", unit = "J/K") = 4.115998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010005003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011005003.C(quantity = "HeatCapacity", unit = "J/K") = 4.115998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012005003.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012005003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012005003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002006003.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003006003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004006003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005006003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006006003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007006003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008006003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009006003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010006003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011006003.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012006003.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012006003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012006003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002007003.C(quantity = "HeatCapacity", unit = "J/K") = 3.292798824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003007003.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004007003.C(quantity = "HeatCapacity", unit = "J/K") = 8.231998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005007003.C(quantity = "HeatCapacity", unit = "J/K") = 8.231997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006007003.C(quantity = "HeatCapacity", unit = "J/K") = 8.232e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007007003.C(quantity = "HeatCapacity", unit = "J/K") = 8.232e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008007003.C(quantity = "HeatCapacity", unit = "J/K") = 8.231997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009007003.C(quantity = "HeatCapacity", unit = "J/K") = 8.231997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010007003.C(quantity = "HeatCapacity", unit = "J/K") = 8.232003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011007003.C(quantity = "HeatCapacity", unit = "J/K") = 8.231997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012007003.C(quantity = "HeatCapacity", unit = "J/K") = 3.2928e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012007003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012007003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002008003.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003008003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004008003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005008003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006008003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007008003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011008003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012008003.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002009003.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759995296e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003009003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004009003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005009003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006009003.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007009003.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011009003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012009003.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002010003.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759995296e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003010003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004010003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005010003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006010003.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007010003.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011010003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012010003.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002011003.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003011003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004011003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005011003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006011003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007011003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008011003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009011003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010011003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011011003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012011003.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012011003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012011003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002012003.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759987064e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003012003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004012003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005012003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006012003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007012003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008012003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009012003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010012003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011012003.C(quantity = "HeatCapacity", unit = "J/K") = 2.939996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012012003.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759990592e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012012003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012012003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002013003.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003013003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004013003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005013003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006013003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007013003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008013003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009013003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010013003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011013003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012013003.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012013003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012013003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002014003.C(quantity = "HeatCapacity", unit = "J/K") = 3.528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003014003.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004014003.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005014003.C(quantity = "HeatCapacity", unit = "J/K") = 8.819997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006014003.C(quantity = "HeatCapacity", unit = "J/K") = 8.820001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007014003.C(quantity = "HeatCapacity", unit = "J/K") = 8.820001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008014003.C(quantity = "HeatCapacity", unit = "J/K") = 8.819997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009014003.C(quantity = "HeatCapacity", unit = "J/K") = 8.819997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010014003.C(quantity = "HeatCapacity", unit = "J/K") = 8.820004704e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011014003.C(quantity = "HeatCapacity", unit = "J/K") = 8.819997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012014003.C(quantity = "HeatCapacity", unit = "J/K") = 3.528001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012014003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012014003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002015003.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003015003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004015003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005015003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006015003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007015003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008015003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009015003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010015003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011015003.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012015003.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012015003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012015003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012005002.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002006002.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003006002.C(quantity = "HeatCapacity", unit = "J/K") = 4.116001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012006002.C(quantity = "HeatCapacity", unit = "J/K") = 1.646401176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012006002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012006002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002007002.C(quantity = "HeatCapacity", unit = "J/K") = 3.2928e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003007002.C(quantity = "HeatCapacity", unit = "J/K") = 8.232e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012007002.C(quantity = "HeatCapacity", unit = "J/K") = 3.2928e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012007002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012007002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002008002.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003008002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012008002.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012008002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012008002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002009002.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003009002.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012009002.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012009002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012009002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002010002.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759996472e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003010002.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012010002.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012010002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012010002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002011002.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003011002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012011002.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012011002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012011002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002012002.C(quantity = "HeatCapacity", unit = "J/K") = 1.175998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003012002.C(quantity = "HeatCapacity", unit = "J/K") = 2.939997648e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012012002.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759991768e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012012002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012012002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002013002.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003013002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012013002.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012013002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012013002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002014002.C(quantity = "HeatCapacity", unit = "J/K") = 3.528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003014002.C(quantity = "HeatCapacity", unit = "J/K") = 8.820002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004014002.C(quantity = "HeatCapacity", unit = "J/K") = 8.820001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005014002.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006014002.C(quantity = "HeatCapacity", unit = "J/K") = 8.820002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007014002.C(quantity = "HeatCapacity", unit = "J/K") = 8.820002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008014002.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009014002.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010014002.C(quantity = "HeatCapacity", unit = "J/K") = 8.82000588e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011014002.C(quantity = "HeatCapacity", unit = "J/K") = 8.82e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012014002.C(quantity = "HeatCapacity", unit = "J/K") = 3.528001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012014002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012014002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002015002.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003015002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004015002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005015002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006015002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007015002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940002352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008015002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009015002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010015002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011015002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012015002.C(quantity = "HeatCapacity", unit = "J/K") = 1.176001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012015002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012015002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002004002.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003004002.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012004002.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012004002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012004002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002005002.C(quantity = "HeatCapacity", unit = "J/K") = 1.6464e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003005002.C(quantity = "HeatCapacity", unit = "J/K") = 4.116e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003005002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003005002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002003002.C(quantity = "HeatCapacity", unit = "J/K") = 2.352e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003003002.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004003002.C(quantity = "HeatCapacity", unit = "J/K") = 5.88e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005003002.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006003002.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007003002.C(quantity = "HeatCapacity", unit = "J/K") = 5.880001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008003002.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009003002.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010003002.C(quantity = "HeatCapacity", unit = "J/K") = 5.880003528e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011003002.C(quantity = "HeatCapacity", unit = "J/K") = 5.879998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012003002.C(quantity = "HeatCapacity", unit = "J/K") = 2.352001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012003002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012003002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA002002002.C(quantity = "HeatCapacity", unit = "J/K") = 1.1759998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA002002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA002002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA002002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA002002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA003002002.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA003002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA003002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA003002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA003002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA004002002.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA004002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA004002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA004002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA004002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA005002002.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA005002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA005002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA005002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA005002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA006002002.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA006002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA006002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA006002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA006002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA007002002.C(quantity = "HeatCapacity", unit = "J/K") = 2.94e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA007002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA007002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA007002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA007002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA008002002.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA008002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA008002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA008002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA008002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA009002002.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA009002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA009002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA009002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA009002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA010002002.C(quantity = "HeatCapacity", unit = "J/K") = 2.940001176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA010002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA010002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA010002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA010002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA011002002.C(quantity = "HeatCapacity", unit = "J/K") = 2.939998824e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA011002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA011002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA011002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA011002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real AIR0CabiA012002002.C(quantity = "HeatCapacity", unit = "J/K") = 1.176e-08 "Heat capacity of element (= cp*m)"; Real AIR0CabiA012002002.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real AIR0CabiA012002002.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real AIR0CabiA012002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real AIR0CabiA012002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real ST0CabiA008008003.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real ST0CabiA008008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real ST0CabiA008008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real ST0CabiA008008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real ST0CabiA008008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real ST0CabiA009008003.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real ST0CabiA009008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real ST0CabiA009008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real ST0CabiA009008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real ST0CabiA009008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real ST0CabiA010008003.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087506105 "Heat capacity of element (= cp*m)"; Real ST0CabiA010008003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real ST0CabiA010008003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real ST0CabiA010008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real ST0CabiA010008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real ST0CabiA008009003.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real ST0CabiA008009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real ST0CabiA008009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real ST0CabiA008009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real ST0CabiA008009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real ST0CabiA009009003.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real ST0CabiA009009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real ST0CabiA009009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real ST0CabiA009009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real ST0CabiA009009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real ST0CabiA010009003.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real ST0CabiA010009003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real ST0CabiA010009003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real ST0CabiA010009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real ST0CabiA010009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real ST0CabiA008010003.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real ST0CabiA008010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real ST0CabiA008010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real ST0CabiA008010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real ST0CabiA008010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real ST0CabiA009010003.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087497965 "Heat capacity of element (= cp*m)"; Real ST0CabiA009010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real ST0CabiA009010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real ST0CabiA009010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real ST0CabiA009010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real ST0CabiA010010003.C(quantity = "HeatCapacity", unit = "J/K") = 0.05087502035 "Heat capacity of element (= cp*m)"; Real ST0CabiA010010003.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real ST0CabiA010010003.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real ST0CabiA010010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real ST0CabiA010010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA004004004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924 "Heat capacity of element (= cp*m)"; Real IC30CabiA004004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA004004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA004004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA004004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA005004004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924 "Heat capacity of element (= cp*m)"; Real IC30CabiA005004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA005004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA005004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA005004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA006004004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000264 "Heat capacity of element (= cp*m)"; Real IC30CabiA006004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA006004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA006004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA006004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA007004004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000264 "Heat capacity of element (= cp*m)"; Real IC30CabiA007004004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA007004004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA007004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA007004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA004005004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924 "Heat capacity of element (= cp*m)"; Real IC30CabiA004005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA004005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA004005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA004005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA005005004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924 "Heat capacity of element (= cp*m)"; Real IC30CabiA005005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA005005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA005005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA005005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA006005004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000264 "Heat capacity of element (= cp*m)"; Real IC30CabiA006005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA006005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA006005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA006005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA007005004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000264 "Heat capacity of element (= cp*m)"; Real IC30CabiA007005004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA007005004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA007005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA007005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA004006004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000264 "Heat capacity of element (= cp*m)"; Real IC30CabiA004006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA004006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA004006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA004006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA005006004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924 "Heat capacity of element (= cp*m)"; Real IC30CabiA005006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA005006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA005006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA005006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA006006004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000528 "Heat capacity of element (= cp*m)"; Real IC30CabiA006006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA006006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA006006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA006006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC30CabiA007006004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000528 "Heat capacity of element (= cp*m)"; Real IC30CabiA007006004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC30CabiA007006004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC30CabiA007006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC30CabiA007006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC20CabiA008008004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC20CabiA008008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC20CabiA008008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC20CabiA008008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC20CabiA008008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC20CabiA009008004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC20CabiA009008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC20CabiA009008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC20CabiA009008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC20CabiA009008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC20CabiA010008004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000792 "Heat capacity of element (= cp*m)"; Real IC20CabiA010008004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC20CabiA010008004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC20CabiA010008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC20CabiA010008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC20CabiA008009004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999736 "Heat capacity of element (= cp*m)"; Real IC20CabiA008009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC20CabiA008009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC20CabiA008009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC20CabiA008009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC20CabiA009009004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999736 "Heat capacity of element (= cp*m)"; Real IC20CabiA009009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC20CabiA009009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC20CabiA009009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC20CabiA009009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC20CabiA010009004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC20CabiA010009004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC20CabiA010009004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC20CabiA010009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC20CabiA010009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC20CabiA008010004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999736 "Heat capacity of element (= cp*m)"; Real IC20CabiA008010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC20CabiA008010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC20CabiA008010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC20CabiA008010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC20CabiA009010004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999736 "Heat capacity of element (= cp*m)"; Real IC20CabiA009010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC20CabiA009010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC20CabiA009010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC20CabiA009010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC20CabiA010010004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC20CabiA010010004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC20CabiA010010004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC20CabiA010010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC20CabiA010010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC60CabiA004011004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000528 "Heat capacity of element (= cp*m)"; Real IC60CabiA004011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC60CabiA004011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC60CabiA004011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC60CabiA004011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC60CabiA005011004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC60CabiA005011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC60CabiA005011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC60CabiA005011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC60CabiA005011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC60CabiA006011004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000528 "Heat capacity of element (= cp*m)"; Real IC60CabiA006011004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC60CabiA006011004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC60CabiA006011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC60CabiA006011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC60CabiA004012004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999472 "Heat capacity of element (= cp*m)"; Real IC60CabiA004012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC60CabiA004012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC60CabiA004012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC60CabiA004012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC60CabiA005012004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999208 "Heat capacity of element (= cp*m)"; Real IC60CabiA005012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC60CabiA005012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC60CabiA005012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC60CabiA005012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC60CabiA006012004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999472 "Heat capacity of element (= cp*m)"; Real IC60CabiA006012004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC60CabiA006012004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC60CabiA006012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC60CabiA006012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC60CabiA004013004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000528 "Heat capacity of element (= cp*m)"; Real IC60CabiA004013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC60CabiA004013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC60CabiA004013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC60CabiA004013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC60CabiA005013004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC60CabiA005013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC60CabiA005013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC60CabiA005013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC60CabiA005013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC60CabiA006013004.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000528 "Heat capacity of element (= cp*m)"; Real IC60CabiA006013004.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC60CabiA006013004.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC60CabiA006013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC60CabiA006013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003011005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004011005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005011005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006011005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007011005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008011005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009011005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010011005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500814 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011011005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011011005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011011005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003012005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017498779 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004012005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017498779 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005012005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017498372 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006012005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017498779 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007012005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017498779 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008012005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017498372 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009012005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017498372 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010012005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011012005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017498372 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011012005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011012005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003013005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004013005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005013005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006013005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007013005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008013005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009013005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010013005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500814 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011013005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011013005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011013005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003014005.C(quantity = "HeatCapacity", unit = "J/K") = 0.3052499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004014005.C(quantity = "HeatCapacity", unit = "J/K") = 0.3052499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005014005.C(quantity = "HeatCapacity", unit = "J/K") = 0.3052498779 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006014005.C(quantity = "HeatCapacity", unit = "J/K") = 0.30525 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007014005.C(quantity = "HeatCapacity", unit = "J/K") = 0.30525 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008014005.C(quantity = "HeatCapacity", unit = "J/K") = 0.3052498779 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009014005.C(quantity = "HeatCapacity", unit = "J/K") = 0.3052498779 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010014005.C(quantity = "HeatCapacity", unit = "J/K") = 0.3052500814 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011014005.C(quantity = "HeatCapacity", unit = "J/K") = 0.3052498779 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011014005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011014005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003006005.C(quantity = "HeatCapacity", unit = "J/K") = 0.14245 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004006005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005006005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006006005.C(quantity = "HeatCapacity", unit = "J/K") = 0.14245 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007006005.C(quantity = "HeatCapacity", unit = "J/K") = 0.14245 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008006005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009006005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010006005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011006005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011006005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011006005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003007005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2848998779 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004007005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2848998779 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005007005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2848998372 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006007005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2848999186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007007005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2848999186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008007005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2848998372 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009007005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2848998372 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010007005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2849000407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011007005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2848998372 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011007005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011007005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003008005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004008005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005008005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006008005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007008005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008008005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009008005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010008005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017500814 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011008005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011008005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011008005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003009005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004009005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005009005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006009005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007009005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008009005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009009005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010009005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011009005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011009005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011009005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003010005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004010005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005010005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006010005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007010005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008010005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009010005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010010005.C(quantity = "HeatCapacity", unit = "J/K") = 0.10175 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011010005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1017499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011010005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011010005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003003005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2034999593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004003005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2034999593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005003005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2034999186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006003005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2035 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007003005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2035 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008003005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2034999186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009003005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2034999186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010003005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2035000407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011003005.C(quantity = "HeatCapacity", unit = "J/K") = 0.2034999186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011003005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011003005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003004005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004004005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005004005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006004005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007004005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008004005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009004005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010004005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011004005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011004005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011004005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA003005005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA003005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA003005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA003005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA003005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA004005005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA004005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA004005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA004005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA004005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA005005005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA005005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA005005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA005005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA005005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA006005005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA006005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA006005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA006005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA006005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA007005005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499593 "Heat capacity of element (= cp*m)"; Real PWB0CabiA007005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA007005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA007005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA007005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA008005005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA008005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA008005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA008005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA008005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA009005005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA009005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA009005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA009005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA009005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA010005005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424500407 "Heat capacity of element (= cp*m)"; Real PWB0CabiA010005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA010005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA010005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA010005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real PWB0CabiA011005005.C(quantity = "HeatCapacity", unit = "J/K") = 0.1424499186 "Heat capacity of element (= cp*m)"; Real PWB0CabiA011005005.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real PWB0CabiA011005005.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real PWB0CabiA011005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real PWB0CabiA011005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA006004006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000264 "Heat capacity of element (= cp*m)"; Real IC50CabiA006004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA006004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA006004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA006004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA007004006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000264 "Heat capacity of element (= cp*m)"; Real IC50CabiA007004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA007004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA007004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA007004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA008004006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924 "Heat capacity of element (= cp*m)"; Real IC50CabiA008004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA008004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA008004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA008004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA009004006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924 "Heat capacity of element (= cp*m)"; Real IC50CabiA009004006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA009004006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA009004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA009004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA006005006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000264 "Heat capacity of element (= cp*m)"; Real IC50CabiA006005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA006005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA006005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA006005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA007005006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000264 "Heat capacity of element (= cp*m)"; Real IC50CabiA007005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA007005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA007005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA007005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA008005006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924 "Heat capacity of element (= cp*m)"; Real IC50CabiA008005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA008005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA008005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA008005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA009005006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924 "Heat capacity of element (= cp*m)"; Real IC50CabiA009005006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA009005006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA009005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA009005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA006006006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000528 "Heat capacity of element (= cp*m)"; Real IC50CabiA006006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA006006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA006006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA006006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA007006006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924000528 "Heat capacity of element (= cp*m)"; Real IC50CabiA007006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA007006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA007006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA007006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA008006006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924 "Heat capacity of element (= cp*m)"; Real IC50CabiA008006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA008006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA008006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA008006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC50CabiA009006006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0924 "Heat capacity of element (= cp*m)"; Real IC50CabiA009006006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC50CabiA009006006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC50CabiA009006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC50CabiA009006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC40CabiA008009006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999736 "Heat capacity of element (= cp*m)"; Real IC40CabiA008009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC40CabiA008009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC40CabiA008009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC40CabiA008009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC40CabiA009009006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999736 "Heat capacity of element (= cp*m)"; Real IC40CabiA009009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC40CabiA009009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC40CabiA009009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC40CabiA009009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC40CabiA010009006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC40CabiA010009006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC40CabiA010009006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC40CabiA010009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC40CabiA010009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC40CabiA008010006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999736 "Heat capacity of element (= cp*m)"; Real IC40CabiA008010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC40CabiA008010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC40CabiA008010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC40CabiA008010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC40CabiA009010006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999736 "Heat capacity of element (= cp*m)"; Real IC40CabiA009010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC40CabiA009010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC40CabiA009010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC40CabiA009010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC40CabiA010010006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC40CabiA010010006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC40CabiA010010006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC40CabiA010010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC40CabiA010010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC40CabiA008011006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC40CabiA008011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC40CabiA008011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC40CabiA008011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC40CabiA008011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC40CabiA009011006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC40CabiA009011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC40CabiA009011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC40CabiA009011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC40CabiA009011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC40CabiA010011006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000792 "Heat capacity of element (= cp*m)"; Real IC40CabiA010011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC40CabiA010011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC40CabiA010011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC40CabiA010011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC10CabiA004011006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000528 "Heat capacity of element (= cp*m)"; Real IC10CabiA004011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC10CabiA004011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC10CabiA004011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC10CabiA004011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC10CabiA005011006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC10CabiA005011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC10CabiA005011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC10CabiA005011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC10CabiA005011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC10CabiA006011006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000528 "Heat capacity of element (= cp*m)"; Real IC10CabiA006011006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC10CabiA006011006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC10CabiA006011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC10CabiA006011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC10CabiA004012006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999472 "Heat capacity of element (= cp*m)"; Real IC10CabiA004012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC10CabiA004012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC10CabiA004012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC10CabiA004012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC10CabiA005012006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999208 "Heat capacity of element (= cp*m)"; Real IC10CabiA005012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC10CabiA005012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC10CabiA005012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC10CabiA005012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC10CabiA006012006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0659999472 "Heat capacity of element (= cp*m)"; Real IC10CabiA006012006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC10CabiA006012006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC10CabiA006012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC10CabiA006012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC10CabiA004013006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000528 "Heat capacity of element (= cp*m)"; Real IC10CabiA004013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC10CabiA004013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC10CabiA004013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC10CabiA004013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC10CabiA005013006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000264 "Heat capacity of element (= cp*m)"; Real IC10CabiA005013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC10CabiA005013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC10CabiA005013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC10CabiA005013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real IC10CabiA006013006.C(quantity = "HeatCapacity", unit = "J/K") = 0.0660000528 "Heat capacity of element (= cp*m)"; Real IC10CabiA006013006.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0, start = 298.15) "Temperature of element"; Real IC10CabiA006013006.der_T(quantity = "TemperatureSlope", unit = "K/s", start = 0.0) "Time derivative of temperature (= der(T))"; Real IC10CabiA006013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real IC10CabiA006013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1_2.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1_2.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1_2.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1_2.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1_2.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1_2.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1_2.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199985867721872 "Constant thermal conductance of material"; Real TC_1_14.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1_14.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1_14.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1_14.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1_14.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1_14.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1_14.G(quantity = "ThermalConductance", unit = "W/K") = 9.99982633461845e-05 "Constant thermal conductance of material"; Real TC_1_424.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1_424.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1_424.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1_424.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1_424.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1_424.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1_424.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299942124844967 "Constant thermal conductance of material"; Real TC_2_3.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_2_3.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_2_3.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_2_3.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_2_3.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_2_3.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_2_3.G(quantity = "ThermalConductance", unit = "W/K") = 8.57142857142861e-05 "Constant thermal conductance of material"; Real TC_2_15.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_2_15.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_2_15.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_2_15.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_2_15.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_2_15.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_2_15.G(quantity = "ThermalConductance", unit = "W/K") = 0.00020000279724192 "Constant thermal conductance of material"; Real TC_2_209.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_2_209.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_2_209.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_2_209.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_2_209.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_2_209.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_2_209.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599881656804703 "Constant thermal conductance of material"; Real TC_3_4.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_3_4.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_3_4.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_3_4.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_3_4.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_3_4.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_3_4.G(quantity = "ThermalConductance", unit = "W/K") = 6.00013425747225e-05 "Constant thermal conductance of material"; Real TC_3_16.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_3_16.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_3_16.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_3_16.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_3_16.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_3_16.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_3_16.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499999999999999 "Constant thermal conductance of material"; Real TC_3_210.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_3_210.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_3_210.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_3_210.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_3_210.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_3_210.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_3_210.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149995404834117 "Constant thermal conductance of material"; Real TC_4_5.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_4_5.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_4_5.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_4_5.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_4_5.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_4_5.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_4_5.G(quantity = "ThermalConductance", unit = "W/K") = 5.99993184993357e-05 "Constant thermal conductance of material"; Real TC_4_17.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_4_17.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_4_17.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_4_17.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_4_17.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_4_17.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_4_17.G(quantity = "ThermalConductance", unit = "W/K") = 0.0005 "Constant thermal conductance of material"; Real TC_4_211.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_4_211.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_4_211.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_4_211.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_4_211.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_4_211.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_4_211.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150006778741865 "Constant thermal conductance of material"; Real TC_5_6.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_5_6.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_5_6.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_5_6.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_5_6.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_5_6.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_5_6.G(quantity = "ThermalConductance", unit = "W/K") = 6.00016866250625e-05 "Constant thermal conductance of material"; Real TC_5_18.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_5_18.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_5_18.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_5_18.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_5_18.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_5_18.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_5_18.G(quantity = "ThermalConductance", unit = "W/K") = 0.00050000341793871 "Constant thermal conductance of material"; Real TC_5_212.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_5_212.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_5_212.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_5_212.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_5_212.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_5_212.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_5_212.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150003152783908 "Constant thermal conductance of material"; Real TC_6_7.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_6_7.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_6_7.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_6_7.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_6_7.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_6_7.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_6_7.G(quantity = "ThermalConductance", unit = "W/K") = 6.00040600893259e-05 "Constant thermal conductance of material"; Real TC_6_19.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_6_19.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_6_19.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_6_19.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_6_19.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_6_19.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_6_19.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499996632021394 "Constant thermal conductance of material"; Real TC_6_213.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_6_213.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_6_213.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_6_213.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_6_213.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_6_213.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_6_213.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149999999999999 "Constant thermal conductance of material"; Real TC_7_8.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_7_8.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_7_8.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_7_8.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_7_8.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_7_8.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_7_8.G(quantity = "ThermalConductance", unit = "W/K") = 5.99999999999988e-05 "Constant thermal conductance of material"; Real TC_7_20.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_7_20.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_7_20.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_7_20.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_7_20.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_7_20.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_7_20.G(quantity = "ThermalConductance", unit = "W/K") = 0.0005 "Constant thermal conductance of material"; Real TC_7_214.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_7_214.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_7_214.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_7_214.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_7_214.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_7_214.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_7_214.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150006246876561 "Constant thermal conductance of material"; Real TC_8_9.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_8_9.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_8_9.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_8_9.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_8_9.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_8_9.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_8_9.G(quantity = "ThermalConductance", unit = "W/K") = 6.00033402922757e-05 "Constant thermal conductance of material"; Real TC_8_21.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_8_21.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_8_21.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_8_21.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_8_21.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_8_21.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_8_21.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499996614186559 "Constant thermal conductance of material"; Real TC_8_215.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_8_215.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_8_215.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_8_215.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_8_215.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_8_215.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_8_215.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150009399085158 "Constant thermal conductance of material"; Real TC_9_10.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_9_10.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_9_10.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_9_10.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_9_10.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_9_10.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_9_10.G(quantity = "ThermalConductance", unit = "W/K") = 5.99984885126965e-05 "Constant thermal conductance of material"; Real TC_9_22.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_9_22.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_9_22.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_9_22.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_9_22.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_9_22.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_9_22.G(quantity = "ThermalConductance", unit = "W/K") = 0.00049999656454195 "Constant thermal conductance of material"; Real TC_9_216.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_9_216.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_9_216.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_9_216.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_9_216.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_9_216.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_9_216.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149996847613644 "Constant thermal conductance of material"; Real TC_10_11.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_10_11.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_10_11.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_10_11.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_10_11.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_10_11.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_10_11.G(quantity = "ThermalConductance", unit = "W/K") = 6.00011274169e-05 "Constant thermal conductance of material"; Real TC_10_23.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_10_23.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_10_23.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_10_23.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_10_23.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_10_23.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_10_23.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499999999999999 "Constant thermal conductance of material"; Real TC_10_217.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_10_217.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_10_217.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_10_217.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_10_217.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_10_217.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_10_217.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150006558237145 "Constant thermal conductance of material"; Real TC_11_12.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_11_12.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_11_12.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_11_12.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_11_12.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_11_12.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_11_12.G(quantity = "ThermalConductance", unit = "W/K") = 8.57140151156407e-05 "Constant thermal conductance of material"; Real TC_11_24.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_11_24.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_11_24.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_11_24.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_11_24.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_11_24.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_11_24.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499999999999999 "Constant thermal conductance of material"; Real TC_11_218.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_11_218.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_11_218.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_11_218.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_11_218.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_11_218.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_11_218.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149995991341298 "Constant thermal conductance of material"; Real TC_12_13.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_12_13.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_12_13.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_12_13.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_12_13.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_12_13.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_12_13.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199992917345419 "Constant thermal conductance of material"; Real TC_12_25.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_12_25.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_12_25.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_12_25.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_12_25.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_12_25.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_12_25.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199997409024369 "Constant thermal conductance of material"; Real TC_12_219.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_12_219.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_12_219.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_12_219.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_12_219.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_12_219.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_12_219.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599967783505138 "Constant thermal conductance of material"; Real TC_13_26.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_13_26.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_13_26.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_13_26.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_13_26.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_13_26.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_13_26.G(quantity = "ThermalConductance", unit = "W/K") = 9.99983867585141e-05 "Constant thermal conductance of material"; Real TC_13_220.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_13_220.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_13_220.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_13_220.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_13_220.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_13_220.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_13_220.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299973821989503 "Constant thermal conductance of material"; Real TC_14_15.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_14_15.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_14_15.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_14_15.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_14_15.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_14_15.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_14_15.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100003562649186 "Constant thermal conductance of material"; Real TC_14_27.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_14_27.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_14_27.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_14_27.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_14_27.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_14_27.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_14_27.G(quantity = "ThermalConductance", unit = "W/K") = 4.00012484946536e-05 "Constant thermal conductance of material"; Real TC_14_221.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_14_221.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_14_221.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_14_221.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_14_221.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_14_221.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_14_221.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149545893719822 "Constant thermal conductance of material"; Real TC_15_16.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_15_16.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_15_16.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_15_16.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_15_16.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_15_16.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_15_16.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428575984013434 "Constant thermal conductance of material"; Real TC_15_28.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_15_28.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_15_28.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_15_28.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_15_28.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_15_28.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_15_28.G(quantity = "ThermalConductance", unit = "W/K") = 8.00008239249496e-05 "Constant thermal conductance of material"; Real TC_15_1477.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_15_1477.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_15_1477.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_15_1477.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_15_1477.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_15_1477.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_15_1477.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478532110091734 "Constant thermal conductance of material"; Real TC_16_17.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_16_17.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_16_17.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_16_17.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_16_17.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_16_17.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_16_17.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299998835408248 "Constant thermal conductance of material"; Real TC_16_29.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_16_29.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_16_29.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_16_29.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_16_29.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_16_29.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_16_29.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200005806127298 "Constant thermal conductance of material"; Real TC_16_1478.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_16_1478.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_16_1478.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_16_1478.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_16_1478.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_16_1478.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_16_1478.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119631692418254 "Constant thermal conductance of material"; Real TC_17_18.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_17_18.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_17_18.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_17_18.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_17_18.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_17_18.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_17_18.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300010640561824 "Constant thermal conductance of material"; Real TC_17_30.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_17_30.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_17_30.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_17_30.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_17_30.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_17_30.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_17_30.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200004476598581 "Constant thermal conductance of material"; Real TC_17_1479.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_17_1479.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_17_1479.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_17_1479.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_17_1479.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_17_1479.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_17_1479.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119631581523602 "Constant thermal conductance of material"; Real TC_18_19.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_18_19.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_18_19.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_18_19.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_18_19.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_18_19.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_18_19.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299985742800113 "Constant thermal conductance of material"; Real TC_18_31.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_18_31.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_18_31.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_18_31.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_18_31.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_18_31.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_18_31.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200001196608811 "Constant thermal conductance of material"; Real TC_18_1480.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_18_1480.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_18_1480.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_18_1480.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_18_1480.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_18_1480.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_18_1480.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119630455147462 "Constant thermal conductance of material"; Real TC_19_20.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_19_20.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_19_20.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_19_20.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_19_20.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_19_20.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_19_20.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300042536736254 "Constant thermal conductance of material"; Real TC_19_32.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_19_32.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_19_32.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_19_32.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_19_32.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_19_32.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_19_32.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200003568518529 "Constant thermal conductance of material"; Real TC_19_1481.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_19_1481.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_19_1481.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_19_1481.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_19_1481.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_19_1481.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_19_1481.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119631970917981 "Constant thermal conductance of material"; Real TC_20_21.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_20_21.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_20_21.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_20_21.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_20_21.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_20_21.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_20_21.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299980127185993 "Constant thermal conductance of material"; Real TC_20_33.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_20_33.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_20_33.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_20_33.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_20_33.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_20_33.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_20_33.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199994757985732 "Constant thermal conductance of material"; Real TC_20_1482.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_20_1482.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_20_1482.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_20_1482.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_20_1482.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_20_1482.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_20_1482.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119632386107352 "Constant thermal conductance of material"; Real TC_21_22.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_21_22.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_21_22.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_21_22.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_21_22.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_21_22.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_21_22.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300014175349071 "Constant thermal conductance of material"; Real TC_21_34.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_21_34.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_21_34.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_21_34.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_21_34.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_21_34.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_21_34.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199996169343737 "Constant thermal conductance of material"; Real TC_21_1483.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_21_1483.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_21_1483.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_21_1483.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_21_1483.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_21_1483.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_21_1483.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119632330253179 "Constant thermal conductance of material"; Real TC_22_23.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_22_23.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_22_23.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_22_23.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_22_23.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_22_23.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_22_23.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299996937306668 "Constant thermal conductance of material"; Real TC_22_35.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_22_35.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_22_35.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_22_35.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_22_35.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_22_35.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_22_35.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200000241109393 "Constant thermal conductance of material"; Real TC_22_1484.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_22_1484.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_22_1484.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_22_1484.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_22_1484.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_22_1484.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_22_1484.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119633193519204 "Constant thermal conductance of material"; Real TC_23_24.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_23_24.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_23_24.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_23_24.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_23_24.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_23_24.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_23_24.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299995935014431 "Constant thermal conductance of material"; Real TC_23_36.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_23_36.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_23_36.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_23_36.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_23_36.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_23_36.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_23_36.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200002465817603 "Constant thermal conductance of material"; Real TC_23_1485.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_23_1485.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_23_1485.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_23_1485.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_23_1485.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_23_1485.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_23_1485.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119632975055087 "Constant thermal conductance of material"; Real TC_24_25.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_24_25.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_24_25.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_24_25.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_24_25.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_24_25.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_24_25.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428571428571428 "Constant thermal conductance of material"; Real TC_24_37.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_24_37.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_24_37.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_24_37.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_24_37.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_24_37.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_24_37.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199998623546982 "Constant thermal conductance of material"; Real TC_24_1486.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_24_1486.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_24_1486.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_24_1486.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_24_1486.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_24_1486.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_24_1486.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119632885602174 "Constant thermal conductance of material"; Real TC_25_26.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_25_26.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_25_26.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_25_26.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_25_26.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_25_26.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_25_26.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999996 "Constant thermal conductance of material"; Real TC_25_38.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_25_38.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_25_38.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_25_38.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_25_38.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_25_38.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_25_38.G(quantity = "ThermalConductance", unit = "W/K") = 7.99992680576283e-05 "Constant thermal conductance of material"; Real TC_25_1487.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_25_1487.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_25_1487.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_25_1487.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_25_1487.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_25_1487.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_25_1487.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478517201285822 "Constant thermal conductance of material"; Real TC_26_39.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_26_39.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_26_39.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_26_39.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_26_39.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_26_39.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_26_39.G(quantity = "ThermalConductance", unit = "W/K") = 3.99987908045335e-05 "Constant thermal conductance of material"; Real TC_26_222.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_26_222.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_26_222.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_26_222.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_26_222.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_26_222.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_26_222.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149950787401589 "Constant thermal conductance of material"; Real TC_27_28.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_27_28.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_27_28.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_27_28.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_27_28.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_27_28.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_27_28.G(quantity = "ThermalConductance", unit = "W/K") = 0.00200002483268975 "Constant thermal conductance of material"; Real TC_27_40.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_27_40.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_27_40.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_27_40.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_27_40.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_27_40.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_27_40.G(quantity = "ThermalConductance", unit = "W/K") = 3.52941176470588e-05 "Constant thermal conductance of material"; Real TC_27_223.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_27_223.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_27_223.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_27_223.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_27_223.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_27_223.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_27_223.G(quantity = "ThermalConductance", unit = "W/K") = 0.00300013309671704 "Constant thermal conductance of material"; Real TC_28_29.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_28_29.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_28_29.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_28_29.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_28_29.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_28_29.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_28_29.G(quantity = "ThermalConductance", unit = "W/K") = 0.00085714652453093 "Constant thermal conductance of material"; Real TC_28_41.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_28_41.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_28_41.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_28_41.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_28_41.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_28_41.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_28_41.G(quantity = "ThermalConductance", unit = "W/K") = 7.05876975370974e-05 "Constant thermal conductance of material"; Real TC_28_1466.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_28_1466.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_28_1466.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_28_1466.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_28_1466.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_28_1466.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_28_1466.G(quantity = "ThermalConductance", unit = "W/K") = 0.000957050530685107 "Constant thermal conductance of material"; Real TC_29_30.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_29_30.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_29_30.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_29_30.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_29_30.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_29_30.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_29_30.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599996603952999 "Constant thermal conductance of material"; Real TC_29_42.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_29_42.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_29_42.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_29_42.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_29_42.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_29_42.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_29_42.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176471555370787 "Constant thermal conductance of material"; Real TC_29_1467.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_29_1467.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_29_1467.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_29_1467.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_29_1467.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_29_1467.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_29_1467.G(quantity = "ThermalConductance", unit = "W/K") = 0.00239263545375806 "Constant thermal conductance of material"; Real TC_30_31.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_30_31.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_30_31.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_30_31.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_30_31.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_30_31.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_30_31.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600000000000003 "Constant thermal conductance of material"; Real TC_30_43.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_30_43.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_30_43.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_30_43.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_30_43.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_30_43.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_30_43.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176470261154698 "Constant thermal conductance of material"; Real TC_30_1468.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_30_1468.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_30_1468.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_30_1468.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_30_1468.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_30_1468.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_30_1468.G(quantity = "ThermalConductance", unit = "W/K") = 0.00239262170967101 "Constant thermal conductance of material"; Real TC_31_32.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_31_32.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_31_32.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_31_32.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_31_32.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_31_32.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_31_32.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600010516352913 "Constant thermal conductance of material"; Real TC_31_44.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_31_44.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_31_44.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_31_44.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_31_44.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_31_44.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_31_44.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176474272650402 "Constant thermal conductance of material"; Real TC_31_1469.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_31_1469.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_31_1469.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_31_1469.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_31_1469.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_31_1469.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_31_1469.G(quantity = "ThermalConductance", unit = "W/K") = 0.0023926307423701 "Constant thermal conductance of material"; Real TC_32_33.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_32_33.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_32_33.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_32_33.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_32_33.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_32_33.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_32_33.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599622937941978 "Constant thermal conductance of material"; Real TC_32_45.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_32_45.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_32_45.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_32_45.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_32_45.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_32_45.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_32_45.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176471718494026 "Constant thermal conductance of material"; Real TC_32_1470.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_32_1470.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_32_1470.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_32_1470.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_32_1470.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_32_1470.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_32_1470.G(quantity = "ThermalConductance", unit = "W/K") = 0.00239264847158134 "Constant thermal conductance of material"; Real TC_33_34.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_33_34.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_33_34.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_33_34.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_33_34.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_33_34.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_33_34.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599988935605248 "Constant thermal conductance of material"; Real TC_33_46.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_33_46.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_33_46.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_33_46.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_33_46.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_33_46.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_33_46.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176470981590579 "Constant thermal conductance of material"; Real TC_33_1471.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_33_1471.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_33_1471.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_33_1471.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_33_1471.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_33_1471.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_33_1471.G(quantity = "ThermalConductance", unit = "W/K") = 0.00239264716591051 "Constant thermal conductance of material"; Real TC_34_35.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_34_35.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_34_35.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_34_35.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_34_35.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_34_35.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_34_35.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599969963956734 "Constant thermal conductance of material"; Real TC_34_47.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_34_47.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_34_47.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_34_47.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_34_47.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_34_47.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_34_47.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176467363132501 "Constant thermal conductance of material"; Real TC_34_1472.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_34_1472.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_34_1472.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_34_1472.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_34_1472.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_34_1472.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_34_1472.G(quantity = "ThermalConductance", unit = "W/K") = 0.00239264391608928 "Constant thermal conductance of material"; Real TC_35_36.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_35_36.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_35_36.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_35_36.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_35_36.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_35_36.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_35_36.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600000000000004 "Constant thermal conductance of material"; Real TC_35_48.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_35_48.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_35_48.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_35_48.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_35_48.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_35_48.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_35_48.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176472514696491 "Constant thermal conductance of material"; Real TC_35_1473.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_35_1473.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_35_1473.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_35_1473.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_35_1473.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_35_1473.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_35_1473.G(quantity = "ThermalConductance", unit = "W/K") = 0.00239262799948672 "Constant thermal conductance of material"; Real TC_36_37.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_36_37.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_36_37.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_36_37.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_36_37.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_36_37.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_36_37.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600002525475736 "Constant thermal conductance of material"; Real TC_36_49.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_36_49.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_36_49.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_36_49.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_36_49.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_36_49.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_36_49.G(quantity = "ThermalConductance", unit = "W/K") = 0.00017647123757739 "Constant thermal conductance of material"; Real TC_36_1474.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_36_1474.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_36_1474.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_36_1474.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_36_1474.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_36_1474.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_36_1474.G(quantity = "ThermalConductance", unit = "W/K") = 0.00239262416947091 "Constant thermal conductance of material"; Real TC_37_38.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_37_38.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_37_38.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_37_38.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_37_38.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_37_38.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_37_38.G(quantity = "ThermalConductance", unit = "W/K") = 0.000857137647133908 "Constant thermal conductance of material"; Real TC_37_50.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_37_50.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_37_50.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_37_50.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_37_50.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_37_50.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_37_50.G(quantity = "ThermalConductance", unit = "W/K") = 0.00017646987102387 "Constant thermal conductance of material"; Real TC_37_1475.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_37_1475.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_37_1475.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_37_1475.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_37_1475.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_37_1475.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_37_1475.G(quantity = "ThermalConductance", unit = "W/K") = 0.00239265707530721 "Constant thermal conductance of material"; Real TC_38_39.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_38_39.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_38_39.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_38_39.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_38_39.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_38_39.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_38_39.G(quantity = "ThermalConductance", unit = "W/K") = 0.00199995610521581 "Constant thermal conductance of material"; Real TC_38_51.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_38_51.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_38_51.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_38_51.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_38_51.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_38_51.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_38_51.G(quantity = "ThermalConductance", unit = "W/K") = 7.05887377656291e-05 "Constant thermal conductance of material"; Real TC_38_1476.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_38_1476.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_38_1476.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_38_1476.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_38_1476.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_38_1476.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_38_1476.G(quantity = "ThermalConductance", unit = "W/K") = 0.000957061261325444 "Constant thermal conductance of material"; Real TC_39_52.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_39_52.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_39_52.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_39_52.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_39_52.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_39_52.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_39_52.G(quantity = "ThermalConductance", unit = "W/K") = 3.52939664683454e-05 "Constant thermal conductance of material"; Real TC_39_224.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_39_224.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_39_224.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_39_224.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_39_224.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_39_224.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_39_224.G(quantity = "ThermalConductance", unit = "W/K") = 0.00299950273495736 "Constant thermal conductance of material"; Real TC_40_41.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_40_41.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_40_41.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_40_41.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_40_41.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_40_41.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_40_41.G(quantity = "ThermalConductance", unit = "W/K") = 0.00140003801438211 "Constant thermal conductance of material"; Real TC_40_53.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_40_53.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_40_53.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_40_53.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_40_53.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_40_53.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_40_53.G(quantity = "ThermalConductance", unit = "W/K") = 4.28558423232737e-05 "Constant thermal conductance of material"; Real TC_40_225.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_40_225.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_40_225.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_40_225.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_40_225.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_40_225.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_40_225.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209992356333822 "Constant thermal conductance of material"; Real TC_41_42.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_41_42.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_41_42.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_41_42.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_41_42.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_41_42.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_41_42.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600000402630789 "Constant thermal conductance of material"; Real TC_41_54.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_41_54.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_41_54.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_41_54.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_41_54.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_41_54.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_41_54.G(quantity = "ThermalConductance", unit = "W/K") = 8.57139936624753e-05 "Constant thermal conductance of material"; Real TC_41_1461.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_41_1461.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_41_1461.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_41_1461.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_41_1461.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_41_1461.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_41_1461.G(quantity = "ThermalConductance", unit = "W/K") = 0.0006699355990563 "Constant thermal conductance of material"; Real TC_42_43.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_42_43.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_42_43.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_42_43.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_42_43.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_42_43.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_42_43.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419997754322928 "Constant thermal conductance of material"; Real TC_42_55.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_42_55.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_42_55.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_42_55.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_42_55.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_42_55.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_42_55.G(quantity = "ThermalConductance", unit = "W/K") = 0.0002142929651812 "Constant thermal conductance of material"; Real TC_42_1462.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_42_1462.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_42_1462.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_42_1462.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_42_1462.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_42_1462.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_42_1462.G(quantity = "ThermalConductance", unit = "W/K") = 0.00167482999509538 "Constant thermal conductance of material"; Real TC_43_44.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_43_44.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_43_44.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_43_44.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_43_44.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_43_44.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_43_44.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419992364469331 "Constant thermal conductance of material"; Real TC_43_56.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_43_56.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_43_56.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_43_56.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_43_56.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_43_56.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_43_56.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214285044757927 "Constant thermal conductance of material"; Real TC_43_813.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_43_813.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_43_813.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_43_813.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_43_813.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_43_813.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_43_813.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209376456803033 "Constant thermal conductance of material"; Real TC_44_45.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_44_45.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_44_45.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_44_45.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_44_45.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_44_45.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_44_45.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419969913501336 "Constant thermal conductance of material"; Real TC_44_57.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_44_57.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_44_57.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_44_57.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_44_57.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_44_57.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_44_57.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214289156626503 "Constant thermal conductance of material"; Real TC_44_814.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_44_814.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_44_814.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_44_814.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_44_814.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_44_814.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_44_814.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209365127891572 "Constant thermal conductance of material"; Real TC_45_46.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_45_46.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_45_46.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_45_46.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_45_46.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_45_46.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_45_46.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420367892976519 "Constant thermal conductance of material"; Real TC_45_58.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_45_58.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_45_58.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_45_58.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_45_58.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_45_58.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_45_58.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214291008477322 "Constant thermal conductance of material"; Real TC_45_815.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_45_815.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_45_815.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_45_815.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_45_815.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_45_815.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_45_815.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209376391219478 "Constant thermal conductance of material"; Real TC_46_47.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_46_47.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_46_47.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_46_47.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_46_47.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_46_47.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_46_47.G(quantity = "ThermalConductance", unit = "W/K") = 0.00041989308176114 "Constant thermal conductance of material"; Real TC_46_59.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_46_59.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_46_59.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_46_59.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_46_59.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_46_59.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_46_59.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214285090782121 "Constant thermal conductance of material"; Real TC_46_816.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_46_816.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_46_816.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_46_816.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_46_816.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_46_816.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_46_816.G(quantity = "ThermalConductance", unit = "W/K") = 0.020937719403394 "Constant thermal conductance of material"; Real TC_47_48.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_47_48.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_47_48.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_47_48.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_47_48.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_47_48.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_47_48.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420142378559368 "Constant thermal conductance of material"; Real TC_47_60.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_47_60.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_47_60.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_47_60.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_47_60.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_47_60.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_47_60.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214282783522078 "Constant thermal conductance of material"; Real TC_47_817.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_47_817.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_47_817.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_47_817.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_47_817.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_47_817.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_47_817.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209375214085088 "Constant thermal conductance of material"; Real TC_48_49.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_48_49.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_48_49.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_48_49.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_48_49.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_48_49.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_48_49.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419937917860564 "Constant thermal conductance of material"; Real TC_48_61.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_48_61.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_48_61.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_48_61.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_48_61.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_48_61.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_48_61.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214290165530669 "Constant thermal conductance of material"; Real TC_48_818.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_48_818.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_48_818.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_48_818.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_48_818.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_48_818.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_48_818.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209374679476221 "Constant thermal conductance of material"; Real TC_49_50.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_49_50.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_49_50.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_49_50.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_49_50.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_49_50.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_49_50.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420012983399797 "Constant thermal conductance of material"; Real TC_49_62.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_49_62.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_49_62.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_49_62.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_49_62.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_49_62.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_49_62.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214282522898205 "Constant thermal conductance of material"; Real TC_49_819.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_49_819.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_49_819.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_49_819.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_49_819.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_49_819.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_49_819.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209374051976942 "Constant thermal conductance of material"; Real TC_50_51.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_50_51.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_50_51.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_50_51.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_50_51.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_50_51.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_50_51.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599998796994893 "Constant thermal conductance of material"; Real TC_50_63.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_50_63.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_50_63.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_50_63.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_50_63.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_50_63.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_50_63.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214283773687427 "Constant thermal conductance of material"; Real TC_50_820.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_50_820.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_50_820.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_50_820.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_50_820.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_50_820.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_50_820.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209372776719528 "Constant thermal conductance of material"; Real TC_51_52.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_51_52.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_51_52.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_51_52.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_51_52.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_51_52.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_51_52.G(quantity = "ThermalConductance", unit = "W/K") = 0.00140001175554348 "Constant thermal conductance of material"; Real TC_51_64.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_51_64.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_51_64.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_51_64.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_51_64.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_51_64.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_51_64.G(quantity = "ThermalConductance", unit = "W/K") = 8.57133059925659e-05 "Constant thermal conductance of material"; Real TC_51_1463.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_51_1463.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_51_1463.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_51_1463.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_51_1463.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_51_1463.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_51_1463.G(quantity = "ThermalConductance", unit = "W/K") = 0.000669937394109067 "Constant thermal conductance of material"; Real TC_52_65.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_52_65.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_52_65.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_52_65.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_52_65.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_52_65.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_52_65.G(quantity = "ThermalConductance", unit = "W/K") = 4.28569485994018e-05 "Constant thermal conductance of material"; Real TC_52_226.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_52_226.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_52_226.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_52_226.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_52_226.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_52_226.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_52_226.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209993592174606 "Constant thermal conductance of material"; Real TC_53_54.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_53_54.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_53_54.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_53_54.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_53_54.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_53_54.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_53_54.G(quantity = "ThermalConductance", unit = "W/K") = 0.00139997714198636 "Constant thermal conductance of material"; Real TC_53_66.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_53_66.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_53_66.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_53_66.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_53_66.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_53_66.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_53_66.G(quantity = "ThermalConductance", unit = "W/K") = 4.28571428571419e-05 "Constant thermal conductance of material"; Real TC_53_227.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_53_227.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_53_227.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_53_227.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_53_227.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_53_227.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_53_227.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209995670192366 "Constant thermal conductance of material"; Real TC_54_55.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_54_55.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_54_55.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_54_55.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_54_55.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_54_55.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_54_55.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599991320197899 "Constant thermal conductance of material"; Real TC_54_67.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_54_67.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_54_67.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_54_67.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_54_67.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_54_67.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_54_67.G(quantity = "ThermalConductance", unit = "W/K") = 8.57196898051847e-05 "Constant thermal conductance of material"; Real TC_54_1464.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_54_1464.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_54_1464.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_54_1464.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_54_1464.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_54_1464.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_54_1464.G(quantity = "ThermalConductance", unit = "W/K") = 0.00066994618121164 "Constant thermal conductance of material"; Real TC_55_56.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_55_56.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_55_56.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_55_56.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_55_56.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_55_56.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_55_56.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420000562587359 "Constant thermal conductance of material"; Real TC_55_68.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_55_68.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_55_68.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_55_68.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_55_68.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_55_68.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_55_68.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214278728606354 "Constant thermal conductance of material"; Real TC_55_1465.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_55_1465.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_55_1465.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_55_1465.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_55_1465.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_55_1465.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_55_1465.G(quantity = "ThermalConductance", unit = "W/K") = 0.00167484966062168 "Constant thermal conductance of material"; Real TC_56_57.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_56_57.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_56_57.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_56_57.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_56_57.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_56_57.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_56_57.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419998259886026 "Constant thermal conductance of material"; Real TC_56_69.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_56_69.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_56_69.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_56_69.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_56_69.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_56_69.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_56_69.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214282190429206 "Constant thermal conductance of material"; Real TC_56_741.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_56_741.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_56_741.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_56_741.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_56_741.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_56_741.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_56_741.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209377502730252 "Constant thermal conductance of material"; Real TC_57_58.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_57_58.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_57_58.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_57_58.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_57_58.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_57_58.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_57_58.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419965675057231 "Constant thermal conductance of material"; Real TC_57_70.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_57_70.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_57_70.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_57_70.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_57_70.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_57_70.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_57_70.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214281630552859 "Constant thermal conductance of material"; Real TC_57_742.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_57_742.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_57_742.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_57_742.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_57_742.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_57_742.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_57_742.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209380710659899 "Constant thermal conductance of material"; Real TC_58_59.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_58_59.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_58_59.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_58_59.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_58_59.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_58_59.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_58_59.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419999999999993 "Constant thermal conductance of material"; Real TC_58_71.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_58_71.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_58_71.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_58_71.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_58_71.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_58_71.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_58_71.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214284274193549 "Constant thermal conductance of material"; Real TC_58_743.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_58_743.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_58_743.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_58_743.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_58_743.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_58_743.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_58_743.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209383109585402 "Constant thermal conductance of material"; Real TC_59_60.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_59_60.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_59_60.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_59_60.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_59_60.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_59_60.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_59_60.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419030769230601 "Constant thermal conductance of material"; Real TC_59_72.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_59_72.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_59_72.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_59_72.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_59_72.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_59_72.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_59_72.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214286952376826 "Constant thermal conductance of material"; Real TC_59_744.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_59_744.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_59_744.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_59_744.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_59_744.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_59_744.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_59_744.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209374042683551 "Constant thermal conductance of material"; Real TC_60_61.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_60_61.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_60_61.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_60_61.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_60_61.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_60_61.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_60_61.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419963133640638 "Constant thermal conductance of material"; Real TC_60_73.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_60_73.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_60_73.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_60_73.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_60_73.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_60_73.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_60_73.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214283026677199 "Constant thermal conductance of material"; Real TC_60_745.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_60_745.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_60_745.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_60_745.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_60_745.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_60_745.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_60_745.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209362224039246 "Constant thermal conductance of material"; Real TC_61_62.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_61_62.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_61_62.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_61_62.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_61_62.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_61_62.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_61_62.G(quantity = "ThermalConductance", unit = "W/K") = 0.00042009983361061 "Constant thermal conductance of material"; Real TC_61_74.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_61_74.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_61_74.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_61_74.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_61_74.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_61_74.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_61_74.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214284244461214 "Constant thermal conductance of material"; Real TC_61_746.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_61_746.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_61_746.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_61_746.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_61_746.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_61_746.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_61_746.G(quantity = "ThermalConductance", unit = "W/K") = 0.020938126201284 "Constant thermal conductance of material"; Real TC_62_63.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_62_63.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_62_63.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_62_63.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_62_63.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_62_63.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_62_63.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420012768388161 "Constant thermal conductance of material"; Real TC_62_75.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_62_75.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_62_75.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_62_75.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_62_75.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_62_75.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_62_75.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214287120590649 "Constant thermal conductance of material"; Real TC_62_747.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_62_747.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_62_747.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_62_747.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_62_747.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_62_747.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_62_747.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209374430056537 "Constant thermal conductance of material"; Real TC_63_64.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_63_64.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_63_64.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_63_64.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_63_64.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_63_64.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_63_64.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599995178404282 "Constant thermal conductance of material"; Real TC_63_76.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_63_76.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_63_76.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_63_76.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_63_76.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_63_76.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_63_76.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214284783104652 "Constant thermal conductance of material"; Real TC_63_748.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_63_748.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_63_748.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_63_748.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_63_748.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_63_748.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_63_748.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209366795058043 "Constant thermal conductance of material"; Real TC_64_65.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_64_65.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_64_65.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_64_65.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_64_65.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_64_65.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_64_65.G(quantity = "ThermalConductance", unit = "W/K") = 0.0013999977906981 "Constant thermal conductance of material"; Real TC_64_77.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_64_77.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_64_77.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_64_77.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_64_77.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_64_77.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_64_77.G(quantity = "ThermalConductance", unit = "W/K") = 8.57125993546865e-05 "Constant thermal conductance of material"; Real TC_64_1414.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_64_1414.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_64_1414.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_64_1414.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_64_1414.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_64_1414.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_64_1414.G(quantity = "ThermalConductance", unit = "W/K") = 0.000669943467942657 "Constant thermal conductance of material"; Real TC_65_78.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_65_78.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_65_78.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_65_78.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_65_78.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_65_78.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_65_78.G(quantity = "ThermalConductance", unit = "W/K") = 4.28581332871127e-05 "Constant thermal conductance of material"; Real TC_65_228.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_65_228.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_65_228.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_65_228.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_65_228.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_65_228.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_65_228.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209995082688476 "Constant thermal conductance of material"; Real TC_66_67.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_66_67.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_66_67.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_66_67.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_66_67.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_66_67.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_66_67.G(quantity = "ThermalConductance", unit = "W/K") = 0.00139998032672766 "Constant thermal conductance of material"; Real TC_66_79.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_66_79.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_66_79.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_66_79.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_66_79.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_66_79.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_66_79.G(quantity = "ThermalConductance", unit = "W/K") = 2.856783919597e-05 "Constant thermal conductance of material"; Real TC_66_229.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_66_229.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_66_229.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_66_229.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_66_229.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_66_229.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_66_229.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209995772180948 "Constant thermal conductance of material"; Real TC_67_68.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_67_68.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_67_68.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_67_68.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_67_68.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_67_68.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_67_68.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599996067791278 "Constant thermal conductance of material"; Real TC_67_80.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_67_80.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_67_80.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_67_80.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_67_80.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_67_80.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_67_80.G(quantity = "ThermalConductance", unit = "W/K") = 5.72269807280846e-05 "Constant thermal conductance of material"; Real TC_67_1415.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_67_1415.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_67_1415.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_67_1415.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_67_1415.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_67_1415.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_67_1415.G(quantity = "ThermalConductance", unit = "W/K") = 0.000669932019302833 "Constant thermal conductance of material"; Real TC_68_69.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_68_69.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_68_69.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_68_69.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_68_69.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_68_69.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_68_69.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420003150071939 "Constant thermal conductance of material"; Real TC_68_81.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_68_81.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_68_81.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_68_81.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_68_81.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_68_81.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_68_81.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142906309751505 "Constant thermal conductance of material"; Real TC_68_1416.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_68_1416.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_68_1416.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_68_1416.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_68_1416.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_68_1416.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_68_1416.G(quantity = "ThermalConductance", unit = "W/K") = 0.00167486198985384 "Constant thermal conductance of material"; Real TC_69_70.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_69_70.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_69_70.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_69_70.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_69_70.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_69_70.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_69_70.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419998351331308 "Constant thermal conductance of material"; Real TC_69_82.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_69_82.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_69_82.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_69_82.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_69_82.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_69_82.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_69_82.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142855197303464 "Constant thermal conductance of material"; Real TC_69_749.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_69_749.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_69_749.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_69_749.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_69_749.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_69_749.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_69_749.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209370467072817 "Constant thermal conductance of material"; Real TC_70_71.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_70_71.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_70_71.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_70_71.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_70_71.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_70_71.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_70_71.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419982891360133 "Constant thermal conductance of material"; Real TC_70_83.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_70_83.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_70_83.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_70_83.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_70_83.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_70_83.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_70_83.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142857142857143 "Constant thermal conductance of material"; Real TC_70_750.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_70_750.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_70_750.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_70_750.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_70_750.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_70_750.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_70_750.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209379421871841 "Constant thermal conductance of material"; Real TC_71_72.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_71_72.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_71_72.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_71_72.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_71_72.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_71_72.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_71_72.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420019379844957 "Constant thermal conductance of material"; Real TC_71_84.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_71_84.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_71_84.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_71_84.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_71_84.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_71_84.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_71_84.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142859677582886 "Constant thermal conductance of material"; Real TC_71_751.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_71_751.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_71_751.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_71_751.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_71_751.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_71_751.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_71_751.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209381732449899 "Constant thermal conductance of material"; Real TC_72_73.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_72_73.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_72_73.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_72_73.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_72_73.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_72_73.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_72_73.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419999999999961 "Constant thermal conductance of material"; Real TC_72_85.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_72_85.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_72_85.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_72_85.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_72_85.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_72_85.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_72_85.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142858889953322 "Constant thermal conductance of material"; Real TC_72_752.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_72_752.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_72_752.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_72_752.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_72_752.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_72_752.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_72_752.G(quantity = "ThermalConductance", unit = "W/K") = 0.020936555278268 "Constant thermal conductance of material"; Real TC_73_74.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_73_74.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_73_74.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_73_74.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_73_74.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_73_74.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_73_74.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420033422460034 "Constant thermal conductance of material"; Real TC_73_86.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_73_86.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_73_86.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_73_86.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_73_86.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_73_86.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_73_86.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142856907325277 "Constant thermal conductance of material"; Real TC_73_753.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_73_753.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_73_753.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_73_753.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_73_753.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_73_753.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_73_753.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209382035005173 "Constant thermal conductance of material"; Real TC_74_75.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_74_75.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_74_75.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_74_75.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_74_75.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_74_75.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_74_75.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419999999999989 "Constant thermal conductance of material"; Real TC_74_87.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_74_87.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_74_87.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_74_87.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_74_87.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_74_87.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_74_87.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142857142857142 "Constant thermal conductance of material"; Real TC_74_754.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_74_754.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_74_754.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_74_754.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_74_754.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_74_754.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_74_754.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209363599513579 "Constant thermal conductance of material"; Real TC_75_76.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_75_76.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_75_76.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_75_76.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_75_76.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_75_76.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_75_76.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419991202246812 "Constant thermal conductance of material"; Real TC_75_88.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_75_88.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_75_88.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_75_88.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_75_88.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_75_88.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_75_88.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142857348185411 "Constant thermal conductance of material"; Real TC_75_755.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_75_755.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_75_755.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_75_755.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_75_755.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_75_755.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_75_755.G(quantity = "ThermalConductance", unit = "W/K") = 0.0209380772628703 "Constant thermal conductance of material"; Real TC_76_77.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_76_77.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_76_77.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_76_77.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_76_77.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_76_77.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_76_77.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600004169663612 "Constant thermal conductance of material"; Real TC_76_89.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_76_89.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_76_89.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_76_89.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_76_89.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_76_89.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_76_89.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142858417210568 "Constant thermal conductance of material"; Real TC_76_756.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_76_756.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_76_756.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_76_756.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_76_756.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_76_756.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_76_756.G(quantity = "ThermalConductance", unit = "W/K") = 0.020936813986088 "Constant thermal conductance of material"; Real TC_77_78.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_77_78.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_77_78.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_77_78.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_77_78.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_77_78.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_77_78.G(quantity = "ThermalConductance", unit = "W/K") = 0.00139999634923243 "Constant thermal conductance of material"; Real TC_77_90.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_77_90.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_77_90.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_77_90.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_77_90.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_77_90.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_77_90.G(quantity = "ThermalConductance", unit = "W/K") = 5.71428571428566e-05 "Constant thermal conductance of material"; Real TC_77_1417.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_77_1417.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_77_1417.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_77_1417.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_77_1417.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_77_1417.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_77_1417.G(quantity = "ThermalConductance", unit = "W/K") = 0.000669937417909294 "Constant thermal conductance of material"; Real TC_78_91.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_78_91.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_78_91.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_78_91.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_78_91.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_78_91.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_78_91.G(quantity = "ThermalConductance", unit = "W/K") = 2.85711436833187e-05 "Constant thermal conductance of material"; Real TC_78_230.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_78_230.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_78_230.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_78_230.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_78_230.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_78_230.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_78_230.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209998719754192 "Constant thermal conductance of material"; Real TC_79_80.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_79_80.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_79_80.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_79_80.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_79_80.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_79_80.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_79_80.G(quantity = "ThermalConductance", unit = "W/K") = 0.00279997286847996 "Constant thermal conductance of material"; Real TC_79_92.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_79_92.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_79_92.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_79_92.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_79_92.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_79_92.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_79_92.G(quantity = "ThermalConductance", unit = "W/K") = 3.15789473684208e-05 "Constant thermal conductance of material"; Real TC_79_231.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_79_231.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_79_231.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_79_231.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_79_231.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_79_231.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_79_231.G(quantity = "ThermalConductance", unit = "W/K") = 0.00420001157139549 "Constant thermal conductance of material"; Real TC_80_81.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_80_81.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_80_81.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_80_81.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_80_81.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_80_81.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_80_81.G(quantity = "ThermalConductance", unit = "W/K") = 0.00120000078410924 "Constant thermal conductance of material"; Real TC_80_93.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_80_93.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_80_93.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_80_93.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_80_93.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_80_93.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_80_93.G(quantity = "ThermalConductance", unit = "W/K") = 6.31589222959773e-05 "Constant thermal conductance of material"; Real TC_80_1418.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_80_1418.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_80_1418.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_80_1418.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_80_1418.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_80_1418.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_80_1418.G(quantity = "ThermalConductance", unit = "W/K") = 0.00133988028178573 "Constant thermal conductance of material"; Real TC_81_82.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_81_82.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_81_82.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_81_82.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_81_82.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_81_82.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_81_82.G(quantity = "ThermalConductance", unit = "W/K") = 0.000840003310691464 "Constant thermal conductance of material"; Real TC_81_94.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_81_94.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_81_94.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_81_94.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_81_94.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_81_94.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_81_94.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157889097240825 "Constant thermal conductance of material"; Real TC_81_1419.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_81_1419.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_81_1419.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_81_1419.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_81_1419.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_81_1419.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_81_1419.G(quantity = "ThermalConductance", unit = "W/K") = 0.00334968284278986 "Constant thermal conductance of material"; Real TC_82_83.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_82_83.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_82_83.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_82_83.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_82_83.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_82_83.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_82_83.G(quantity = "ThermalConductance", unit = "W/K") = 0.000840007156915378 "Constant thermal conductance of material"; Real TC_82_95.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_82_95.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_82_95.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_82_95.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_82_95.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_82_95.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_82_95.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157893481953924 "Constant thermal conductance of material"; Real TC_82_757.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_82_757.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_82_757.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_82_757.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_82_757.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_82_757.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_82_757.G(quantity = "ThermalConductance", unit = "W/K") = 0.0418744552248404 "Constant thermal conductance of material"; Real TC_83_84.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_83_84.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_83_84.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_83_84.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_83_84.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_83_84.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_83_84.G(quantity = "ThermalConductance", unit = "W/K") = 0.000839990198480755 "Constant thermal conductance of material"; Real TC_83_96.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_83_96.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_83_96.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_83_96.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_83_96.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_83_96.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_83_96.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157894872788323 "Constant thermal conductance of material"; Real TC_83_758.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_83_758.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_83_758.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_83_758.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_83_758.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_83_758.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_83_758.G(quantity = "ThermalConductance", unit = "W/K") = 0.0418758493884403 "Constant thermal conductance of material"; Real TC_84_85.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_84_85.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_84_85.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_84_85.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_84_85.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_84_85.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_84_85.G(quantity = "ThermalConductance", unit = "W/K") = 0.000840002708375627 "Constant thermal conductance of material"; Real TC_84_97.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_84_97.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_84_97.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_84_97.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_84_97.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_84_97.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_84_97.G(quantity = "ThermalConductance", unit = "W/K") = 0.00015789327514382 "Constant thermal conductance of material"; Real TC_84_759.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_84_759.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_84_759.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_84_759.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_84_759.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_84_759.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_84_759.G(quantity = "ThermalConductance", unit = "W/K") = 0.0418735212736097 "Constant thermal conductance of material"; Real TC_85_86.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_85_86.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_85_86.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_85_86.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_85_86.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_85_86.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_85_86.G(quantity = "ThermalConductance", unit = "W/K") = 0.000839927817136754 "Constant thermal conductance of material"; Real TC_85_98.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_85_98.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_85_98.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_85_98.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_85_98.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_85_98.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_85_98.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157888331462726 "Constant thermal conductance of material"; Real TC_85_760.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_85_760.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_85_760.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_85_760.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_85_760.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_85_760.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_85_760.G(quantity = "ThermalConductance", unit = "W/K") = 0.0418732672477417 "Constant thermal conductance of material"; Real TC_86_87.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_86_87.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_86_87.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_86_87.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_86_87.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_86_87.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_86_87.G(quantity = "ThermalConductance", unit = "W/K") = 0.000840018843481326 "Constant thermal conductance of material"; Real TC_86_99.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_86_99.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_86_99.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_86_99.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_86_99.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_86_99.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_86_99.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157894295020315 "Constant thermal conductance of material"; Real TC_86_761.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_86_761.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_86_761.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_86_761.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_86_761.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_86_761.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_86_761.G(quantity = "ThermalConductance", unit = "W/K") = 0.0418752727416988 "Constant thermal conductance of material"; Real TC_87_88.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_87_88.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_87_88.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_87_88.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_87_88.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_87_88.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_87_88.G(quantity = "ThermalConductance", unit = "W/K") = 0.000840627615063346 "Constant thermal conductance of material"; Real TC_87_100.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_87_100.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_87_100.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_87_100.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_87_100.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_87_100.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_87_100.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157897111913358 "Constant thermal conductance of material"; Real TC_87_762.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_87_762.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_87_762.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_87_762.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_87_762.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_87_762.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_87_762.G(quantity = "ThermalConductance", unit = "W/K") = 0.041873937284986 "Constant thermal conductance of material"; Real TC_88_89.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_88_89.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_88_89.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_88_89.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_88_89.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_88_89.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_88_89.G(quantity = "ThermalConductance", unit = "W/K") = 0.000839991213481019 "Constant thermal conductance of material"; Real TC_88_101.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_88_101.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_88_101.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_88_101.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_88_101.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_88_101.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_88_101.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157896408521722 "Constant thermal conductance of material"; Real TC_88_763.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_88_763.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_88_763.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_88_763.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_88_763.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_88_763.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_88_763.G(quantity = "ThermalConductance", unit = "W/K") = 0.0418738012291073 "Constant thermal conductance of material"; Real TC_89_90.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_89_90.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_89_90.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_89_90.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_89_90.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_89_90.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_89_90.G(quantity = "ThermalConductance", unit = "W/K") = 0.00120003279441847 "Constant thermal conductance of material"; Real TC_89_102.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_89_102.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_89_102.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_89_102.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_89_102.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_89_102.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_89_102.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157892518884522 "Constant thermal conductance of material"; Real TC_89_764.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_89_764.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_89_764.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_89_764.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_89_764.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_89_764.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_89_764.G(quantity = "ThermalConductance", unit = "W/K") = 0.0418741226319109 "Constant thermal conductance of material"; Real TC_90_91.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_90_91.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_90_91.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_90_91.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_90_91.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_90_91.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_90_91.G(quantity = "ThermalConductance", unit = "W/K") = 0.00279999008589861 "Constant thermal conductance of material"; Real TC_90_103.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_90_103.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_90_103.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_90_103.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_90_103.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_90_103.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_90_103.G(quantity = "ThermalConductance", unit = "W/K") = 6.31577946768065e-05 "Constant thermal conductance of material"; Real TC_90_1420.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_90_1420.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_90_1420.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_90_1420.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_90_1420.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_90_1420.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_90_1420.G(quantity = "ThermalConductance", unit = "W/K") = 0.00133988818199345 "Constant thermal conductance of material"; Real TC_91_104.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_91_104.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_91_104.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_91_104.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_91_104.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_91_104.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_91_104.G(quantity = "ThermalConductance", unit = "W/K") = 3.1578563439187e-05 "Constant thermal conductance of material"; Real TC_91_232.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_91_232.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_91_232.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_91_232.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_91_232.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_91_232.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_91_232.G(quantity = "ThermalConductance", unit = "W/K") = 0.00420006361323156 "Constant thermal conductance of material"; Real TC_92_93.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_92_93.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_92_93.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_92_93.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_92_93.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_92_93.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_92_93.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000745439772 "Constant thermal conductance of material"; Real TC_92_105.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_92_105.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_92_105.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_92_105.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_92_105.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_92_105.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_92_105.G(quantity = "ThermalConductance", unit = "W/K") = 6.00048076923092e-05 "Constant thermal conductance of material"; Real TC_92_233.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_92_233.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_92_233.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_92_233.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_92_233.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_92_233.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_92_233.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149997131218086 "Constant thermal conductance of material"; Real TC_93_94.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_93_94.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_93_94.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_93_94.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_93_94.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_93_94.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_93_94.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428571705430113 "Constant thermal conductance of material"; Real TC_93_106.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_93_106.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_93_106.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_93_106.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_93_106.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_93_106.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_93_106.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119997780490517 "Constant thermal conductance of material"; Real TC_93_1421.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_93_1421.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_93_1421.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_93_1421.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_93_1421.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_93_1421.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_93_1421.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478530572786596 "Constant thermal conductance of material"; Real TC_94_95.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_94_95.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_94_95.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_94_95.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_94_95.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_94_95.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_94_95.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299997217352589 "Constant thermal conductance of material"; Real TC_94_107.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_94_107.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_94_107.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_94_107.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_94_107.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_94_107.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_94_107.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029999166319299 "Constant thermal conductance of material"; Real TC_94_1422.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_94_1422.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_94_1422.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_94_1422.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_94_1422.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_94_1422.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_94_1422.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119631096275717 "Constant thermal conductance of material"; Real TC_95_96.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_95_96.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_95_96.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_95_96.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_95_96.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_95_96.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_95_96.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999996 "Constant thermal conductance of material"; Real TC_95_108.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_95_108.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_95_108.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_95_108.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_95_108.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_95_108.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_95_108.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300006984703504 "Constant thermal conductance of material"; Real TC_95_765.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_95_765.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_95_765.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_95_765.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_95_765.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_95_765.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_95_765.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149545762329308 "Constant thermal conductance of material"; Real TC_96_97.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_96_97.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_96_97.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_96_97.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_96_97.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_96_97.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_96_97.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000004 "Constant thermal conductance of material"; Real TC_96_109.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_96_109.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_96_109.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_96_109.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_96_109.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_96_109.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_96_109.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000011 "Constant thermal conductance of material"; Real TC_96_766.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_96_766.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_96_766.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_96_766.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_96_766.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_96_766.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_96_766.G(quantity = "ThermalConductance", unit = "W/K") = 0.014955173297078 "Constant thermal conductance of material"; Real TC_97_98.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_97_98.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_97_98.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_97_98.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_97_98.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_97_98.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_97_98.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000001 "Constant thermal conductance of material"; Real TC_97_110.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_97_110.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_97_110.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_97_110.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_97_110.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_97_110.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_97_110.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300005665722384 "Constant thermal conductance of material"; Real TC_97_767.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_97_767.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_97_767.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_97_767.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_97_767.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_97_767.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_97_767.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149550170285647 "Constant thermal conductance of material"; Real TC_98_99.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_98_99.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_98_99.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_98_99.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_98_99.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_98_99.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_98_99.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300008314625424 "Constant thermal conductance of material"; Real TC_98_111.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_98_111.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_98_111.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_98_111.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_98_111.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_98_111.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_98_111.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999997 "Constant thermal conductance of material"; Real TC_98_768.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_98_768.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_98_768.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_98_768.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_98_768.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_98_768.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_98_768.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149552592247519 "Constant thermal conductance of material"; Real TC_99_100.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_99_100.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_99_100.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_99_100.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_99_100.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_99_100.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_99_100.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029999552111793 "Constant thermal conductance of material"; Real TC_99_112.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_99_112.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_99_112.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_99_112.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_99_112.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_99_112.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_99_112.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003605162592 "Constant thermal conductance of material"; Real TC_99_769.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_99_769.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_99_769.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_99_769.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_99_769.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_99_769.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_99_769.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149549632692238 "Constant thermal conductance of material"; Real TC_100_101.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_100_101.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_100_101.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_100_101.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_100_101.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_100_101.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_100_101.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299985259433945 "Constant thermal conductance of material"; Real TC_100_113.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_100_113.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_100_113.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_100_113.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_100_113.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_100_113.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_100_113.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300006644518278 "Constant thermal conductance of material"; Real TC_100_770.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_100_770.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_100_770.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_100_770.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_100_770.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_100_770.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_100_770.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149550557675375 "Constant thermal conductance of material"; Real TC_101_102.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_101_102.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_101_102.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_101_102.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_101_102.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_101_102.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_101_102.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299992048978294 "Constant thermal conductance of material"; Real TC_101_114.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_101_114.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_101_114.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_101_114.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_101_114.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_101_114.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_101_114.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299993184296615 "Constant thermal conductance of material"; Real TC_101_771.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_101_771.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_101_771.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_101_771.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_101_771.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_101_771.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_101_771.G(quantity = "ThermalConductance", unit = "W/K") = 0.014954984508839 "Constant thermal conductance of material"; Real TC_102_103.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_102_103.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_102_103.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_102_103.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_102_103.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_102_103.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_102_103.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428567823490816 "Constant thermal conductance of material"; Real TC_102_115.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_102_115.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_102_115.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_102_115.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_102_115.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_102_115.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_102_115.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299996175323186 "Constant thermal conductance of material"; Real TC_102_772.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_102_772.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_102_772.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_102_772.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_102_772.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_102_772.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_102_772.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149548945885914 "Constant thermal conductance of material"; Real TC_103_104.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_103_104.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_103_104.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_103_104.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_103_104.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_103_104.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_103_104.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_103_116.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_103_116.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_103_116.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_103_116.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_103_116.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_103_116.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_103_116.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001199987076764 "Constant thermal conductance of material"; Real TC_103_1423.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_103_1423.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_103_1423.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_103_1423.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_103_1423.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_103_1423.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_103_1423.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478521808988232 "Constant thermal conductance of material"; Real TC_104_117.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_104_117.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_104_117.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_104_117.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_104_117.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_104_117.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_104_117.G(quantity = "ThermalConductance", unit = "W/K") = 5.99984130762516e-05 "Constant thermal conductance of material"; Real TC_104_234.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_104_234.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_104_234.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_104_234.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_104_234.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_104_234.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_104_234.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150002327963498 "Constant thermal conductance of material"; Real TC_105_106.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_105_106.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_105_106.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_105_106.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_105_106.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_105_106.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_105_106.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_105_118.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_105_118.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_105_118.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_105_118.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_105_118.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_105_118.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_105_118.G(quantity = "ThermalConductance", unit = "W/K") = 5.99968344412763e-05 "Constant thermal conductance of material"; Real TC_105_235.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_105_235.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_105_235.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_105_235.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_105_235.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_105_235.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_105_235.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150005803830528 "Constant thermal conductance of material"; Real TC_106_107.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_106_107.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_106_107.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_106_107.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_106_107.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_106_107.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_106_107.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428573905972711 "Constant thermal conductance of material"; Real TC_106_119.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_106_119.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_106_119.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_106_119.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_106_119.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_106_119.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_106_119.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120005986828976 "Constant thermal conductance of material"; Real TC_106_1424.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_106_1424.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_106_1424.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_106_1424.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_106_1424.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_106_1424.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_106_1424.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478528175159319 "Constant thermal conductance of material"; Real TC_107_108.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_107_108.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_107_108.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_107_108.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_107_108.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_107_108.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_107_108.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000370222282 "Constant thermal conductance of material"; Real TC_107_120.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_107_120.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_107_120.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_107_120.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_107_120.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_107_120.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_107_120.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300015515903798 "Constant thermal conductance of material"; Real TC_107_1425.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_107_1425.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_107_1425.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_107_1425.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_107_1425.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_107_1425.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_107_1425.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119633671376053 "Constant thermal conductance of material"; Real TC_108_109.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_108_109.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_108_109.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_108_109.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_108_109.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_108_109.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_108_109.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299997073199285 "Constant thermal conductance of material"; Real TC_108_121.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_108_121.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_108_121.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_108_121.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_108_121.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_108_121.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_108_121.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999995 "Constant thermal conductance of material"; Real TC_108_773.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_108_773.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_108_773.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_108_773.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_108_773.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_108_773.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_108_773.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149554762774234 "Constant thermal conductance of material"; Real TC_109_110.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_109_110.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_109_110.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_109_110.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_109_110.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_109_110.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_109_110.G(quantity = "ThermalConductance", unit = "W/K") = 0.0003 "Constant thermal conductance of material"; Real TC_109_122.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_109_122.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_109_122.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_109_122.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_109_122.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_109_122.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_109_122.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300010997470581 "Constant thermal conductance of material"; Real TC_109_774.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_109_774.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_109_774.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_109_774.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_109_774.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_109_774.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_109_774.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149552268051337 "Constant thermal conductance of material"; Real TC_110_111.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_110_111.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_110_111.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_110_111.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_110_111.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_110_111.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_110_111.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299992918014209 "Constant thermal conductance of material"; Real TC_110_123.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_110_123.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_110_123.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_110_123.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_110_123.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_110_123.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_110_123.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300014306151628 "Constant thermal conductance of material"; Real TC_110_775.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_110_775.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_110_775.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_110_775.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_110_775.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_110_775.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_110_775.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149550095849145 "Constant thermal conductance of material"; Real TC_111_112.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_111_112.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_111_112.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_111_112.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_111_112.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_111_112.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_111_112.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300006044852807 "Constant thermal conductance of material"; Real TC_111_124.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_111_124.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_111_124.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_111_124.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_111_124.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_111_124.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_111_124.G(quantity = "ThermalConductance", unit = "W/K") = 0.0002999920031987 "Constant thermal conductance of material"; Real TC_111_776.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_111_776.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_111_776.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_111_776.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_111_776.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_111_776.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_111_776.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149551215378097 "Constant thermal conductance of material"; Real TC_112_113.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_112_113.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_112_113.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_112_113.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_112_113.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_112_113.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_112_113.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000008 "Constant thermal conductance of material"; Real TC_112_125.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_112_125.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_112_125.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_112_125.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_112_125.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_112_125.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_112_125.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300022060445622 "Constant thermal conductance of material"; Real TC_112_777.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_112_777.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_112_777.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_112_777.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_112_777.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_112_777.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_112_777.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149551245727238 "Constant thermal conductance of material"; Real TC_113_114.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_113_114.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_113_114.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_113_114.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_113_114.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_113_114.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_113_114.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300039787798429 "Constant thermal conductance of material"; Real TC_113_126.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_113_126.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_113_126.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_113_126.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_113_126.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_113_126.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_113_126.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300028376844511 "Constant thermal conductance of material"; Real TC_113_778.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_113_778.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_113_778.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_113_778.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_113_778.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_113_778.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_113_778.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149549696771615 "Constant thermal conductance of material"; Real TC_114_115.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_114_115.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_114_115.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_114_115.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_114_115.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_114_115.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_114_115.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300001513248489 "Constant thermal conductance of material"; Real TC_114_127.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_114_127.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_114_127.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_114_127.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_114_127.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_114_127.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_114_127.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029999999999999 "Constant thermal conductance of material"; Real TC_114_779.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_114_779.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_114_779.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_114_779.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_114_779.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_114_779.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_114_779.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149551565460615 "Constant thermal conductance of material"; Real TC_115_116.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_115_116.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_115_116.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_115_116.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_115_116.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_115_116.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_115_116.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428574722228093 "Constant thermal conductance of material"; Real TC_115_128.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_115_128.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_115_128.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_115_128.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_115_128.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_115_128.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_115_128.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299886363636578 "Constant thermal conductance of material"; Real TC_115_780.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_115_780.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_115_780.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_115_780.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_115_780.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_115_780.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_115_780.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149546493621413 "Constant thermal conductance of material"; Real TC_116_117.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_116_117.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_116_117.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_116_117.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_116_117.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_116_117.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_116_117.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999989891263692 "Constant thermal conductance of material"; Real TC_116_129.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_116_129.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_116_129.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_116_129.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_116_129.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_116_129.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_116_129.G(quantity = "ThermalConductance", unit = "W/K") = 0.000116730000000272 "Constant thermal conductance of material"; Real TC_116_1426.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_116_1426.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_116_1426.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_116_1426.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_116_1426.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_116_1426.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_116_1426.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478532037815126 "Constant thermal conductance of material"; Real TC_117_130.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_117_130.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_117_130.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_117_130.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_117_130.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_117_130.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_117_130.G(quantity = "ThermalConductance", unit = "W/K") = 6.00177777776807e-05 "Constant thermal conductance of material"; Real TC_117_236.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_117_236.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_117_236.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_117_236.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_117_236.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_117_236.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_117_236.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150002881346165 "Constant thermal conductance of material"; Real TC_118_119.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_118_119.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_118_119.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_118_119.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_118_119.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_118_119.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_118_119.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100003693171327 "Constant thermal conductance of material"; Real TC_118_131.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_118_131.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_118_131.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_118_131.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_118_131.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_118_131.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_118_131.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000043e-05 "Constant thermal conductance of material"; Real TC_118_237.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_118_237.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_118_237.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_118_237.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_118_237.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_118_237.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_118_237.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149997012963733 "Constant thermal conductance of material"; Real TC_119_120.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_119_120.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_119_120.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_119_120.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_119_120.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_119_120.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_119_120.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428575534881047 "Constant thermal conductance of material"; Real TC_119_132.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_119_132.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_119_132.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_119_132.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_119_132.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_119_132.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_119_132.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119995732574675 "Constant thermal conductance of material"; Real TC_119_1427.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_119_1427.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_119_1427.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_119_1427.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_119_1427.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_119_1427.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_119_1427.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478527290787825 "Constant thermal conductance of material"; Real TC_120_121.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_120_121.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_120_121.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_120_121.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_120_121.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_120_121.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_120_121.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000185620706 "Constant thermal conductance of material"; Real TC_120_133.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_120_133.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_120_133.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_120_133.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_120_133.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_120_133.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_120_133.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299990477097419 "Constant thermal conductance of material"; Real TC_120_1428.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_120_1428.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_120_1428.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_120_1428.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_120_1428.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_120_1428.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_120_1428.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119630175532628 "Constant thermal conductance of material"; Real TC_121_122.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_121_122.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_121_122.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_121_122.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_121_122.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_121_122.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_121_122.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300005999520039 "Constant thermal conductance of material"; Real TC_121_134.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_121_134.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_121_134.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_121_134.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_121_134.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_121_134.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_121_134.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299966594287605 "Constant thermal conductance of material"; Real TC_121_781.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_121_781.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_121_781.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_121_781.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_121_781.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_121_781.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_121_781.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149548564378644 "Constant thermal conductance of material"; Real TC_122_123.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_122_123.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_122_123.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_122_123.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_122_123.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_122_123.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_122_123.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999995 "Constant thermal conductance of material"; Real TC_122_135.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_122_135.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_122_135.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_122_135.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_122_135.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_122_135.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_122_135.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299948678470626 "Constant thermal conductance of material"; Real TC_122_782.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_122_782.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_122_782.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_122_782.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_122_782.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_122_782.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_122_782.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149552786782797 "Constant thermal conductance of material"; Real TC_123_124.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_123_124.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_123_124.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_123_124.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_123_124.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_123_124.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_123_124.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299984157160962 "Constant thermal conductance of material"; Real TC_123_136.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_123_136.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_123_136.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_123_136.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_123_136.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_123_136.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_123_136.G(quantity = "ThermalConductance", unit = "W/K") = 0.00030007357859534 "Constant thermal conductance of material"; Real TC_123_783.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_123_783.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_123_783.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_123_783.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_123_783.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_123_783.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_123_783.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149548336747635 "Constant thermal conductance of material"; Real TC_124_125.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_124_125.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_124_125.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_124_125.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_124_125.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_124_125.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_124_125.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300010145760762 "Constant thermal conductance of material"; Real TC_124_137.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_124_137.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_124_137.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_124_137.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_124_137.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_124_137.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_124_137.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299992986885464 "Constant thermal conductance of material"; Real TC_124_784.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_124_784.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_124_784.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_124_784.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_124_784.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_124_784.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_124_784.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149553554247009 "Constant thermal conductance of material"; Real TC_125_126.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_125_126.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_125_126.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_125_126.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_125_126.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_125_126.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_125_126.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299995490213768 "Constant thermal conductance of material"; Real TC_125_138.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_125_138.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_125_138.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_125_138.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_125_138.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_125_138.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_125_138.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299995425853077 "Constant thermal conductance of material"; Real TC_125_785.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_125_785.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_125_785.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_125_785.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_125_785.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_125_785.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_125_785.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149550043898158 "Constant thermal conductance of material"; Real TC_126_127.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_126_127.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_126_127.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_126_127.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_126_127.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_126_127.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_126_127.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999998 "Constant thermal conductance of material"; Real TC_126_139.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_126_139.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_126_139.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_126_139.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_126_139.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_126_139.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_126_139.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300001994694112 "Constant thermal conductance of material"; Real TC_126_786.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_126_786.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_126_786.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_126_786.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_126_786.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_126_786.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_126_786.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149553465868786 "Constant thermal conductance of material"; Real TC_127_128.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_127_128.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_127_128.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_127_128.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_127_128.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_127_128.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_127_128.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299991814684457 "Constant thermal conductance of material"; Real TC_127_140.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_127_140.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_127_140.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_127_140.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_127_140.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_127_140.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_127_140.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300011275228324 "Constant thermal conductance of material"; Real TC_127_787.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_127_787.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_127_787.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_127_787.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_127_787.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_127_787.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_127_787.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149551780227725 "Constant thermal conductance of material"; Real TC_128_129.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_128_129.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_128_129.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_128_129.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_128_129.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_128_129.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_128_129.G(quantity = "ThermalConductance", unit = "W/K") = 0.00042857197775689 "Constant thermal conductance of material"; Real TC_128_141.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_128_141.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_128_141.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_128_141.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_128_141.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_128_141.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_128_141.G(quantity = "ThermalConductance", unit = "W/K") = 0.00030000451446887 "Constant thermal conductance of material"; Real TC_128_788.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_128_788.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_128_788.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_128_788.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_128_788.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_128_788.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_128_788.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149554998278999 "Constant thermal conductance of material"; Real TC_129_130.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_129_130.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_129_130.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_129_130.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_129_130.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_129_130.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_129_130.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999989888878777 "Constant thermal conductance of material"; Real TC_129_142.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_129_142.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_129_142.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_129_142.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_129_142.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_129_142.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_129_142.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119997236996614 "Constant thermal conductance of material"; Real TC_129_1429.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_129_1429.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_129_1429.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_129_1429.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_129_1429.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_129_1429.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_129_1429.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478527894983592 "Constant thermal conductance of material"; Real TC_130_143.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_130_143.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_130_143.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_130_143.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_130_143.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_130_143.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_130_143.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000004e-05 "Constant thermal conductance of material"; Real TC_130_238.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_130_238.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_130_238.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_130_238.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_130_238.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_130_238.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_130_238.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149996539872207 "Constant thermal conductance of material"; Real TC_131_132.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_131_132.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_131_132.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_131_132.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_131_132.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_131_132.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_131_132.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999970550123688 "Constant thermal conductance of material"; Real TC_131_144.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_131_144.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_131_144.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_131_144.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_131_144.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_131_144.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_131_144.G(quantity = "ThermalConductance", unit = "W/K") = 5.99973074851956e-05 "Constant thermal conductance of material"; Real TC_131_239.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_131_239.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_131_239.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_131_239.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_131_239.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_131_239.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_131_239.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149999999999999 "Constant thermal conductance of material"; Real TC_132_133.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_132_133.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_132_133.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_132_133.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_132_133.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_132_133.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_132_133.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428580130816499 "Constant thermal conductance of material"; Real TC_132_145.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_132_145.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_132_145.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_132_145.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_132_145.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_132_145.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_132_145.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120003684145896 "Constant thermal conductance of material"; Real TC_132_1430.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_132_1430.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_132_1430.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_132_1430.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_132_1430.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_132_1430.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_132_1430.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478529908119256 "Constant thermal conductance of material"; Real TC_133_134.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_133_134.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_133_134.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_133_134.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_133_134.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_133_134.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_133_134.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300004100835825 "Constant thermal conductance of material"; Real TC_133_146.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_133_146.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_133_146.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_133_146.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_133_146.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_133_146.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_133_146.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299987134954319 "Constant thermal conductance of material"; Real TC_133_1431.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_133_1431.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_133_1431.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_133_1431.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_133_1431.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_133_1431.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_133_1431.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119632141415982 "Constant thermal conductance of material"; Real TC_134_135.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_134_135.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_134_135.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_134_135.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_134_135.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_134_135.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_134_135.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003200409658 "Constant thermal conductance of material"; Real TC_134_147.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_134_147.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_134_147.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_134_147.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_134_147.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_134_147.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_134_147.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300302775441521 "Constant thermal conductance of material"; Real TC_134_789.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_134_789.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_134_789.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_134_789.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_134_789.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_134_789.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_134_789.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149553258829791 "Constant thermal conductance of material"; Real TC_135_136.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_135_136.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_135_136.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_135_136.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_135_136.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_135_136.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_135_136.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300005343022004 "Constant thermal conductance of material"; Real TC_135_148.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_135_148.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_135_148.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_135_148.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_135_148.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_135_148.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_135_148.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029955010224973 "Constant thermal conductance of material"; Real TC_135_790.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_135_790.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_135_790.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_135_790.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_135_790.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_135_790.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_135_790.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149554815204472 "Constant thermal conductance of material"; Real TC_136_137.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_136_137.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_136_137.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_136_137.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_136_137.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_136_137.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_136_137.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000006 "Constant thermal conductance of material"; Real TC_136_149.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_136_149.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_136_149.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_136_149.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_136_149.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_136_149.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_136_149.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029995965301592 "Constant thermal conductance of material"; Real TC_136_791.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_136_791.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_136_791.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_136_791.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_136_791.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_136_791.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_136_791.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149551429574443 "Constant thermal conductance of material"; Real TC_137_138.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_137_138.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_137_138.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_137_138.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_137_138.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_137_138.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_137_138.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003370067061 "Constant thermal conductance of material"; Real TC_137_150.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_137_150.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_137_150.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_137_150.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_137_150.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_137_150.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_137_150.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000004 "Constant thermal conductance of material"; Real TC_137_792.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_137_792.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_137_792.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_137_792.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_137_792.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_137_792.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_137_792.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149552077085307 "Constant thermal conductance of material"; Real TC_138_139.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_138_139.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_138_139.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_138_139.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_138_139.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_138_139.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_138_139.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000006 "Constant thermal conductance of material"; Real TC_138_151.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_138_151.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_138_151.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_138_151.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_138_151.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_138_151.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_138_151.G(quantity = "ThermalConductance", unit = "W/K") = 0.00030000393576826 "Constant thermal conductance of material"; Real TC_138_793.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_138_793.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_138_793.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_138_793.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_138_793.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_138_793.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_138_793.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149550256449514 "Constant thermal conductance of material"; Real TC_139_140.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_139_140.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_139_140.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_139_140.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_139_140.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_139_140.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_139_140.G(quantity = "ThermalConductance", unit = "W/K") = 0.0003014154929586 "Constant thermal conductance of material"; Real TC_139_152.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_139_152.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_139_152.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_139_152.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_139_152.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_139_152.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_139_152.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300006651810959 "Constant thermal conductance of material"; Real TC_139_794.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_139_794.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_139_794.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_139_794.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_139_794.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_139_794.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_139_794.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149549926732257 "Constant thermal conductance of material"; Real TC_140_141.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_140_141.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_140_141.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_140_141.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_140_141.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_140_141.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_140_141.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299992286133036 "Constant thermal conductance of material"; Real TC_140_153.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_140_153.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_140_153.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_140_153.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_140_153.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_140_153.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_140_153.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999995 "Constant thermal conductance of material"; Real TC_140_795.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_140_795.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_140_795.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_140_795.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_140_795.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_140_795.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_140_795.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149550652825142 "Constant thermal conductance of material"; Real TC_141_142.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_141_142.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_141_142.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_141_142.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_141_142.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_141_142.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_141_142.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428570875305472 "Constant thermal conductance of material"; Real TC_141_154.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_141_154.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_141_154.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_141_154.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_141_154.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_141_154.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_141_154.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300004669188034 "Constant thermal conductance of material"; Real TC_141_796.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_141_796.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_141_796.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_141_796.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_141_796.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_141_796.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_141_796.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149549036126666 "Constant thermal conductance of material"; Real TC_142_143.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_142_143.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_142_143.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_142_143.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_142_143.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_142_143.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_142_143.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000339133649 "Constant thermal conductance of material"; Real TC_142_155.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_142_155.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_142_155.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_142_155.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_142_155.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_142_155.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_142_155.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119998489254826 "Constant thermal conductance of material"; Real TC_142_1432.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_142_1432.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_142_1432.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_142_1432.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_142_1432.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_142_1432.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_142_1432.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478527317262317 "Constant thermal conductance of material"; Real TC_143_156.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_143_156.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_143_156.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_143_156.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_143_156.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_143_156.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_143_156.G(quantity = "ThermalConductance", unit = "W/K") = 5.99999999999997e-05 "Constant thermal conductance of material"; Real TC_143_240.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_143_240.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_143_240.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_143_240.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_143_240.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_143_240.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_143_240.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149998841976052 "Constant thermal conductance of material"; Real TC_144_145.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_144_145.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_144_145.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_144_145.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_144_145.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_144_145.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_144_145.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000740143144 "Constant thermal conductance of material"; Real TC_144_157.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_144_157.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_144_157.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_144_157.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_144_157.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_144_157.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_144_157.G(quantity = "ThermalConductance", unit = "W/K") = 6.00010656436487e-05 "Constant thermal conductance of material"; Real TC_144_241.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_144_241.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_144_241.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_144_241.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_144_241.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_144_241.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_144_241.G(quantity = "ThermalConductance", unit = "W/K") = 0.0015000644080896 "Constant thermal conductance of material"; Real TC_145_146.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_145_146.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_145_146.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_145_146.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_145_146.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_145_146.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_145_146.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428563819466374 "Constant thermal conductance of material"; Real TC_145_158.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_145_158.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_145_158.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_145_158.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_145_158.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_145_158.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_145_158.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120000936373426 "Constant thermal conductance of material"; Real TC_145_1433.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_145_1433.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_145_1433.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_145_1433.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_145_1433.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_145_1433.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_145_1433.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478530328606107 "Constant thermal conductance of material"; Real TC_146_147.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_146_147.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_146_147.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_146_147.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_146_147.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_146_147.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_146_147.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299996117990894 "Constant thermal conductance of material"; Real TC_146_159.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_146_159.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_146_159.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_146_159.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_146_159.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_146_159.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_146_159.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300007307003766 "Constant thermal conductance of material"; Real TC_146_1434.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_146_1434.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_146_1434.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_146_1434.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_146_1434.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_146_1434.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_146_1434.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119631536413308 "Constant thermal conductance of material"; Real TC_147_148.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_147_148.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_147_148.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_147_148.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_147_148.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_147_148.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_147_148.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299996617965371 "Constant thermal conductance of material"; Real TC_147_160.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_147_160.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_147_160.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_147_160.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_147_160.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_147_160.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_147_160.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300020688228385 "Constant thermal conductance of material"; Real TC_147_797.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_147_797.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_147_797.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_147_797.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_147_797.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_147_797.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_147_797.G(quantity = "ThermalConductance", unit = "W/K") = 0.014955052739974 "Constant thermal conductance of material"; Real TC_148_149.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_148_149.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_148_149.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_148_149.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_148_149.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_148_149.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_148_149.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300007018528918 "Constant thermal conductance of material"; Real TC_148_161.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_148_161.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_148_161.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_148_161.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_148_161.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_148_161.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_148_161.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999998 "Constant thermal conductance of material"; Real TC_148_798.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_148_798.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_148_798.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_148_798.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_148_798.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_148_798.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_148_798.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149550108594478 "Constant thermal conductance of material"; Real TC_149_150.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_149_150.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_149_150.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_149_150.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_149_150.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_149_150.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_149_150.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299988082469314 "Constant thermal conductance of material"; Real TC_149_162.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_149_162.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_149_162.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_149_162.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_149_162.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_149_162.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_149_162.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300023853539268 "Constant thermal conductance of material"; Real TC_149_799.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_149_799.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_149_799.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_149_799.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_149_799.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_149_799.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_149_799.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149550828342537 "Constant thermal conductance of material"; Real TC_150_151.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_150_151.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_150_151.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_150_151.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_150_151.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_150_151.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_150_151.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300005698655117 "Constant thermal conductance of material"; Real TC_150_163.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_150_163.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_150_163.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_150_163.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_150_163.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_150_163.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_150_163.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300004825090468 "Constant thermal conductance of material"; Real TC_150_800.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_150_800.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_150_800.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_150_800.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_150_800.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_150_800.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_150_800.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149551118334494 "Constant thermal conductance of material"; Real TC_151_152.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_151_152.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_151_152.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_151_152.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_151_152.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_151_152.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_151_152.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299981991716184 "Constant thermal conductance of material"; Real TC_151_164.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_151_164.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_151_164.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_151_164.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_151_164.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_151_164.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_151_164.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003919570414 "Constant thermal conductance of material"; Real TC_151_801.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_151_801.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_151_801.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_151_801.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_151_801.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_151_801.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_151_801.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149551957541727 "Constant thermal conductance of material"; Real TC_152_153.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_152_153.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_152_153.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_152_153.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_152_153.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_152_153.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_152_153.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300020790020847 "Constant thermal conductance of material"; Real TC_152_165.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_152_165.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_152_165.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_152_165.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_152_165.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_152_165.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_152_165.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299992867077994 "Constant thermal conductance of material"; Real TC_152_802.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_152_802.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_152_802.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_152_802.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_152_802.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_152_802.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_152_802.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149550946937056 "Constant thermal conductance of material"; Real TC_153_154.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_153_154.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_153_154.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_153_154.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_153_154.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_153_154.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_153_154.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000005 "Constant thermal conductance of material"; Real TC_153_166.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_153_166.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_153_166.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_153_166.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_153_166.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_153_166.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_153_166.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000006 "Constant thermal conductance of material"; Real TC_153_803.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_153_803.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_153_803.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_153_803.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_153_803.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_153_803.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_153_803.G(quantity = "ThermalConductance", unit = "W/K") = 0.014955117036588 "Constant thermal conductance of material"; Real TC_154_155.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_154_155.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_154_155.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_154_155.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_154_155.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_154_155.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_154_155.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428572254424369 "Constant thermal conductance of material"; Real TC_154_167.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_154_167.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_154_167.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_154_167.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_154_167.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_154_167.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_154_167.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299996554931616 "Constant thermal conductance of material"; Real TC_154_804.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_154_804.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_154_804.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_154_804.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_154_804.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_154_804.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_154_804.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149555506029765 "Constant thermal conductance of material"; Real TC_155_156.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_155_156.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_155_156.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_155_156.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_155_156.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_155_156.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_155_156.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100001016649327 "Constant thermal conductance of material"; Real TC_155_168.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_155_168.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_155_168.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_155_168.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_155_168.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_155_168.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_155_168.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120000257122288 "Constant thermal conductance of material"; Real TC_155_1435.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_155_1435.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_155_1435.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_155_1435.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_155_1435.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_155_1435.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_155_1435.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478527258241966 "Constant thermal conductance of material"; Real TC_156_169.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_156_169.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_156_169.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_156_169.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_156_169.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_156_169.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_156_169.G(quantity = "ThermalConductance", unit = "W/K") = 5.99997417755517e-05 "Constant thermal conductance of material"; Real TC_156_242.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_156_242.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_156_242.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_156_242.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_156_242.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_156_242.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_156_242.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149995976502777 "Constant thermal conductance of material"; Real TC_157_158.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_157_158.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_157_158.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_157_158.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_157_158.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_157_158.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_157_158.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100002308988894 "Constant thermal conductance of material"; Real TC_157_170.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_157_170.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_157_170.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_157_170.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_157_170.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_157_170.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_157_170.G(quantity = "ThermalConductance", unit = "W/K") = 3.00002034463817e-05 "Constant thermal conductance of material"; Real TC_157_243.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_157_243.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_157_243.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_157_243.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_157_243.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_157_243.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_157_243.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149999999999996 "Constant thermal conductance of material"; Real TC_158_159.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_158_159.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_158_159.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_158_159.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_158_159.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_158_159.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_158_159.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428569759881011 "Constant thermal conductance of material"; Real TC_158_171.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_158_171.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_158_171.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_158_171.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_158_171.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_158_171.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_158_171.G(quantity = "ThermalConductance", unit = "W/K") = 6.00017101464618e-05 "Constant thermal conductance of material"; Real TC_158_1436.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_158_1436.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_158_1436.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_158_1436.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_158_1436.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_158_1436.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_158_1436.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478522710782183 "Constant thermal conductance of material"; Real TC_159_160.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_159_160.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_159_160.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_159_160.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_159_160.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_159_160.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_159_160.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003118998712 "Constant thermal conductance of material"; Real TC_159_172.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_159_172.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_159_172.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_159_172.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_159_172.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_159_172.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_159_172.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149999888299857 "Constant thermal conductance of material"; Real TC_159_1437.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_159_1437.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_159_1437.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_159_1437.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_159_1437.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_159_1437.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_159_1437.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119631218493814 "Constant thermal conductance of material"; Real TC_160_161.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_160_161.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_160_161.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_160_161.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_160_161.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_160_161.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_160_161.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300006758583398 "Constant thermal conductance of material"; Real TC_160_173.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_160_173.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_160_173.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_160_173.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_160_173.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_160_173.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_160_173.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149996763030275 "Constant thermal conductance of material"; Real TC_160_805.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_160_805.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_160_805.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_160_805.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_160_805.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_160_805.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_160_805.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149551089208582 "Constant thermal conductance of material"; Real TC_161_162.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_161_162.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_161_162.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_161_162.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_161_162.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_161_162.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_161_162.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299983271997324 "Constant thermal conductance of material"; Real TC_161_174.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_161_174.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_161_174.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_161_174.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_161_174.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_161_174.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_161_174.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150003689664572 "Constant thermal conductance of material"; Real TC_161_806.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_161_806.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_161_806.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_161_806.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_161_806.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_161_806.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_161_806.G(quantity = "ThermalConductance", unit = "W/K") = 0.014955146106682 "Constant thermal conductance of material"; Real TC_162_163.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_162_163.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_162_163.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_162_163.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_162_163.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_162_163.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_162_163.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000006 "Constant thermal conductance of material"; Real TC_162_175.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_162_175.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_162_175.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_162_175.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_162_175.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_162_175.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_162_175.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149999962351297 "Constant thermal conductance of material"; Real TC_162_807.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_162_807.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_162_807.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_162_807.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_162_807.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_162_807.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_162_807.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149553201145558 "Constant thermal conductance of material"; Real TC_163_164.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_163_164.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_163_164.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_163_164.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_163_164.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_163_164.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_163_164.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300007836990593 "Constant thermal conductance of material"; Real TC_163_176.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_163_176.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_163_176.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_163_176.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_163_176.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_163_176.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_163_176.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149998737634386 "Constant thermal conductance of material"; Real TC_163_808.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_163_808.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_163_808.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_163_808.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_163_808.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_163_808.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_163_808.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149554161933364 "Constant thermal conductance of material"; Real TC_164_165.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_164_165.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_164_165.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_164_165.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_164_165.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_164_165.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_164_165.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300011655011659 "Constant thermal conductance of material"; Real TC_164_177.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_164_177.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_164_177.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_164_177.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_164_177.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_164_177.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_164_177.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150002404234951 "Constant thermal conductance of material"; Real TC_164_809.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_164_809.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_164_809.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_164_809.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_164_809.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_164_809.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_164_809.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149553612801581 "Constant thermal conductance of material"; Real TC_165_166.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_165_166.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_165_166.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_165_166.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_165_166.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_165_166.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_165_166.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299918557300643 "Constant thermal conductance of material"; Real TC_165_178.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_165_178.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_165_178.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_165_178.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_165_178.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_165_178.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_165_178.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149999003044986 "Constant thermal conductance of material"; Real TC_165_810.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_165_810.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_165_810.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_165_810.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_165_810.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_165_810.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_165_810.G(quantity = "ThermalConductance", unit = "W/K") = 0.014955305806412 "Constant thermal conductance of material"; Real TC_166_167.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_166_167.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_166_167.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_166_167.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_166_167.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_166_167.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_166_167.G(quantity = "ThermalConductance", unit = "W/K") = 0.0003 "Constant thermal conductance of material"; Real TC_166_179.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_166_179.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_166_179.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_166_179.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_166_179.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_166_179.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_166_179.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149997808951529 "Constant thermal conductance of material"; Real TC_166_811.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_166_811.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_166_811.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_166_811.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_166_811.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_166_811.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_166_811.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149551029017387 "Constant thermal conductance of material"; Real TC_167_168.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_167_168.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_167_168.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_167_168.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_167_168.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_167_168.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_167_168.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428576029890167 "Constant thermal conductance of material"; Real TC_167_180.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_167_180.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_167_180.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_167_180.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_167_180.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_167_180.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_167_180.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150000849702698 "Constant thermal conductance of material"; Real TC_167_812.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_167_812.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_167_812.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_167_812.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_167_812.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_167_812.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_167_812.G(quantity = "ThermalConductance", unit = "W/K") = 0.0149554816452166 "Constant thermal conductance of material"; Real TC_168_169.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_168_169.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_168_169.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_168_169.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_168_169.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_168_169.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_168_169.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100001696324066 "Constant thermal conductance of material"; Real TC_168_181.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_168_181.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_168_181.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_168_181.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_168_181.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_168_181.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_168_181.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000734080546e-05 "Constant thermal conductance of material"; Real TC_168_1438.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_168_1438.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_168_1438.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_168_1438.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_168_1438.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_168_1438.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_168_1438.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478531018596155 "Constant thermal conductance of material"; Real TC_169_182.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_169_182.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_169_182.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_169_182.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_169_182.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_169_182.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_169_182.G(quantity = "ThermalConductance", unit = "W/K") = 3.00006897842946e-05 "Constant thermal conductance of material"; Real TC_169_244.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_169_244.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_169_244.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_169_244.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_169_244.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_169_244.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_169_244.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150005269505954 "Constant thermal conductance of material"; Real TC_170_171.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_170_171.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_170_171.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_170_171.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_170_171.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_170_171.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_170_171.G(quantity = "ThermalConductance", unit = "W/K") = 0.00300002470782991 "Constant thermal conductance of material"; Real TC_170_183.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_170_183.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_170_183.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_170_183.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_170_183.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_170_183.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_170_183.G(quantity = "ThermalConductance", unit = "W/K") = 3.00005614847384e-05 "Constant thermal conductance of material"; Real TC_170_245.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_170_245.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_170_245.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_170_245.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_170_245.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_170_245.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_170_245.G(quantity = "ThermalConductance", unit = "W/K") = 0.00449987446648232 "Constant thermal conductance of material"; Real TC_171_172.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_171_172.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_171_172.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_171_172.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_171_172.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_171_172.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_171_172.G(quantity = "ThermalConductance", unit = "W/K") = 0.00128569961620907 "Constant thermal conductance of material"; Real TC_171_184.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_171_184.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_171_184.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_171_184.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_171_184.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_171_184.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_171_184.G(quantity = "ThermalConductance", unit = "W/K") = 5.99994999240269e-05 "Constant thermal conductance of material"; Real TC_171_1439.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_171_1439.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_171_1439.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_171_1439.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_171_1439.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_171_1439.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_171_1439.G(quantity = "ThermalConductance", unit = "W/K") = 0.00143562452577202 "Constant thermal conductance of material"; Real TC_172_173.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_172_173.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_172_173.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_172_173.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_172_173.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_172_173.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_172_173.G(quantity = "ThermalConductance", unit = "W/K") = 0.000900012352365477 "Constant thermal conductance of material"; Real TC_172_185.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_172_185.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_172_185.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_172_185.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_172_185.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_172_185.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_172_185.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149999933428043 "Constant thermal conductance of material"; Real TC_172_1440.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_172_1440.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_172_1440.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_172_1440.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_172_1440.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_172_1440.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_172_1440.G(quantity = "ThermalConductance", unit = "W/K") = 0.00358884955542663 "Constant thermal conductance of material"; Real TC_173_174.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_173_174.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_173_174.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_173_174.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_173_174.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_173_174.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_173_174.G(quantity = "ThermalConductance", unit = "W/K") = 0.000899990140335889 "Constant thermal conductance of material"; Real TC_173_186.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_173_186.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_173_186.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_173_186.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_173_186.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_173_186.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_173_186.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150003701302634 "Constant thermal conductance of material"; Real TC_173_1441.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_173_1441.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_173_1441.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_173_1441.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_173_1441.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_173_1441.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_173_1441.G(quantity = "ThermalConductance", unit = "W/K") = 0.00358907766114778 "Constant thermal conductance of material"; Real TC_174_175.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_174_175.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_174_175.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_174_175.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_174_175.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_174_175.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_174_175.G(quantity = "ThermalConductance", unit = "W/K") = 0.000900025161452642 "Constant thermal conductance of material"; Real TC_174_187.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_174_187.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_174_187.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_174_187.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_174_187.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_174_187.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_174_187.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150001246127523 "Constant thermal conductance of material"; Real TC_174_1442.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_174_1442.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_174_1442.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_174_1442.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_174_1442.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_174_1442.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_174_1442.G(quantity = "ThermalConductance", unit = "W/K") = 0.00358892060797778 "Constant thermal conductance of material"; Real TC_175_176.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_175_176.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_175_176.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_175_176.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_175_176.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_175_176.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_175_176.G(quantity = "ThermalConductance", unit = "W/K") = 0.000900051858254075 "Constant thermal conductance of material"; Real TC_175_188.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_175_188.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_175_188.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_175_188.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_175_188.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_175_188.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_175_188.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149998595417604 "Constant thermal conductance of material"; Real TC_175_1443.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_175_1443.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_175_1443.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_175_1443.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_175_1443.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_175_1443.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_175_1443.G(quantity = "ThermalConductance", unit = "W/K") = 0.00358881293351763 "Constant thermal conductance of material"; Real TC_176_177.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_176_177.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_176_177.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_176_177.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_176_177.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_176_177.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_176_177.G(quantity = "ThermalConductance", unit = "W/K") = 0.000899923896499244 "Constant thermal conductance of material"; Real TC_176_189.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_176_189.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_176_189.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_176_189.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_176_189.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_176_189.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_176_189.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149999891343795 "Constant thermal conductance of material"; Real TC_176_1444.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_176_1444.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_176_1444.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_176_1444.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_176_1444.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_176_1444.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_176_1444.G(quantity = "ThermalConductance", unit = "W/K") = 0.00358901711102267 "Constant thermal conductance of material"; Real TC_177_178.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_177_178.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_177_178.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_177_178.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_177_178.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_177_178.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_177_178.G(quantity = "ThermalConductance", unit = "W/K") = 0.000899991348732609 "Constant thermal conductance of material"; Real TC_177_190.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_177_190.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_177_190.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_177_190.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_177_190.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_177_190.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_177_190.G(quantity = "ThermalConductance", unit = "W/K") = 0.00015000197025355 "Constant thermal conductance of material"; Real TC_177_1445.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_177_1445.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_177_1445.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_177_1445.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_177_1445.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_177_1445.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_177_1445.G(quantity = "ThermalConductance", unit = "W/K") = 0.00358894065039079 "Constant thermal conductance of material"; Real TC_178_179.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_178_179.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_178_179.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_178_179.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_178_179.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_178_179.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_178_179.G(quantity = "ThermalConductance", unit = "W/K") = 0.000900005505294257 "Constant thermal conductance of material"; Real TC_178_191.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_178_191.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_178_191.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_178_191.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_178_191.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_178_191.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_178_191.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149994967354167 "Constant thermal conductance of material"; Real TC_178_1446.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_178_1446.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_178_1446.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_178_1446.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_178_1446.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_178_1446.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_178_1446.G(quantity = "ThermalConductance", unit = "W/K") = 0.00358891969630225 "Constant thermal conductance of material"; Real TC_179_180.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_179_180.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_179_180.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_179_180.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_179_180.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_179_180.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_179_180.G(quantity = "ThermalConductance", unit = "W/K") = 0.000899977074594311 "Constant thermal conductance of material"; Real TC_179_192.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_179_192.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_179_192.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_179_192.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_179_192.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_179_192.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_179_192.G(quantity = "ThermalConductance", unit = "W/K") = 0.00015000563289245 "Constant thermal conductance of material"; Real TC_179_1447.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_179_1447.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_179_1447.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_179_1447.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_179_1447.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_179_1447.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_179_1447.G(quantity = "ThermalConductance", unit = "W/K") = 0.00358896876493667 "Constant thermal conductance of material"; Real TC_180_181.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_180_181.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_180_181.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_180_181.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_180_181.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_180_181.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_180_181.G(quantity = "ThermalConductance", unit = "W/K") = 0.00128571111315565 "Constant thermal conductance of material"; Real TC_180_193.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_180_193.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_180_193.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_180_193.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_180_193.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_180_193.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_180_193.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150001408584168 "Constant thermal conductance of material"; Real TC_180_1448.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_180_1448.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_180_1448.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_180_1448.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_180_1448.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_180_1448.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_180_1448.G(quantity = "ThermalConductance", unit = "W/K") = 0.00358888234707436 "Constant thermal conductance of material"; Real TC_181_182.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_181_182.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_181_182.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_181_182.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_181_182.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_181_182.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_181_182.G(quantity = "ThermalConductance", unit = "W/K") = 0.00300004635423909 "Constant thermal conductance of material"; Real TC_181_194.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_181_194.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_181_194.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_181_194.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_181_194.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_181_194.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_181_194.G(quantity = "ThermalConductance", unit = "W/K") = 6.00008451082014e-05 "Constant thermal conductance of material"; Real TC_181_1449.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_181_1449.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_181_1449.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_181_1449.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_181_1449.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_181_1449.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_181_1449.G(quantity = "ThermalConductance", unit = "W/K") = 0.00143552367820355 "Constant thermal conductance of material"; Real TC_182_195.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_182_195.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_182_195.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_182_195.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_182_195.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_182_195.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_182_195.G(quantity = "ThermalConductance", unit = "W/K") = 2.99989837883127e-05 "Constant thermal conductance of material"; Real TC_182_246.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_182_246.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_182_246.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_182_246.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_182_246.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_182_246.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_182_246.G(quantity = "ThermalConductance", unit = "W/K") = 0.00449859859859772 "Constant thermal conductance of material"; Real TC_183_184.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_183_184.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_183_184.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_183_184.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_183_184.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_183_184.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_183_184.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_183_196.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_183_196.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_183_196.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_183_196.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_183_196.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_183_196.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_183_196.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_183_247.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_183_247.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_183_247.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_183_247.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_183_247.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_183_247.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_183_247.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149814696485683 "Constant thermal conductance of material"; Real TC_184_185.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_184_185.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_184_185.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_184_185.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_184_185.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_184_185.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_184_185.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428580303670386 "Constant thermal conductance of material"; Real TC_184_197.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_184_197.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_184_197.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_184_197.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_184_197.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_184_197.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_184_197.G(quantity = "ThermalConductance", unit = "W/K") = 0.00020000634890402 "Constant thermal conductance of material"; Real TC_184_1450.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_184_1450.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_184_1450.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_184_1450.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_184_1450.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_184_1450.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_184_1450.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478522844383373 "Constant thermal conductance of material"; Real TC_185_186.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_185_186.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_185_186.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_185_186.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_185_186.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_185_186.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_185_186.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299992854590925 "Constant thermal conductance of material"; Real TC_185_198.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_185_198.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_185_198.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_185_198.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_185_198.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_185_198.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_185_198.G(quantity = "ThermalConductance", unit = "W/K") = 0.0005 "Constant thermal conductance of material"; Real TC_185_1451.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_185_1451.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_185_1451.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_185_1451.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_185_1451.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_185_1451.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_185_1451.G(quantity = "ThermalConductance", unit = "W/K") = 0.0011963143525741 "Constant thermal conductance of material"; Real TC_186_187.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_186_187.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_186_187.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_186_187.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_186_187.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_186_187.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_186_187.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000001 "Constant thermal conductance of material"; Real TC_186_199.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_186_199.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_186_199.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_186_199.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_186_199.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_186_199.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_186_199.G(quantity = "ThermalConductance", unit = "W/K") = 0.0005 "Constant thermal conductance of material"; Real TC_186_1452.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_186_1452.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_186_1452.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_186_1452.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_186_1452.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_186_1452.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_186_1452.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119631944809231 "Constant thermal conductance of material"; Real TC_187_188.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_187_188.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_187_188.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_187_188.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_187_188.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_187_188.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_187_188.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300010822510818 "Constant thermal conductance of material"; Real TC_187_200.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_187_200.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_187_200.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_187_200.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_187_200.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_187_200.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_187_200.G(quantity = "ThermalConductance", unit = "W/K") = 0.0005 "Constant thermal conductance of material"; Real TC_187_1453.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_187_1453.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_187_1453.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_187_1453.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_187_1453.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_187_1453.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_187_1453.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119632775722202 "Constant thermal conductance of material"; Real TC_188_189.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_188_189.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_188_189.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_188_189.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_188_189.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_188_189.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_188_189.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299982668977375 "Constant thermal conductance of material"; Real TC_188_201.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_188_201.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_188_201.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_188_201.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_188_201.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_188_201.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_188_201.G(quantity = "ThermalConductance", unit = "W/K") = 0.0005 "Constant thermal conductance of material"; Real TC_188_1454.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_188_1454.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_188_1454.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_188_1454.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_188_1454.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_188_1454.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_188_1454.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119631601920559 "Constant thermal conductance of material"; Real TC_189_190.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_189_190.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_189_190.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_189_190.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_189_190.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_189_190.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_189_190.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299984360337822 "Constant thermal conductance of material"; Real TC_189_202.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_189_202.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_189_202.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_189_202.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_189_202.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_189_202.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_189_202.G(quantity = "ThermalConductance", unit = "W/K") = 0.0005 "Constant thermal conductance of material"; Real TC_189_1455.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_189_1455.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_189_1455.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_189_1455.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_189_1455.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_189_1455.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_189_1455.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119632671081678 "Constant thermal conductance of material"; Real TC_190_191.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_190_191.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_190_191.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_190_191.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_190_191.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_190_191.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_190_191.G(quantity = "ThermalConductance", unit = "W/K") = 0.00030000733837235 "Constant thermal conductance of material"; Real TC_190_203.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_190_203.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_190_203.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_190_203.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_190_203.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_190_203.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_190_203.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499999999999999 "Constant thermal conductance of material"; Real TC_190_1456.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_190_1456.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_190_1456.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_190_1456.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_190_1456.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_190_1456.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_190_1456.G(quantity = "ThermalConductance", unit = "W/K") = 0.0011963135289907 "Constant thermal conductance of material"; Real TC_191_192.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_191_192.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_191_192.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_191_192.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_191_192.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_191_192.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_191_192.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300006858005005 "Constant thermal conductance of material"; Real TC_191_204.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_191_204.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_191_204.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_191_204.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_191_204.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_191_204.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_191_204.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499995871964862 "Constant thermal conductance of material"; Real TC_191_1457.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_191_1457.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_191_1457.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_191_1457.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_191_1457.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_191_1457.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_191_1457.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119632291553233 "Constant thermal conductance of material"; Real TC_192_193.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_192_193.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_192_193.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_192_193.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_192_193.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_192_193.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_192_193.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299990558912387 "Constant thermal conductance of material"; Real TC_192_205.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_192_205.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_192_205.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_192_205.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_192_205.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_192_205.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_192_205.G(quantity = "ThermalConductance", unit = "W/K") = 0.000500000000000001 "Constant thermal conductance of material"; Real TC_192_1458.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_192_1458.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_192_1458.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_192_1458.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_192_1458.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_192_1458.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_192_1458.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119631697049497 "Constant thermal conductance of material"; Real TC_193_194.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_193_194.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_193_194.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_193_194.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_193_194.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_193_194.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_193_194.G(quantity = "ThermalConductance", unit = "W/K") = 0.00042857506426081 "Constant thermal conductance of material"; Real TC_193_206.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_193_206.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_193_206.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_193_206.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_193_206.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_193_206.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_193_206.G(quantity = "ThermalConductance", unit = "W/K") = 0.000500005103863625 "Constant thermal conductance of material"; Real TC_193_1459.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_193_1459.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_193_1459.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_193_1459.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_193_1459.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_193_1459.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_193_1459.G(quantity = "ThermalConductance", unit = "W/K") = 0.00119632337580948 "Constant thermal conductance of material"; Real TC_194_195.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_194_195.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_194_195.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_194_195.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_194_195.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_194_195.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_194_195.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999958619548127 "Constant thermal conductance of material"; Real TC_194_207.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_194_207.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_194_207.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_194_207.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_194_207.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_194_207.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_194_207.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199993773543787 "Constant thermal conductance of material"; Real TC_194_1460.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_194_1460.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_194_1460.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_194_1460.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_194_1460.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_194_1460.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_194_1460.G(quantity = "ThermalConductance", unit = "W/K") = 0.000478560132540101 "Constant thermal conductance of material"; Real TC_195_208.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_195_208.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_195_208.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_195_208.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_195_208.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_195_208.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_195_208.G(quantity = "ThermalConductance", unit = "W/K") = 9.99999999999999e-05 "Constant thermal conductance of material"; Real TC_195_248.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_195_248.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_195_248.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_195_248.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_195_248.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_195_248.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_195_248.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150044444444399 "Constant thermal conductance of material"; Real TC_196_197.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_196_197.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_196_197.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_196_197.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_196_197.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_196_197.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_196_197.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199991882457996 "Constant thermal conductance of material"; Real TC_196_249.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_196_249.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_196_249.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_196_249.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_196_249.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_196_249.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_196_249.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299949832775915 "Constant thermal conductance of material"; Real TC_197_198.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_197_198.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_197_198.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_197_198.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_197_198.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_197_198.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_197_198.G(quantity = "ThermalConductance", unit = "W/K") = 8.57152057705929e-05 "Constant thermal conductance of material"; Real TC_197_250.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_197_250.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_197_250.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_197_250.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_197_250.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_197_250.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_197_250.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599928418038684 "Constant thermal conductance of material"; Real TC_198_199.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_198_199.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_198_199.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_198_199.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_198_199.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_198_199.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_198_199.G(quantity = "ThermalConductance", unit = "W/K") = 5.99979836677084e-05 "Constant thermal conductance of material"; Real TC_198_251.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_198_251.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_198_251.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_198_251.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_198_251.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_198_251.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_198_251.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149999999999999 "Constant thermal conductance of material"; Real TC_199_200.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_199_200.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_199_200.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_199_200.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_199_200.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_199_200.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_199_200.G(quantity = "ThermalConductance", unit = "W/K") = 6.00008575226174e-05 "Constant thermal conductance of material"; Real TC_199_252.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_199_252.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_199_252.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_199_252.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_199_252.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_199_252.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_199_252.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149987105647725 "Constant thermal conductance of material"; Real TC_200_201.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_200_201.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_200_201.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_200_201.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_200_201.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_200_201.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_200_201.G(quantity = "ThermalConductance", unit = "W/K") = 6.00037945863886e-05 "Constant thermal conductance of material"; Real TC_200_253.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_200_253.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_200_253.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_200_253.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_200_253.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_200_253.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_200_253.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149991961414794 "Constant thermal conductance of material"; Real TC_201_202.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_201_202.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_201_202.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_201_202.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_201_202.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_201_202.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_201_202.G(quantity = "ThermalConductance", unit = "W/K") = 5.98700564971585e-05 "Constant thermal conductance of material"; Real TC_201_254.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_201_254.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_201_254.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_201_254.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_201_254.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_201_254.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_201_254.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149992062232098 "Constant thermal conductance of material"; Real TC_202_203.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_202_203.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_202_203.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_202_203.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_202_203.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_202_203.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_202_203.G(quantity = "ThermalConductance", unit = "W/K") = 6.00095201827861e-05 "Constant thermal conductance of material"; Real TC_202_255.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_202_255.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_202_255.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_202_255.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_202_255.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_202_255.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_202_255.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150003969199017 "Constant thermal conductance of material"; Real TC_203_204.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_203_204.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_203_204.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_203_204.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_203_204.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_203_204.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_203_204.G(quantity = "ThermalConductance", unit = "W/K") = 5.99947478991603e-05 "Constant thermal conductance of material"; Real TC_203_256.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_203_256.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_203_256.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_203_256.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_203_256.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_203_256.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_203_256.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149996018791306 "Constant thermal conductance of material"; Real TC_204_205.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_204_205.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_204_205.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_204_205.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_204_205.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_204_205.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_204_205.G(quantity = "ThermalConductance", unit = "W/K") = 5.99991482837921e-05 "Constant thermal conductance of material"; Real TC_204_257.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_204_257.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_204_257.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_204_257.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_204_257.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_204_257.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_204_257.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150004024144869 "Constant thermal conductance of material"; Real TC_205_206.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_205_206.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_205_206.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_205_206.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_205_206.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_205_206.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_205_206.G(quantity = "ThermalConductance", unit = "W/K") = 5.99999999999999e-05 "Constant thermal conductance of material"; Real TC_205_258.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_205_258.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_205_258.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_205_258.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_205_258.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_205_258.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_205_258.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014999577452886 "Constant thermal conductance of material"; Real TC_206_207.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_206_207.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_206_207.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_206_207.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_206_207.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_206_207.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_206_207.G(quantity = "ThermalConductance", unit = "W/K") = 8.57142857142854e-05 "Constant thermal conductance of material"; Real TC_206_259.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_206_259.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_206_259.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_206_259.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_206_259.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_206_259.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_206_259.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149994774793603 "Constant thermal conductance of material"; Real TC_207_208.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_207_208.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_207_208.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_207_208.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_207_208.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_207_208.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_207_208.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200000000000002 "Constant thermal conductance of material"; Real TC_207_260.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_207_260.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_207_260.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_207_260.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_207_260.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_207_260.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_207_260.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600021017234133 "Constant thermal conductance of material"; Real TC_208_261.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_208_261.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_208_261.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_208_261.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_208_261.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_208_261.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_208_261.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299888381532219 "Constant thermal conductance of material"; Real TC_209_210.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_209_210.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_209_210.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_209_210.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_209_210.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_209_210.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_209_210.G(quantity = "ThermalConductance", unit = "W/K") = 8.57139881262365e-05 "Constant thermal conductance of material"; Real TC_209_371.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_209_371.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_209_371.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_209_371.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_209_371.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_209_371.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_209_371.G(quantity = "ThermalConductance", unit = "W/K") = 0.00060009212344545 "Constant thermal conductance of material"; Real TC_209_424.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_209_424.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_209_424.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_209_424.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_209_424.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_209_424.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_209_424.G(quantity = "ThermalConductance", unit = "W/K") = 0.00020001500825454 "Constant thermal conductance of material"; Real TC_209_1477.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_209_1477.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_209_1477.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_209_1477.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_209_1477.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_209_1477.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_209_1477.G(quantity = "ThermalConductance", unit = "W/K") = 2.04451469028081e-05 "Constant thermal conductance of material"; Real TC_210_211.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_210_211.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_210_211.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_210_211.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_210_211.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_210_211.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_210_211.G(quantity = "ThermalConductance", unit = "W/K") = 5.99989231100582e-05 "Constant thermal conductance of material"; Real TC_210_372.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_210_372.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_210_372.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_210_372.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_210_372.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_210_372.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_210_372.G(quantity = "ThermalConductance", unit = "W/K") = 0.0015000249999999 "Constant thermal conductance of material"; Real TC_210_1478.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_210_1478.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_210_1478.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_210_1478.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_210_1478.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_210_1478.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_210_1478.G(quantity = "ThermalConductance", unit = "W/K") = 5.11141147372731e-05 "Constant thermal conductance of material"; Real TC_211_212.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_211_212.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_211_212.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_211_212.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_211_212.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_211_212.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_211_212.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000002e-05 "Constant thermal conductance of material"; Real TC_211_373.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_211_373.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_211_373.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_211_373.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_211_373.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_211_373.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_211_373.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149990717821781 "Constant thermal conductance of material"; Real TC_211_1479.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_211_1479.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_211_1479.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_211_1479.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_211_1479.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_211_1479.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_211_1479.G(quantity = "ThermalConductance", unit = "W/K") = 5.11156887749145e-05 "Constant thermal conductance of material"; Real TC_212_213.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_212_213.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_212_213.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_212_213.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_212_213.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_212_213.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_212_213.G(quantity = "ThermalConductance", unit = "W/K") = 6.00025682732638e-05 "Constant thermal conductance of material"; Real TC_212_374.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_212_374.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_212_374.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_212_374.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_212_374.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_212_374.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_212_374.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149986323851205 "Constant thermal conductance of material"; Real TC_212_1480.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_212_1480.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_212_1480.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_212_1480.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_212_1480.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_212_1480.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_212_1480.G(quantity = "ThermalConductance", unit = "W/K") = 5.11157725609212e-05 "Constant thermal conductance of material"; Real TC_213_214.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_213_214.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_213_214.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_213_214.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_213_214.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_213_214.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_213_214.G(quantity = "ThermalConductance", unit = "W/K") = 5.99879566439219e-05 "Constant thermal conductance of material"; Real TC_213_375.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_213_375.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_213_375.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_213_375.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_213_375.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_213_375.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_213_375.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149986566362173 "Constant thermal conductance of material"; Real TC_213_1481.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_213_1481.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_213_1481.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_213_1481.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_213_1481.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_213_1481.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_213_1481.G(quantity = "ThermalConductance", unit = "W/K") = 5.11157582656114e-05 "Constant thermal conductance of material"; Real TC_214_215.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_214_215.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_214_215.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_214_215.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_214_215.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_214_215.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_214_215.G(quantity = "ThermalConductance", unit = "W/K") = 5.99950956351181e-05 "Constant thermal conductance of material"; Real TC_214_376.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_214_376.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_214_376.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_214_376.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_214_376.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_214_376.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_214_376.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149999999999998 "Constant thermal conductance of material"; Real TC_214_1482.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_214_1482.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_214_1482.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_214_1482.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_214_1482.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_214_1482.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_214_1482.G(quantity = "ThermalConductance", unit = "W/K") = 5.11153072389086e-05 "Constant thermal conductance of material"; Real TC_215_216.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_215_216.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_215_216.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_215_216.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_215_216.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_215_216.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_215_216.G(quantity = "ThermalConductance", unit = "W/K") = 5.99991580365405e-05 "Constant thermal conductance of material"; Real TC_215_377.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_215_377.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_215_377.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_215_377.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_215_377.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_215_377.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_215_377.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014998654467169 "Constant thermal conductance of material"; Real TC_215_1483.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_215_1483.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_215_1483.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_215_1483.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_215_1483.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_215_1483.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_215_1483.G(quantity = "ThermalConductance", unit = "W/K") = 5.111206823823e-05 "Constant thermal conductance of material"; Real TC_216_217.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_216_217.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_216_217.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_216_217.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_216_217.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_216_217.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_216_217.G(quantity = "ThermalConductance", unit = "W/K") = 6.00015473289232e-05 "Constant thermal conductance of material"; Real TC_216_378.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_216_378.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_216_378.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_216_378.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_216_378.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_216_378.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_216_378.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014999326054724 "Constant thermal conductance of material"; Real TC_216_1484.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_216_1484.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_216_1484.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_216_1484.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_216_1484.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_216_1484.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_216_1484.G(quantity = "ThermalConductance", unit = "W/K") = 5.11123012461915e-05 "Constant thermal conductance of material"; Real TC_217_218.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_217_218.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_217_218.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_217_218.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_217_218.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_217_218.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_217_218.G(quantity = "ThermalConductance", unit = "W/K") = 5.99992070414719e-05 "Constant thermal conductance of material"; Real TC_217_379.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_217_379.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_217_379.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_217_379.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_217_379.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_217_379.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_217_379.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150000000000003 "Constant thermal conductance of material"; Real TC_217_1485.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_217_1485.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_217_1485.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_217_1485.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_217_1485.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_217_1485.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_217_1485.G(quantity = "ThermalConductance", unit = "W/K") = 5.11135092710683e-05 "Constant thermal conductance of material"; Real TC_218_219.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_218_219.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_218_219.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_218_219.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_218_219.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_218_219.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_218_219.G(quantity = "ThermalConductance", unit = "W/K") = 8.57139786795048e-05 "Constant thermal conductance of material"; Real TC_218_380.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_218_380.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_218_380.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_218_380.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_218_380.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_218_380.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_218_380.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150003667705851 "Constant thermal conductance of material"; Real TC_218_1486.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_218_1486.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_218_1486.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_218_1486.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_218_1486.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_218_1486.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_218_1486.G(quantity = "ThermalConductance", unit = "W/K") = 5.11139574389562e-05 "Constant thermal conductance of material"; Real TC_219_220.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_219_220.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_219_220.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_219_220.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_219_220.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_219_220.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_219_220.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200000000000006 "Constant thermal conductance of material"; Real TC_219_381.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_219_381.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_219_381.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_219_381.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_219_381.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_219_381.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_219_381.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600154225786582 "Constant thermal conductance of material"; Real TC_219_1487.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_219_1487.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_219_1487.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_219_1487.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_219_1487.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_219_1487.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_219_1487.G(quantity = "ThermalConductance", unit = "W/K") = 2.04458273821669e-05 "Constant thermal conductance of material"; Real TC_220_222.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_220_222.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_220_222.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_220_222.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_220_222.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_220_222.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_220_222.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_220_382.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_220_382.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_220_382.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_220_382.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_220_382.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_220_382.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_220_382.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029990793650779 "Constant thermal conductance of material"; Real TC_221_223.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_221_223.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_221_223.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_221_223.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_221_223.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_221_223.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_221_223.G(quantity = "ThermalConductance", unit = "W/K") = 4.00001033794751e-05 "Constant thermal conductance of material"; Real TC_221_383.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_221_383.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_221_383.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_221_383.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_221_383.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_221_383.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_221_383.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150020725388592 "Constant thermal conductance of material"; Real TC_221_424.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_221_424.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_221_424.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_221_424.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_221_424.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_221_424.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_221_424.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_221_1477.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_221_1477.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_221_1477.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_221_1477.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_221_1477.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_221_1477.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_221_1477.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600167872779 "Constant thermal conductance of material"; Real TC_222_224.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_222_224.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_222_224.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_222_224.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_222_224.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_222_224.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_222_224.G(quantity = "ThermalConductance", unit = "W/K") = 3.99993443114334e-05 "Constant thermal conductance of material"; Real TC_222_384.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_222_384.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_222_384.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_222_384.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_222_384.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_222_384.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_222_384.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149942611190839 "Constant thermal conductance of material"; Real TC_222_1487.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_222_1487.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_222_1487.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_222_1487.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_222_1487.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_222_1487.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_222_1487.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124599644128114 "Constant thermal conductance of material"; Real TC_223_225.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_223_225.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_223_225.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_223_225.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_223_225.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_223_225.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_223_225.G(quantity = "ThermalConductance", unit = "W/K") = 3.52939526691608e-05 "Constant thermal conductance of material"; Real TC_223_385.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_223_385.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_223_385.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_223_385.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_223_385.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_223_385.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_223_385.G(quantity = "ThermalConductance", unit = "W/K") = 0.00299988719047877 "Constant thermal conductance of material"; Real TC_223_1466.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_223_1466.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_223_1466.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_223_1466.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_223_1466.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_223_1466.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_223_1466.G(quantity = "ThermalConductance", unit = "W/K") = 0.00024920305001226 "Constant thermal conductance of material"; Real TC_224_226.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_224_226.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_224_226.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_224_226.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_224_226.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_224_226.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_224_226.G(quantity = "ThermalConductance", unit = "W/K") = 3.52938436391046e-05 "Constant thermal conductance of material"; Real TC_224_386.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_224_386.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_224_386.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_224_386.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_224_386.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_224_386.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_224_386.G(quantity = "ThermalConductance", unit = "W/K") = 0.00299979533360615 "Constant thermal conductance of material"; Real TC_224_1476.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_224_1476.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_224_1476.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_224_1476.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_224_1476.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_224_1476.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_224_1476.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249199942016703 "Constant thermal conductance of material"; Real TC_225_227.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_225_227.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_225_227.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_225_227.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_225_227.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_225_227.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_225_227.G(quantity = "ThermalConductance", unit = "W/K") = 4.28561263697171e-05 "Constant thermal conductance of material"; Real TC_225_387.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_225_387.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_225_387.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_225_387.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_225_387.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_225_387.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_225_387.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209977973568289 "Constant thermal conductance of material"; Real TC_225_1461.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_225_1461.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_225_1461.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_225_1461.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_225_1461.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_225_1461.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_225_1461.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174438774112857 "Constant thermal conductance of material"; Real TC_226_228.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_226_228.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_226_228.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_226_228.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_226_228.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_226_228.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_226_228.G(quantity = "ThermalConductance", unit = "W/K") = 4.28565536016278e-05 "Constant thermal conductance of material"; Real TC_226_388.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_226_388.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_226_388.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_226_388.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_226_388.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_226_388.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_226_388.G(quantity = "ThermalConductance", unit = "W/K") = 0.00210000642302011 "Constant thermal conductance of material"; Real TC_226_1463.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_226_1463.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_226_1463.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_226_1463.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_226_1463.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_226_1463.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_226_1463.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174441351126447 "Constant thermal conductance of material"; Real TC_227_229.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_227_229.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_227_229.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_227_229.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_227_229.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_227_229.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_227_229.G(quantity = "ThermalConductance", unit = "W/K") = 4.28576051779932e-05 "Constant thermal conductance of material"; Real TC_227_389.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_227_389.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_227_389.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_227_389.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_227_389.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_227_389.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_227_389.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209884868421149 "Constant thermal conductance of material"; Real TC_227_1464.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_227_1464.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_227_1464.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_227_1464.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_227_1464.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_227_1464.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_227_1464.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174440444164871 "Constant thermal conductance of material"; Real TC_228_230.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_228_230.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_228_230.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_228_230.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_228_230.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_228_230.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_228_230.G(quantity = "ThermalConductance", unit = "W/K") = 4.28575923761579e-05 "Constant thermal conductance of material"; Real TC_228_390.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_228_390.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_228_390.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_228_390.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_228_390.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_228_390.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_228_390.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209991117645257 "Constant thermal conductance of material"; Real TC_228_1414.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_228_1414.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_228_1414.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_228_1414.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_228_1414.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_228_1414.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_228_1414.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174440626277582 "Constant thermal conductance of material"; Real TC_229_231.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_229_231.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_229_231.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_229_231.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_229_231.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_229_231.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_229_231.G(quantity = "ThermalConductance", unit = "W/K") = 2.85772357723548e-05 "Constant thermal conductance of material"; Real TC_229_391.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_229_391.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_229_391.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_229_391.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_229_391.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_229_391.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_229_391.G(quantity = "ThermalConductance", unit = "W/K") = 0.00211351063829801 "Constant thermal conductance of material"; Real TC_229_1415.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_229_1415.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_229_1415.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_229_1415.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_229_1415.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_229_1415.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_229_1415.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174442867502792 "Constant thermal conductance of material"; Real TC_230_232.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_230_232.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_230_232.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_230_232.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_230_232.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_230_232.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_230_232.G(quantity = "ThermalConductance", unit = "W/K") = 2.85714285714285e-05 "Constant thermal conductance of material"; Real TC_230_392.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_230_392.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_230_392.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_230_392.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_230_392.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_230_392.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_230_392.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209999248176829 "Constant thermal conductance of material"; Real TC_230_1417.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_230_1417.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_230_1417.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_230_1417.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_230_1417.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_230_1417.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_230_1417.G(quantity = "ThermalConductance", unit = "W/K") = 0.00017444119332088 "Constant thermal conductance of material"; Real TC_231_233.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_231_233.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_231_233.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_231_233.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_231_233.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_231_233.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_231_233.G(quantity = "ThermalConductance", unit = "W/K") = 3.15788533666719e-05 "Constant thermal conductance of material"; Real TC_231_393.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_231_393.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_231_393.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_231_393.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_231_393.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_231_393.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_231_393.G(quantity = "ThermalConductance", unit = "W/K") = 0.00419676746611238 "Constant thermal conductance of material"; Real TC_231_1418.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_231_1418.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_231_1418.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_231_1418.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_231_1418.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_231_1418.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_231_1418.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348880363434744 "Constant thermal conductance of material"; Real TC_232_234.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_232_234.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_232_234.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_232_234.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_232_234.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_232_234.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_232_234.G(quantity = "ThermalConductance", unit = "W/K") = 3.15790897775854e-05 "Constant thermal conductance of material"; Real TC_232_394.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_232_394.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_232_394.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_232_394.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_232_394.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_232_394.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_232_394.G(quantity = "ThermalConductance", unit = "W/K") = 0.00419998295115507 "Constant thermal conductance of material"; Real TC_232_1420.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_232_1420.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_232_1420.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_232_1420.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_232_1420.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_232_1420.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_232_1420.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348891880917271 "Constant thermal conductance of material"; Real TC_233_235.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_233_235.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_233_235.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_233_235.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_233_235.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_233_235.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_233_235.G(quantity = "ThermalConductance", unit = "W/K") = 5.99976523066107e-05 "Constant thermal conductance of material"; Real TC_233_395.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_233_395.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_233_395.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_233_395.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_233_395.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_233_395.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_233_395.G(quantity = "ThermalConductance", unit = "W/K") = 0.0015003325942351 "Constant thermal conductance of material"; Real TC_233_1421.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_233_1421.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_233_1421.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_233_1421.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_233_1421.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_233_1421.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_233_1421.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601868563542 "Constant thermal conductance of material"; Real TC_234_236.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_234_236.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_234_236.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_234_236.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_234_236.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_234_236.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_234_236.G(quantity = "ThermalConductance", unit = "W/K") = 5.99982978723406e-05 "Constant thermal conductance of material"; Real TC_234_396.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_234_396.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_234_396.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_234_396.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_234_396.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_234_396.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_234_396.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014999394045487 "Constant thermal conductance of material"; Real TC_234_1423.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_234_1423.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_234_1423.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_234_1423.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_234_1423.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_234_1423.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_234_1423.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600250814943 "Constant thermal conductance of material"; Real TC_235_237.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_235_237.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_235_237.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_235_237.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_235_237.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_235_237.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_235_237.G(quantity = "ThermalConductance", unit = "W/K") = 6.00060192616376e-05 "Constant thermal conductance of material"; Real TC_235_397.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_235_397.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_235_397.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_235_397.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_235_397.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_235_397.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_235_397.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149817427385822 "Constant thermal conductance of material"; Real TC_235_1424.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_235_1424.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_235_1424.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_235_1424.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_235_1424.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_235_1424.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_235_1424.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600358359976 "Constant thermal conductance of material"; Real TC_236_238.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_236_238.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_236_238.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_236_238.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_236_238.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_236_238.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_236_238.G(quantity = "ThermalConductance", unit = "W/K") = 5.99875816992494e-05 "Constant thermal conductance of material"; Real TC_236_398.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_236_398.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_236_398.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_236_398.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_236_398.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_236_398.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_236_398.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014999933250564 "Constant thermal conductance of material"; Real TC_236_1426.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_236_1426.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_236_1426.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_236_1426.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_236_1426.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_236_1426.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_236_1426.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601662307564 "Constant thermal conductance of material"; Real TC_237_239.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_237_239.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_237_239.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_237_239.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_237_239.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_237_239.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_237_239.G(quantity = "ThermalConductance", unit = "W/K") = 5.99944659656896e-05 "Constant thermal conductance of material"; Real TC_237_399.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_237_399.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_237_399.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_237_399.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_237_399.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_237_399.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_237_399.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014975781249985 "Constant thermal conductance of material"; Real TC_237_1427.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_237_1427.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_237_1427.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_237_1427.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_237_1427.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_237_1427.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_237_1427.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124598830348239 "Constant thermal conductance of material"; Real TC_238_240.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_238_240.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_238_240.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_238_240.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_238_240.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_238_240.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_238_240.G(quantity = "ThermalConductance", unit = "W/K") = 6.00008133387541e-05 "Constant thermal conductance of material"; Real TC_238_400.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_238_400.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_238_400.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_238_400.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_238_400.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_238_400.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_238_400.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149996657530583 "Constant thermal conductance of material"; Real TC_238_1429.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_238_1429.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_238_1429.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_238_1429.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_238_1429.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_238_1429.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_238_1429.G(quantity = "ThermalConductance", unit = "W/K") = 0.00012460029996633 "Constant thermal conductance of material"; Real TC_239_241.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_239_241.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_239_241.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_239_241.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_239_241.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_239_241.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_239_241.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000005e-05 "Constant thermal conductance of material"; Real TC_239_401.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_239_401.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_239_401.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_239_401.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_239_401.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_239_401.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_239_401.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150038759689886 "Constant thermal conductance of material"; Real TC_239_1430.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_239_1430.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_239_1430.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_239_1430.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_239_1430.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_239_1430.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_239_1430.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124602774220532 "Constant thermal conductance of material"; Real TC_240_242.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_240_242.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_240_242.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_240_242.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_240_242.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_240_242.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_240_242.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000002e-05 "Constant thermal conductance of material"; Real TC_240_402.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_240_402.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_240_402.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_240_402.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_240_402.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_240_402.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_240_402.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150004024792724 "Constant thermal conductance of material"; Real TC_240_1432.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_240_1432.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_240_1432.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_240_1432.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_240_1432.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_240_1432.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_240_1432.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601098237645 "Constant thermal conductance of material"; Real TC_241_243.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_241_243.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_241_243.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_241_243.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_241_243.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_241_243.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_241_243.G(quantity = "ThermalConductance", unit = "W/K") = 6.00005616715347e-05 "Constant thermal conductance of material"; Real TC_241_403.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_241_403.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_241_403.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_241_403.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_241_403.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_241_403.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_241_403.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150024291497959 "Constant thermal conductance of material"; Real TC_241_1433.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_241_1433.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_241_1433.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_241_1433.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_241_1433.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_241_1433.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_241_1433.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600942207803 "Constant thermal conductance of material"; Real TC_242_244.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_242_244.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_242_244.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_242_244.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_242_244.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_242_244.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_242_244.G(quantity = "ThermalConductance", unit = "W/K") = 5.99999999999999e-05 "Constant thermal conductance of material"; Real TC_242_404.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_242_404.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_242_404.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_242_404.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_242_404.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_242_404.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_242_404.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149997996821624 "Constant thermal conductance of material"; Real TC_242_1435.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_242_1435.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_242_1435.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_242_1435.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_242_1435.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_242_1435.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_242_1435.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600009845911 "Constant thermal conductance of material"; Real TC_243_245.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_243_245.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_243_245.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_243_245.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_243_245.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_243_245.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_243_245.G(quantity = "ThermalConductance", unit = "W/K") = 2.9999832431255e-05 "Constant thermal conductance of material"; Real TC_243_405.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_243_405.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_243_405.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_243_405.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_243_405.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_243_405.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_243_405.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149991233837379 "Constant thermal conductance of material"; Real TC_243_1436.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_243_1436.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_243_1436.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_243_1436.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_243_1436.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_243_1436.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_243_1436.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601599349298 "Constant thermal conductance of material"; Real TC_244_246.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_244_246.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_244_246.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_244_246.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_244_246.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_244_246.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_244_246.G(quantity = "ThermalConductance", unit = "W/K") = 3.00006863836732e-05 "Constant thermal conductance of material"; Real TC_244_406.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_244_406.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_244_406.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_244_406.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_244_406.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_244_406.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_244_406.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150004926039043 "Constant thermal conductance of material"; Real TC_244_1438.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_244_1438.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_244_1438.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_244_1438.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_244_1438.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_244_1438.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_244_1438.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601027449311 "Constant thermal conductance of material"; Real TC_245_247.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_245_247.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_245_247.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_245_247.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_245_247.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_245_247.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_245_247.G(quantity = "ThermalConductance", unit = "W/K") = 3.00003428120875e-05 "Constant thermal conductance of material"; Real TC_245_407.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_245_407.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_245_407.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_245_407.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_245_407.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_245_407.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_245_407.G(quantity = "ThermalConductance", unit = "W/K") = 0.00449989872392144 "Constant thermal conductance of material"; Real TC_245_1439.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_245_1439.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_245_1439.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_245_1439.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_245_1439.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_245_1439.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_245_1439.G(quantity = "ThermalConductance", unit = "W/K") = 0.000373801769339155 "Constant thermal conductance of material"; Real TC_246_248.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_246_248.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_246_248.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_246_248.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_246_248.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_246_248.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_246_248.G(quantity = "ThermalConductance", unit = "W/K") = 3.00007892758187e-05 "Constant thermal conductance of material"; Real TC_246_408.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_246_408.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_246_408.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_246_408.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_246_408.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_246_408.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_246_408.G(quantity = "ThermalConductance", unit = "W/K") = 0.00449969102425454 "Constant thermal conductance of material"; Real TC_246_1449.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_246_1449.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_246_1449.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_246_1449.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_246_1449.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_246_1449.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_246_1449.G(quantity = "ThermalConductance", unit = "W/K") = 0.000373803242047536 "Constant thermal conductance of material"; Real TC_247_249.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_247_249.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_247_249.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_247_249.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_247_249.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_247_249.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_247_249.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_247_409.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_247_409.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_247_409.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_247_409.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_247_409.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_247_409.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_247_409.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150045682960262 "Constant thermal conductance of material"; Real TC_247_1450.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_247_1450.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_247_1450.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_247_1450.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_247_1450.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_247_1450.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_247_1450.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124602739726027 "Constant thermal conductance of material"; Real TC_248_261.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_248_261.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_248_261.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_248_261.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_248_261.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_248_261.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_248_261.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_248_410.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_248_410.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_248_410.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_248_410.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_248_410.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_248_410.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_248_410.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149945567651634 "Constant thermal conductance of material"; Real TC_248_1460.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_248_1460.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_248_1460.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_248_1460.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_248_1460.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_248_1460.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_248_1460.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124602943126077 "Constant thermal conductance of material"; Real TC_249_250.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_249_250.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_249_250.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_249_250.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_249_250.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_249_250.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_249_250.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200017433751746 "Constant thermal conductance of material"; Real TC_249_411.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_249_411.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_249_411.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_249_411.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_249_411.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_249_411.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_249_411.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300209617755912 "Constant thermal conductance of material"; Real TC_250_251.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_250_251.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_250_251.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_250_251.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_250_251.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_250_251.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_250_251.G(quantity = "ThermalConductance", unit = "W/K") = 8.57146264669405e-05 "Constant thermal conductance of material"; Real TC_250_412.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_250_412.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_250_412.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_250_412.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_250_412.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_250_412.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_250_412.G(quantity = "ThermalConductance", unit = "W/K") = 0.00060007858546165 "Constant thermal conductance of material"; Real TC_250_1450.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_250_1450.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_250_1450.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_250_1450.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_250_1450.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_250_1450.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_250_1450.G(quantity = "ThermalConductance", unit = "W/K") = 2.044551003682e-05 "Constant thermal conductance of material"; Real TC_251_252.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_251_252.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_251_252.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_251_252.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_251_252.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_251_252.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_251_252.G(quantity = "ThermalConductance", unit = "W/K") = 6e-05 "Constant thermal conductance of material"; Real TC_251_413.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_251_413.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_251_413.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_251_413.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_251_413.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_251_413.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_251_413.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150003827018761 "Constant thermal conductance of material"; Real TC_251_1451.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_251_1451.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_251_1451.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_251_1451.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_251_1451.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_251_1451.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_251_1451.G(quantity = "ThermalConductance", unit = "W/K") = 5.11137857252024e-05 "Constant thermal conductance of material"; Real TC_252_253.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_252_253.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_252_253.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_252_253.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_252_253.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_252_253.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_252_253.G(quantity = "ThermalConductance", unit = "W/K") = 5.99973352282815e-05 "Constant thermal conductance of material"; Real TC_252_414.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_252_414.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_252_414.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_252_414.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_252_414.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_252_414.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_252_414.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150028442758955 "Constant thermal conductance of material"; Real TC_252_1452.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_252_1452.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_252_1452.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_252_1452.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_252_1452.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_252_1452.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_252_1452.G(quantity = "ThermalConductance", unit = "W/K") = 5.11138108241769e-05 "Constant thermal conductance of material"; Real TC_253_254.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_253_254.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_253_254.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_253_254.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_253_254.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_253_254.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_253_254.G(quantity = "ThermalConductance", unit = "W/K") = 6.00012906556548e-05 "Constant thermal conductance of material"; Real TC_253_415.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_253_415.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_253_415.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_253_415.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_253_415.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_253_415.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_253_415.G(quantity = "ThermalConductance", unit = "W/K") = 0.0015002273666804 "Constant thermal conductance of material"; Real TC_253_1453.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_253_1453.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_253_1453.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_253_1453.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_253_1453.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_253_1453.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_253_1453.G(quantity = "ThermalConductance", unit = "W/K") = 5.11137175068849e-05 "Constant thermal conductance of material"; Real TC_254_255.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_254_255.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_254_255.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_254_255.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_254_255.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_254_255.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_254_255.G(quantity = "ThermalConductance", unit = "W/K") = 6.0079545454637e-05 "Constant thermal conductance of material"; Real TC_254_416.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_254_416.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_254_416.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_254_416.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_254_416.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_254_416.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_254_416.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150009946290041 "Constant thermal conductance of material"; Real TC_254_1454.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_254_1454.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_254_1454.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_254_1454.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_254_1454.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_254_1454.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_254_1454.G(quantity = "ThermalConductance", unit = "W/K") = 5.11140437812273e-05 "Constant thermal conductance of material"; Real TC_255_256.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_255_256.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_255_256.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_255_256.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_255_256.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_255_256.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_255_256.G(quantity = "ThermalConductance", unit = "W/K") = 6.0003835826619e-05 "Constant thermal conductance of material"; Real TC_255_417.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_255_417.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_255_417.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_255_417.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_255_417.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_255_417.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_255_417.G(quantity = "ThermalConductance", unit = "W/K") = 0.0015000586739683 "Constant thermal conductance of material"; Real TC_255_1455.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_255_1455.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_255_1455.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_255_1455.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_255_1455.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_255_1455.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_255_1455.G(quantity = "ThermalConductance", unit = "W/K") = 5.11141514791678e-05 "Constant thermal conductance of material"; Real TC_256_257.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_256_257.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_256_257.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_256_257.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_256_257.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_256_257.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_256_257.G(quantity = "ThermalConductance", unit = "W/K") = 6.00008857395927e-05 "Constant thermal conductance of material"; Real TC_256_418.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_256_418.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_256_418.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_256_418.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_256_418.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_256_418.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_256_418.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149982554758672 "Constant thermal conductance of material"; Real TC_256_1456.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_256_1456.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_256_1456.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_256_1456.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_256_1456.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_256_1456.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_256_1456.G(quantity = "ThermalConductance", unit = "W/K") = 5.1114124058092e-05 "Constant thermal conductance of material"; Real TC_257_258.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_257_258.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_257_258.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_257_258.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_257_258.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_257_258.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_257_258.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000001e-05 "Constant thermal conductance of material"; Real TC_257_419.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_257_419.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_257_419.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_257_419.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_257_419.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_257_419.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_257_419.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149988265206335 "Constant thermal conductance of material"; Real TC_257_1457.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_257_1457.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_257_1457.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_257_1457.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_257_1457.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_257_1457.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_257_1457.G(quantity = "ThermalConductance", unit = "W/K") = 5.11142563319657e-05 "Constant thermal conductance of material"; Real TC_258_259.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_258_259.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_258_259.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_258_259.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_258_259.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_258_259.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_258_259.G(quantity = "ThermalConductance", unit = "W/K") = 5.99986304809292e-05 "Constant thermal conductance of material"; Real TC_258_420.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_258_420.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_258_420.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_258_420.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_258_420.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_258_420.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_258_420.G(quantity = "ThermalConductance", unit = "W/K") = 0.0015000422654268 "Constant thermal conductance of material"; Real TC_258_1458.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_258_1458.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_258_1458.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_258_1458.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_258_1458.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_258_1458.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_258_1458.G(quantity = "ThermalConductance", unit = "W/K") = 5.11136988266979e-05 "Constant thermal conductance of material"; Real TC_259_260.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_259_260.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_259_260.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_259_260.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_259_260.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_259_260.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_259_260.G(quantity = "ThermalConductance", unit = "W/K") = 8.57135723559372e-05 "Constant thermal conductance of material"; Real TC_259_421.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_259_421.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_259_421.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_259_421.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_259_421.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_259_421.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_259_421.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149988561624259 "Constant thermal conductance of material"; Real TC_259_1459.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_259_1459.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_259_1459.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_259_1459.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_259_1459.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_259_1459.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_259_1459.G(quantity = "ThermalConductance", unit = "W/K") = 5.11138709428329e-05 "Constant thermal conductance of material"; Real TC_260_261.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_260_261.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_260_261.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_260_261.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_260_261.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_260_261.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_260_261.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200019087612143 "Constant thermal conductance of material"; Real TC_260_422.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_260_422.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_260_422.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_260_422.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_260_422.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_260_422.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_260_422.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599954001839991 "Constant thermal conductance of material"; Real TC_260_1460.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_260_1460.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_260_1460.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_260_1460.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_260_1460.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_260_1460.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_260_1460.G(quantity = "ThermalConductance", unit = "W/K") = 2.04462864157318e-05 "Constant thermal conductance of material"; Real TC_261_423.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_261_423.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_261_423.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_261_423.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_261_423.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_261_423.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_261_423.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300798165137727 "Constant thermal conductance of material"; Real TC_262_263.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_262_263.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_262_263.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_262_263.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_262_263.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_262_263.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_262_263.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200014079549473 "Constant thermal conductance of material"; Real TC_262_275.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_262_275.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_262_275.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_262_275.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_262_275.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_262_275.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_262_275.G(quantity = "ThermalConductance", unit = "W/K") = 0.000100001696151433 "Constant thermal conductance of material"; Real TC_262_316.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_262_316.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_262_316.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_262_316.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_262_316.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_262_316.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_262_316.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300437375745654 "Constant thermal conductance of material"; Real TC_262_425.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_262_425.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_262_425.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_262_425.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_262_425.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_262_425.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_262_425.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299965870307157 "Constant thermal conductance of material"; Real TC_263_264.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_263_264.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_263_264.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_263_264.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_263_264.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_263_264.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_263_264.G(quantity = "ThermalConductance", unit = "W/K") = 8.57151998634869e-05 "Constant thermal conductance of material"; Real TC_263_317.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_263_317.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_263_317.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_263_317.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_263_317.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_263_317.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_263_317.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600561959654164 "Constant thermal conductance of material"; Real TC_263_426.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_263_426.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_263_426.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_263_426.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_263_426.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_263_426.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_263_426.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600062959076724 "Constant thermal conductance of material"; Real TC_263_1099.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_263_1099.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_263_1099.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_263_1099.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_263_1099.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_263_1099.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_263_1099.G(quantity = "ThermalConductance", unit = "W/K") = 2.04457606195317e-05 "Constant thermal conductance of material"; Real TC_264_265.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_264_265.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_264_265.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_264_265.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_264_265.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_264_265.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_264_265.G(quantity = "ThermalConductance", unit = "W/K") = 6.00007884725315e-05 "Constant thermal conductance of material"; Real TC_264_318.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_264_318.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_264_318.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_264_318.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_264_318.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_264_318.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_264_318.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149921397380006 "Constant thermal conductance of material"; Real TC_264_427.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_264_427.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_264_427.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_264_427.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_264_427.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_264_427.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_264_427.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149990579368823 "Constant thermal conductance of material"; Real TC_264_1100.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_264_1100.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_264_1100.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_264_1100.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_264_1100.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_264_1100.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_264_1100.G(quantity = "ThermalConductance", unit = "W/K") = 5.11129829600376e-05 "Constant thermal conductance of material"; Real TC_265_266.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_265_266.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_265_266.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_265_266.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_265_266.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_265_266.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_265_266.G(quantity = "ThermalConductance", unit = "W/K") = 6e-05 "Constant thermal conductance of material"; Real TC_265_319.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_265_319.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_265_319.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_265_319.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_265_319.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_265_319.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_265_319.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150024958402666 "Constant thermal conductance of material"; Real TC_265_428.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_265_428.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_265_428.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_265_428.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_265_428.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_265_428.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_265_428.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150015191796421 "Constant thermal conductance of material"; Real TC_265_1101.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_265_1101.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_265_1101.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_265_1101.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_265_1101.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_265_1101.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_265_1101.G(quantity = "ThermalConductance", unit = "W/K") = 5.11144694440951e-05 "Constant thermal conductance of material"; Real TC_266_267.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_266_267.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_266_267.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_266_267.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_266_267.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_266_267.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_266_267.G(quantity = "ThermalConductance", unit = "W/K") = 6.00026171159373e-05 "Constant thermal conductance of material"; Real TC_266_320.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_266_320.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_266_320.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_266_320.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_266_320.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_266_320.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_266_320.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150062695924764 "Constant thermal conductance of material"; Real TC_266_429.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_266_429.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_266_429.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_266_429.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_266_429.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_266_429.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_266_429.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150007181328541 "Constant thermal conductance of material"; Real TC_266_1102.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_266_1102.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_266_1102.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_266_1102.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_266_1102.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_266_1102.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_266_1102.G(quantity = "ThermalConductance", unit = "W/K") = 5.11136822083437e-05 "Constant thermal conductance of material"; Real TC_267_268.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_267_268.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_267_268.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_267_268.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_267_268.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_267_268.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_267_268.G(quantity = "ThermalConductance", unit = "W/K") = 5.99960830395617e-05 "Constant thermal conductance of material"; Real TC_267_321.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_267_321.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_267_321.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_267_321.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_267_321.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_267_321.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_267_321.G(quantity = "ThermalConductance", unit = "W/K") = 0.001499875311721 "Constant thermal conductance of material"; Real TC_267_430.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_267_430.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_267_430.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_267_430.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_267_430.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_267_430.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_267_430.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150025849335294 "Constant thermal conductance of material"; Real TC_267_1103.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_267_1103.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_267_1103.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_267_1103.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_267_1103.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_267_1103.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_267_1103.G(quantity = "ThermalConductance", unit = "W/K") = 5.11131814823144e-05 "Constant thermal conductance of material"; Real TC_268_269.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_268_269.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_268_269.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_268_269.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_268_269.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_268_269.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_268_269.G(quantity = "ThermalConductance", unit = "W/K") = 6.00024177949696e-05 "Constant thermal conductance of material"; Real TC_268_322.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_268_322.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_268_322.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_268_322.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_268_322.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_268_322.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_268_322.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150006365372388 "Constant thermal conductance of material"; Real TC_268_431.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_268_431.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_268_431.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_268_431.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_268_431.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_268_431.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_268_431.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149969765684051 "Constant thermal conductance of material"; Real TC_268_1104.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_268_1104.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_268_1104.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_268_1104.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_268_1104.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_268_1104.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_268_1104.G(quantity = "ThermalConductance", unit = "W/K") = 5.11146323904974e-05 "Constant thermal conductance of material"; Real TC_269_270.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_269_270.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_269_270.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_269_270.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_269_270.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_269_270.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_269_270.G(quantity = "ThermalConductance", unit = "W/K") = 6.00016662501042e-05 "Constant thermal conductance of material"; Real TC_269_323.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_269_323.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_269_323.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_269_323.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_269_323.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_269_323.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_269_323.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014999999999999 "Constant thermal conductance of material"; Real TC_269_432.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_269_432.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_269_432.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_269_432.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_269_432.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_269_432.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_269_432.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149988755622195 "Constant thermal conductance of material"; Real TC_269_1105.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_269_1105.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_269_1105.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_269_1105.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_269_1105.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_269_1105.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_269_1105.G(quantity = "ThermalConductance", unit = "W/K") = 5.11136123471086e-05 "Constant thermal conductance of material"; Real TC_270_271.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_270_271.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_270_271.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_270_271.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_270_271.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_270_271.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_270_271.G(quantity = "ThermalConductance", unit = "W/K") = 5.99999999999997e-05 "Constant thermal conductance of material"; Real TC_270_324.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_270_324.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_270_324.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_270_324.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_270_324.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_270_324.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_270_324.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149994096812295 "Constant thermal conductance of material"; Real TC_270_433.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_270_433.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_270_433.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_270_433.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_270_433.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_270_433.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_270_433.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149999999999999 "Constant thermal conductance of material"; Real TC_270_1106.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_270_1106.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_270_1106.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_270_1106.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_270_1106.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_270_1106.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_270_1106.G(quantity = "ThermalConductance", unit = "W/K") = 5.11133582520337e-05 "Constant thermal conductance of material"; Real TC_271_272.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_271_272.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_271_272.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_271_272.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_271_272.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_271_272.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_271_272.G(quantity = "ThermalConductance", unit = "W/K") = 6.0000420229866e-05 "Constant thermal conductance of material"; Real TC_271_325.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_271_325.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_271_325.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_271_325.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_271_325.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_271_325.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_271_325.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149994124559322 "Constant thermal conductance of material"; Real TC_271_434.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_271_434.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_271_434.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_271_434.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_271_434.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_271_434.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_271_434.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149996647670128 "Constant thermal conductance of material"; Real TC_271_1107.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_271_1107.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_271_1107.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_271_1107.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_271_1107.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_271_1107.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_271_1107.G(quantity = "ThermalConductance", unit = "W/K") = 5.11146142977532e-05 "Constant thermal conductance of material"; Real TC_272_273.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_272_273.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_272_273.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_272_273.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_272_273.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_272_273.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_272_273.G(quantity = "ThermalConductance", unit = "W/K") = 8.57146058853849e-05 "Constant thermal conductance of material"; Real TC_272_326.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_272_326.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_272_326.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_272_326.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_272_326.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_272_326.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_272_326.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150000000000009 "Constant thermal conductance of material"; Real TC_272_435.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_272_435.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_272_435.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_272_435.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_272_435.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_272_435.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_272_435.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150006846970202 "Constant thermal conductance of material"; Real TC_272_1108.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_272_1108.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_272_1108.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_272_1108.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_272_1108.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_272_1108.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_272_1108.G(quantity = "ThermalConductance", unit = "W/K") = 5.11144026778321e-05 "Constant thermal conductance of material"; Real TC_273_274.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_273_274.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_273_274.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_273_274.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_273_274.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_273_274.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_273_274.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199984552008237 "Constant thermal conductance of material"; Real TC_273_327.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_273_327.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_273_327.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_273_327.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_273_327.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_273_327.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_273_327.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599920098340553 "Constant thermal conductance of material"; Real TC_273_436.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_273_436.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_273_436.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_273_436.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_273_436.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_273_436.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_273_436.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600056818181884 "Constant thermal conductance of material"; Real TC_273_1109.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_273_1109.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_273_1109.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_273_1109.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_273_1109.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_273_1109.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_273_1109.G(quantity = "ThermalConductance", unit = "W/K") = 2.04459503625098e-05 "Constant thermal conductance of material"; Real TC_274_276.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_274_276.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_274_276.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_274_276.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_274_276.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_274_276.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_274_276.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_274_328.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_274_328.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_274_328.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_274_328.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_274_328.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_274_328.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_274_328.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300095108695642 "Constant thermal conductance of material"; Real TC_274_437.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_274_437.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_274_437.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_274_437.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_274_437.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_274_437.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_274_437.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299970916141533 "Constant thermal conductance of material"; Real TC_275_277.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_275_277.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_275_277.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_275_277.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_275_277.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_275_277.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_275_277.G(quantity = "ThermalConductance", unit = "W/K") = 3.99993515621562e-05 "Constant thermal conductance of material"; Real TC_275_329.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_275_329.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_275_329.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_275_329.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_275_329.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_275_329.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_275_329.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150020304568526 "Constant thermal conductance of material"; Real TC_275_438.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_275_438.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_275_438.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_275_438.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_275_438.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_275_438.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_275_438.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150032813781784 "Constant thermal conductance of material"; Real TC_275_1099.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_275_1099.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_275_1099.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_275_1099.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_275_1099.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_275_1099.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_275_1099.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124602442333786 "Constant thermal conductance of material"; Real TC_276_278.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_276_278.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_276_278.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_276_278.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_276_278.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_276_278.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_276_278.G(quantity = "ThermalConductance", unit = "W/K") = 3.9999645922913e-05 "Constant thermal conductance of material"; Real TC_276_330.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_276_330.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_276_330.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_276_330.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_276_330.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_276_330.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_276_330.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149945778466287 "Constant thermal conductance of material"; Real TC_276_439.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_276_439.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_276_439.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_276_439.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_276_439.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_276_439.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_276_439.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150023510971786 "Constant thermal conductance of material"; Real TC_276_1109.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_276_1109.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_276_1109.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_276_1109.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_276_1109.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_276_1109.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_276_1109.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124596707134542 "Constant thermal conductance of material"; Real TC_277_279.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_277_279.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_277_279.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_277_279.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_277_279.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_277_279.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_277_279.G(quantity = "ThermalConductance", unit = "W/K") = 3.52939904106132e-05 "Constant thermal conductance of material"; Real TC_277_331.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_277_331.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_277_331.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_277_331.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_277_331.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_277_331.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_277_331.G(quantity = "ThermalConductance", unit = "W/K") = 0.00300009673986635 "Constant thermal conductance of material"; Real TC_277_440.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_277_440.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_277_440.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_277_440.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_277_440.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_277_440.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_277_440.G(quantity = "ThermalConductance", unit = "W/K") = 0.00300005463286704 "Constant thermal conductance of material"; Real TC_277_1110.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_277_1110.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_277_1110.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_277_1110.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_277_1110.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_277_1110.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_277_1110.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249195814161814 "Constant thermal conductance of material"; Real TC_278_280.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_278_280.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_278_280.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_278_280.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_278_280.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_278_280.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_278_280.G(quantity = "ThermalConductance", unit = "W/K") = 3.52938460500286e-05 "Constant thermal conductance of material"; Real TC_278_332.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_278_332.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_278_332.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_278_332.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_278_332.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_278_332.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_278_332.G(quantity = "ThermalConductance", unit = "W/K") = 0.0029998817966905 "Constant thermal conductance of material"; Real TC_278_441.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_278_441.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_278_441.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_278_441.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_278_441.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_278_441.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_278_441.G(quantity = "ThermalConductance", unit = "W/K") = 0.00300000000000002 "Constant thermal conductance of material"; Real TC_278_1111.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_278_1111.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_278_1111.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_278_1111.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_278_1111.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_278_1111.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_278_1111.G(quantity = "ThermalConductance", unit = "W/K") = 0.00024920083723824 "Constant thermal conductance of material"; Real TC_279_281.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_279_281.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_279_281.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_279_281.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_279_281.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_279_281.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_279_281.G(quantity = "ThermalConductance", unit = "W/K") = 4.28583426651737e-05 "Constant thermal conductance of material"; Real TC_279_333.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_279_333.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_279_333.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_279_333.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_279_333.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_279_333.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_279_333.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209849137931106 "Constant thermal conductance of material"; Real TC_279_442.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_279_442.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_279_442.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_279_442.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_279_442.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_279_442.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_279_442.G(quantity = "ThermalConductance", unit = "W/K") = 0.00210001858390634 "Constant thermal conductance of material"; Real TC_279_1112.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_279_1112.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_279_1112.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_279_1112.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_279_1112.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_279_1112.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_279_1112.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174442554684091 "Constant thermal conductance of material"; Real TC_280_282.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_280_282.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_280_282.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_280_282.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_280_282.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_280_282.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_280_282.G(quantity = "ThermalConductance", unit = "W/K") = 4.28564344980329e-05 "Constant thermal conductance of material"; Real TC_280_334.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_280_334.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_280_334.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_280_334.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_280_334.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_280_334.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_280_334.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209992801136253 "Constant thermal conductance of material"; Real TC_280_443.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_280_443.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_280_443.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_280_443.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_280_443.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_280_443.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_280_443.G(quantity = "ThermalConductance", unit = "W/K") = 0.0020999969354295 "Constant thermal conductance of material"; Real TC_280_1113.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_280_1113.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_280_1113.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_280_1113.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_280_1113.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_280_1113.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_280_1113.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174445817283233 "Constant thermal conductance of material"; Real TC_281_283.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_281_283.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_281_283.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_281_283.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_281_283.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_281_283.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_281_283.G(quantity = "ThermalConductance", unit = "W/K") = 4.2851593892311e-05 "Constant thermal conductance of material"; Real TC_281_335.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_281_335.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_281_335.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_281_335.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_281_335.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_281_335.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_281_335.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209950544015831 "Constant thermal conductance of material"; Real TC_281_444.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_281_444.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_281_444.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_281_444.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_281_444.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_281_444.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_281_444.G(quantity = "ThermalConductance", unit = "W/K") = 0.0021000452851221 "Constant thermal conductance of material"; Real TC_281_1114.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_281_1114.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_281_1114.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_281_1114.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_281_1114.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_281_1114.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_281_1114.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174441296906513 "Constant thermal conductance of material"; Real TC_282_284.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_282_284.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_282_284.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_282_284.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_282_284.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_282_284.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_282_284.G(quantity = "ThermalConductance", unit = "W/K") = 4.28586451184426e-05 "Constant thermal conductance of material"; Real TC_282_336.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_282_336.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_282_336.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_282_336.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_282_336.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_282_336.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_282_336.G(quantity = "ThermalConductance", unit = "W/K") = 0.00210006044874304 "Constant thermal conductance of material"; Real TC_282_445.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_282_445.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_282_445.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_282_445.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_282_445.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_282_445.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_282_445.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209996275391799 "Constant thermal conductance of material"; Real TC_282_1115.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_282_1115.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_282_1115.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_282_1115.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_282_1115.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_282_1115.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_282_1115.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174438631459014 "Constant thermal conductance of material"; Real TC_283_285.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_283_285.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_283_285.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_283_285.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_283_285.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_283_285.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_283_285.G(quantity = "ThermalConductance", unit = "W/K") = 2.85661283282415e-05 "Constant thermal conductance of material"; Real TC_283_337.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_283_337.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_283_337.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_283_337.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_283_337.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_283_337.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_283_337.G(quantity = "ThermalConductance", unit = "W/K") = 0.00210016474464582 "Constant thermal conductance of material"; Real TC_283_446.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_283_446.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_283_446.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_283_446.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_283_446.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_283_446.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_283_446.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209995202850877 "Constant thermal conductance of material"; Real TC_283_1116.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_283_1116.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_283_1116.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_283_1116.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_283_1116.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_283_1116.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_283_1116.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174435983495462 "Constant thermal conductance of material"; Real TC_284_286.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_284_286.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_284_286.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_284_286.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_284_286.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_284_286.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_284_286.G(quantity = "ThermalConductance", unit = "W/K") = 2.85695399259651e-05 "Constant thermal conductance of material"; Real TC_284_338.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_284_338.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_284_338.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_284_338.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_284_338.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_284_338.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_284_338.G(quantity = "ThermalConductance", unit = "W/K") = 0.00210001557875057 "Constant thermal conductance of material"; Real TC_284_447.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_284_447.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_284_447.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_284_447.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_284_447.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_284_447.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_284_447.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209995929767437 "Constant thermal conductance of material"; Real TC_284_1117.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_284_1117.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_284_1117.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_284_1117.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_284_1117.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_284_1117.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_284_1117.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174442705344511 "Constant thermal conductance of material"; Real TC_285_287.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_285_287.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_285_287.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_285_287.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_285_287.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_285_287.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_285_287.G(quantity = "ThermalConductance", unit = "W/K") = 3.15772017107444e-05 "Constant thermal conductance of material"; Real TC_285_339.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_285_339.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_285_339.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_285_339.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_285_339.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_285_339.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_285_339.G(quantity = "ThermalConductance", unit = "W/K") = 0.00419914874551961 "Constant thermal conductance of material"; Real TC_285_448.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_285_448.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_285_448.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_285_448.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_285_448.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_285_448.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_285_448.G(quantity = "ThermalConductance", unit = "W/K") = 0.00419992552723328 "Constant thermal conductance of material"; Real TC_285_1118.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_285_1118.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_285_1118.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_285_1118.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_285_1118.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_285_1118.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_285_1118.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348877686168184 "Constant thermal conductance of material"; Real TC_286_288.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_286_288.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_286_288.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_286_288.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_286_288.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_286_288.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_286_288.G(quantity = "ThermalConductance", unit = "W/K") = 3.15790450042663e-05 "Constant thermal conductance of material"; Real TC_286_340.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_286_340.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_286_340.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_286_340.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_286_340.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_286_340.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_286_340.G(quantity = "ThermalConductance", unit = "W/K") = 0.00420009453798631 "Constant thermal conductance of material"; Real TC_286_449.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_286_449.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_286_449.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_286_449.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_286_449.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_286_449.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_286_449.G(quantity = "ThermalConductance", unit = "W/K") = 0.00419999192930069 "Constant thermal conductance of material"; Real TC_286_1119.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_286_1119.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_286_1119.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_286_1119.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_286_1119.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_286_1119.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_286_1119.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348881792921106 "Constant thermal conductance of material"; Real TC_287_289.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_287_289.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_287_289.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_287_289.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_287_289.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_287_289.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_287_289.G(quantity = "ThermalConductance", unit = "W/K") = 5.99989898989919e-05 "Constant thermal conductance of material"; Real TC_287_341.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_287_341.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_287_341.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_287_341.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_287_341.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_287_341.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_287_341.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150009107468124 "Constant thermal conductance of material"; Real TC_287_450.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_287_450.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_287_450.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_287_450.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_287_450.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_287_450.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_287_450.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149998317008312 "Constant thermal conductance of material"; Real TC_287_1120.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_287_1120.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_287_1120.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_287_1120.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_287_1120.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_287_1120.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_287_1120.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601252930551 "Constant thermal conductance of material"; Real TC_288_290.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_288_290.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_288_290.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_288_290.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_288_290.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_288_290.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_288_290.G(quantity = "ThermalConductance", unit = "W/K") = 6.00027990296699e-05 "Constant thermal conductance of material"; Real TC_288_342.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_288_342.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_288_342.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_288_342.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_288_342.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_288_342.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_288_342.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150000780165083 "Constant thermal conductance of material"; Real TC_288_451.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_288_451.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_288_451.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_288_451.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_288_451.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_288_451.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_288_451.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149999345266935 "Constant thermal conductance of material"; Real TC_288_1121.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_288_1121.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_288_1121.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_288_1121.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_288_1121.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_288_1121.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_288_1121.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600981117018 "Constant thermal conductance of material"; Real TC_289_291.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_289_291.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_289_291.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_289_291.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_289_291.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_289_291.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_289_291.G(quantity = "ThermalConductance", unit = "W/K") = 6.00031000542509e-05 "Constant thermal conductance of material"; Real TC_289_343.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_289_343.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_289_343.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_289_343.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_289_343.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_289_343.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_289_343.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150007614213196 "Constant thermal conductance of material"; Real TC_289_452.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_289_452.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_289_452.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_289_452.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_289_452.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_289_452.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_289_452.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149994915771279 "Constant thermal conductance of material"; Real TC_289_1122.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_289_1122.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_289_1122.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_289_1122.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_289_1122.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_289_1122.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_289_1122.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600009779048 "Constant thermal conductance of material"; Real TC_290_292.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_290_292.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_290_292.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_290_292.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_290_292.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_290_292.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_290_292.G(quantity = "ThermalConductance", unit = "W/K") = 5.9980253878719e-05 "Constant thermal conductance of material"; Real TC_290_344.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_290_344.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_290_344.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_290_344.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_290_344.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_290_344.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_290_344.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149998440278254 "Constant thermal conductance of material"; Real TC_290_453.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_290_453.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_290_453.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_290_453.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_290_453.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_290_453.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_290_453.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150000657609195 "Constant thermal conductance of material"; Real TC_290_1123.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_290_1123.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_290_1123.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_290_1123.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_290_1123.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_290_1123.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_290_1123.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601245078496 "Constant thermal conductance of material"; Real TC_291_293.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_291_293.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_291_293.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_291_293.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_291_293.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_291_293.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_291_293.G(quantity = "ThermalConductance", unit = "W/K") = 5.99964853703537e-05 "Constant thermal conductance of material"; Real TC_291_345.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_291_345.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_291_345.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_291_345.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_291_345.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_291_345.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_291_345.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149996570644732 "Constant thermal conductance of material"; Real TC_291_454.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_291_454.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_291_454.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_291_454.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_291_454.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_291_454.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_291_454.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150003477051462 "Constant thermal conductance of material"; Real TC_291_1124.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_291_1124.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_291_1124.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_291_1124.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_291_1124.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_291_1124.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_291_1124.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601027896611 "Constant thermal conductance of material"; Real TC_292_294.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_292_294.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_292_294.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_292_294.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_292_294.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_292_294.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_292_294.G(quantity = "ThermalConductance", unit = "W/K") = 6.00008549931606e-05 "Constant thermal conductance of material"; Real TC_292_346.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_292_346.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_292_346.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_292_346.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_292_346.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_292_346.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_292_346.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150001566219772 "Constant thermal conductance of material"; Real TC_292_455.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_292_455.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_292_455.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_292_455.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_292_455.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_292_455.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_292_455.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150004625285777 "Constant thermal conductance of material"; Real TC_292_1125.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_292_1125.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_292_1125.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_292_1125.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_292_1125.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_292_1125.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_292_1125.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600867334064 "Constant thermal conductance of material"; Real TC_293_295.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_293_295.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_293_295.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_293_295.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_293_295.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_293_295.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_293_295.G(quantity = "ThermalConductance", unit = "W/K") = 5.99945024738848e-05 "Constant thermal conductance of material"; Real TC_293_347.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_293_347.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_293_347.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_293_347.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_293_347.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_293_347.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_293_347.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149978308026045 "Constant thermal conductance of material"; Real TC_293_456.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_293_456.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_293_456.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_293_456.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_293_456.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_293_456.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_293_456.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014999817431628 "Constant thermal conductance of material"; Real TC_293_1126.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_293_1126.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_293_1126.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_293_1126.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_293_1126.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_293_1126.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_293_1126.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600189753819 "Constant thermal conductance of material"; Real TC_294_296.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_294_296.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_294_296.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_294_296.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_294_296.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_294_296.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_294_296.G(quantity = "ThermalConductance", unit = "W/K") = 6.00014359563472e-05 "Constant thermal conductance of material"; Real TC_294_348.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_294_348.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_294_348.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_294_348.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_294_348.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_294_348.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_294_348.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150000784892391 "Constant thermal conductance of material"; Real TC_294_457.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_294_457.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_294_457.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_294_457.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_294_457.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_294_457.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_294_457.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150002646482825 "Constant thermal conductance of material"; Real TC_294_1127.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_294_1127.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_294_1127.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_294_1127.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_294_1127.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_294_1127.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_294_1127.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600330134998 "Constant thermal conductance of material"; Real TC_295_297.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_295_297.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_295_297.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_295_297.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_295_297.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_295_297.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_295_297.G(quantity = "ThermalConductance", unit = "W/K") = 5.99993233413409e-05 "Constant thermal conductance of material"; Real TC_295_349.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_295_349.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_295_349.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_295_349.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_295_349.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_295_349.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_295_349.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150133333333429 "Constant thermal conductance of material"; Real TC_295_458.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_295_458.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_295_458.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_295_458.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_295_458.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_295_458.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_295_458.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150003799680828 "Constant thermal conductance of material"; Real TC_295_1128.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_295_1128.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_295_1128.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_295_1128.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_295_1128.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_295_1128.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_295_1128.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600789151388 "Constant thermal conductance of material"; Real TC_296_298.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_296_298.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_296_298.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_296_298.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_296_298.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_296_298.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_296_298.G(quantity = "ThermalConductance", unit = "W/K") = 5.99990252777956e-05 "Constant thermal conductance of material"; Real TC_296_350.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_296_350.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_296_350.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_296_350.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_296_350.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_296_350.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_296_350.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149998431323336 "Constant thermal conductance of material"; Real TC_296_459.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_296_459.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_296_459.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_296_459.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_296_459.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_296_459.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_296_459.G(quantity = "ThermalConductance", unit = "W/K") = 0.0015 "Constant thermal conductance of material"; Real TC_296_1129.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_296_1129.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_296_1129.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_296_1129.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_296_1129.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_296_1129.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_296_1129.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601034254717 "Constant thermal conductance of material"; Real TC_297_299.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_297_299.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_297_299.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_297_299.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_297_299.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_297_299.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_297_299.G(quantity = "ThermalConductance", unit = "W/K") = 3.00002133424359e-05 "Constant thermal conductance of material"; Real TC_297_351.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_297_351.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_297_351.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_297_351.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_297_351.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_297_351.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_297_351.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149999999999969 "Constant thermal conductance of material"; Real TC_297_460.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_297_460.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_297_460.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_297_460.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_297_460.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_297_460.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_297_460.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150002023717974 "Constant thermal conductance of material"; Real TC_297_1130.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_297_1130.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_297_1130.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_297_1130.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_297_1130.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_297_1130.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_297_1130.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600768724897 "Constant thermal conductance of material"; Real TC_298_300.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_298_300.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_298_300.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_298_300.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_298_300.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_298_300.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_298_300.G(quantity = "ThermalConductance", unit = "W/K") = 2.99998670027065e-05 "Constant thermal conductance of material"; Real TC_298_352.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_298_352.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_298_352.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_298_352.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_298_352.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_298_352.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_298_352.G(quantity = "ThermalConductance", unit = "W/K") = 0.0015 "Constant thermal conductance of material"; Real TC_298_461.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_298_461.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_298_461.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_298_461.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_298_461.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_298_461.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_298_461.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149993628138142 "Constant thermal conductance of material"; Real TC_298_1131.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_298_1131.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_298_1131.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_298_1131.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_298_1131.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_298_1131.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_298_1131.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600461298896 "Constant thermal conductance of material"; Real TC_299_301.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_299_301.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_299_301.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_299_301.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_299_301.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_299_301.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_299_301.G(quantity = "ThermalConductance", unit = "W/K") = 2.99996901458638e-05 "Constant thermal conductance of material"; Real TC_299_353.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_299_353.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_299_353.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_299_353.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_299_353.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_299_353.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_299_353.G(quantity = "ThermalConductance", unit = "W/K") = 0.00450008298755187 "Constant thermal conductance of material"; Real TC_299_462.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_299_462.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_299_462.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_299_462.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_299_462.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_299_462.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_299_462.G(quantity = "ThermalConductance", unit = "W/K") = 0.00449999999999998 "Constant thermal conductance of material"; Real TC_299_1132.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_299_1132.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_299_1132.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_299_1132.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_299_1132.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_299_1132.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_299_1132.G(quantity = "ThermalConductance", unit = "W/K") = 0.000373796440315819 "Constant thermal conductance of material"; Real TC_300_302.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_300_302.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_300_302.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_300_302.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_300_302.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_300_302.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_300_302.G(quantity = "ThermalConductance", unit = "W/K") = 2.99998831097482e-05 "Constant thermal conductance of material"; Real TC_300_354.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_300_354.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_300_354.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_300_354.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_300_354.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_300_354.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_300_354.G(quantity = "ThermalConductance", unit = "W/K") = 0.0044998161088634 "Constant thermal conductance of material"; Real TC_300_463.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_300_463.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_300_463.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_300_463.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_300_463.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_300_463.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_300_463.G(quantity = "ThermalConductance", unit = "W/K") = 0.00449992989016117 "Constant thermal conductance of material"; Real TC_300_1133.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_300_1133.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_300_1133.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_300_1133.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_300_1133.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_300_1133.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_300_1133.G(quantity = "ThermalConductance", unit = "W/K") = 0.000373800798634179 "Constant thermal conductance of material"; Real TC_301_303.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_301_303.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_301_303.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_301_303.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_301_303.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_301_303.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_301_303.G(quantity = "ThermalConductance", unit = "W/K") = 9.99999999999999e-05 "Constant thermal conductance of material"; Real TC_301_355.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_301_355.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_301_355.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_301_355.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_301_355.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_301_355.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_301_355.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149992223950193 "Constant thermal conductance of material"; Real TC_301_464.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_301_464.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_301_464.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_301_464.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_301_464.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_301_464.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_301_464.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150011695906408 "Constant thermal conductance of material"; Real TC_301_1134.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_301_1134.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_301_1134.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_301_1134.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_301_1134.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_301_1134.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_301_1134.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124597623254351 "Constant thermal conductance of material"; Real TC_302_315.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_302_315.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_302_315.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_302_315.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_302_315.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_302_315.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_302_315.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_302_356.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_302_356.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_302_356.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_302_356.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_302_356.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_302_356.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_302_356.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150052631578876 "Constant thermal conductance of material"; Real TC_302_465.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_302_465.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_302_465.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_302_465.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_302_465.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_302_465.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_302_465.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150007680491561 "Constant thermal conductance of material"; Real TC_302_1144.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_302_1144.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_302_1144.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_302_1144.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_302_1144.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_302_1144.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_302_1144.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601178682111 "Constant thermal conductance of material"; Real TC_303_304.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_303_304.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_303_304.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_303_304.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_303_304.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_303_304.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_303_304.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200004003202567 "Constant thermal conductance of material"; Real TC_303_357.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_303_357.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_303_357.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_303_357.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_303_357.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_303_357.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_303_357.G(quantity = "ThermalConductance", unit = "W/K") = 0.000298894117647131 "Constant thermal conductance of material"; Real TC_303_466.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_303_466.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_303_466.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_303_466.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_303_466.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_303_466.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_303_466.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300013888888848 "Constant thermal conductance of material"; Real TC_304_305.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_304_305.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_304_305.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_304_305.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_304_305.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_304_305.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_304_305.G(quantity = "ThermalConductance", unit = "W/K") = 8.57122654850571e-05 "Constant thermal conductance of material"; Real TC_304_358.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_304_358.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_304_358.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_304_358.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_304_358.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_304_358.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_304_358.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599908675799414 "Constant thermal conductance of material"; Real TC_304_467.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_304_467.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_304_467.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_304_467.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_304_467.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_304_467.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_304_467.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599646840148829 "Constant thermal conductance of material"; Real TC_304_1134.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_304_1134.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_304_1134.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_304_1134.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_304_1134.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_304_1134.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_304_1134.G(quantity = "ThermalConductance", unit = "W/K") = 2.04452453354357e-05 "Constant thermal conductance of material"; Real TC_305_306.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_305_306.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_305_306.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_305_306.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_305_306.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_305_306.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_305_306.G(quantity = "ThermalConductance", unit = "W/K") = 6.00013683322308e-05 "Constant thermal conductance of material"; Real TC_305_359.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_305_359.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_305_359.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_305_359.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_305_359.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_305_359.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_305_359.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149875816993483 "Constant thermal conductance of material"; Real TC_305_468.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_305_468.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_305_468.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_305_468.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_305_468.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_305_468.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_305_468.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149928400954641 "Constant thermal conductance of material"; Real TC_305_1135.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_305_1135.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_305_1135.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_305_1135.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_305_1135.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_305_1135.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_305_1135.G(quantity = "ThermalConductance", unit = "W/K") = 5.11141323582896e-05 "Constant thermal conductance of material"; Real TC_306_307.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_306_307.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_306_307.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_306_307.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_306_307.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_306_307.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_306_307.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000008e-05 "Constant thermal conductance of material"; Real TC_306_360.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_306_360.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_306_360.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_306_360.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_306_360.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_306_360.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_306_360.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149992647058625 "Constant thermal conductance of material"; Real TC_306_469.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_306_469.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_306_469.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_306_469.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_306_469.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_306_469.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_306_469.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150021516944597 "Constant thermal conductance of material"; Real TC_306_1136.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_306_1136.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_306_1136.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_306_1136.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_306_1136.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_306_1136.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_306_1136.G(quantity = "ThermalConductance", unit = "W/K") = 5.11147864323539e-05 "Constant thermal conductance of material"; Real TC_307_308.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_307_308.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_307_308.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_307_308.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_307_308.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_307_308.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_307_308.G(quantity = "ThermalConductance", unit = "W/K") = 5.99986120749473e-05 "Constant thermal conductance of material"; Real TC_307_361.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_307_361.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_307_361.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_307_361.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_307_361.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_307_361.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_307_361.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149726666666661 "Constant thermal conductance of material"; Real TC_307_470.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_307_470.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_307_470.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_307_470.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_307_470.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_307_470.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_307_470.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150046035805635 "Constant thermal conductance of material"; Real TC_307_1137.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_307_1137.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_307_1137.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_307_1137.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_307_1137.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_307_1137.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_307_1137.G(quantity = "ThermalConductance", unit = "W/K") = 5.11149762467225e-05 "Constant thermal conductance of material"; Real TC_308_309.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_308_309.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_308_309.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_308_309.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_308_309.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_308_309.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_308_309.G(quantity = "ThermalConductance", unit = "W/K") = 5.99759259259473e-05 "Constant thermal conductance of material"; Real TC_308_362.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_308_362.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_308_362.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_308_362.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_308_362.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_308_362.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_308_362.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149792993630482 "Constant thermal conductance of material"; Real TC_308_471.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_308_471.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_308_471.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_308_471.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_308_471.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_308_471.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_308_471.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149966085271316 "Constant thermal conductance of material"; Real TC_308_1138.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_308_1138.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_308_1138.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_308_1138.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_308_1138.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_308_1138.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_308_1138.G(quantity = "ThermalConductance", unit = "W/K") = 5.11132703210331e-05 "Constant thermal conductance of material"; Real TC_309_310.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_309_310.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_309_310.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_309_310.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_309_310.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_309_310.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_309_310.G(quantity = "ThermalConductance", unit = "W/K") = 6.00018328445724e-05 "Constant thermal conductance of material"; Real TC_309_363.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_309_363.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_309_363.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_309_363.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_309_363.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_309_363.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_309_363.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149845315904129 "Constant thermal conductance of material"; Real TC_309_472.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_309_472.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_309_472.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_309_472.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_309_472.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_309_472.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_309_472.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150009128251927 "Constant thermal conductance of material"; Real TC_309_1139.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_309_1139.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_309_1139.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_309_1139.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_309_1139.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_309_1139.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_309_1139.G(quantity = "ThermalConductance", unit = "W/K") = 5.11141670900268e-05 "Constant thermal conductance of material"; Real TC_310_311.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_310_311.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_310_311.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_310_311.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_310_311.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_310_311.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_310_311.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000009e-05 "Constant thermal conductance of material"; Real TC_310_364.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_310_364.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_310_364.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_310_364.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_310_364.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_310_364.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_310_364.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150000000000009 "Constant thermal conductance of material"; Real TC_310_473.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_310_473.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_310_473.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_310_473.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_310_473.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_310_473.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_310_473.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149986870897167 "Constant thermal conductance of material"; Real TC_310_1140.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_310_1140.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_310_1140.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_310_1140.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_310_1140.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_310_1140.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_310_1140.G(quantity = "ThermalConductance", unit = "W/K") = 5.1113675272356e-05 "Constant thermal conductance of material"; Real TC_311_312.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_311_312.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_311_312.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_311_312.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_311_312.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_311_312.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_311_312.G(quantity = "ThermalConductance", unit = "W/K") = 6.00027034333604e-05 "Constant thermal conductance of material"; Real TC_311_365.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_311_365.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_311_365.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_311_365.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_311_365.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_311_365.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_311_365.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014990743801657 "Constant thermal conductance of material"; Real TC_311_474.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_311_474.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_311_474.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_311_474.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_311_474.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_311_474.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_311_474.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150029901751376 "Constant thermal conductance of material"; Real TC_311_1141.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_311_1141.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_311_1141.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_311_1141.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_311_1141.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_311_1141.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_311_1141.G(quantity = "ThermalConductance", unit = "W/K") = 5.11130004464116e-05 "Constant thermal conductance of material"; Real TC_312_313.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_312_313.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_312_313.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_312_313.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_312_313.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_312_313.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_312_313.G(quantity = "ThermalConductance", unit = "W/K") = 5.99990397080711e-05 "Constant thermal conductance of material"; Real TC_312_366.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_312_366.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_312_366.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_312_366.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_312_366.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_312_366.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_312_366.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150105675146818 "Constant thermal conductance of material"; Real TC_312_475.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_312_475.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_312_475.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_312_475.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_312_475.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_312_475.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_312_475.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149974704890382 "Constant thermal conductance of material"; Real TC_312_1142.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_312_1142.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_312_1142.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_312_1142.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_312_1142.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_312_1142.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_312_1142.G(quantity = "ThermalConductance", unit = "W/K") = 5.11138099578261e-05 "Constant thermal conductance of material"; Real TC_313_314.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_313_314.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_313_314.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_313_314.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_313_314.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_313_314.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_313_314.G(quantity = "ThermalConductance", unit = "W/K") = 8.57142857142861e-05 "Constant thermal conductance of material"; Real TC_313_367.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_313_367.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_313_367.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_313_367.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_313_367.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_313_367.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_313_367.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150131067961152 "Constant thermal conductance of material"; Real TC_313_476.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_313_476.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_313_476.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_313_476.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_313_476.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_313_476.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_313_476.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149973556632873 "Constant thermal conductance of material"; Real TC_313_1143.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_313_1143.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_313_1143.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_313_1143.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_313_1143.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_313_1143.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_313_1143.G(quantity = "ThermalConductance", unit = "W/K") = 5.11144115590534e-05 "Constant thermal conductance of material"; Real TC_314_315.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_314_315.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_314_315.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_314_315.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_314_315.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_314_315.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_314_315.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199994900560937 "Constant thermal conductance of material"; Real TC_314_368.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_314_368.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_314_368.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_314_368.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_314_368.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_314_368.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_314_368.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599722543352644 "Constant thermal conductance of material"; Real TC_314_477.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_314_477.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_314_477.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_314_477.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_314_477.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_314_477.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_314_477.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599855725879012 "Constant thermal conductance of material"; Real TC_314_1144.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_314_1144.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_314_1144.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_314_1144.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_314_1144.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_314_1144.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_314_1144.G(quantity = "ThermalConductance", unit = "W/K") = 2.04455193089274e-05 "Constant thermal conductance of material"; Real TC_315_369.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_315_369.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_315_369.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_315_369.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_315_369.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_315_369.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_315_369.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300133333333322 "Constant thermal conductance of material"; Real TC_315_478.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_315_478.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_315_478.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_315_478.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_315_478.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_315_478.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_315_478.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300045283018803 "Constant thermal conductance of material"; Real TC_316_317.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_316_317.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_316_317.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_316_317.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_316_317.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_316_317.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_316_317.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200006596306071 "Constant thermal conductance of material"; Real TC_316_329.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_316_329.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_316_329.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_316_329.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_316_329.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_316_329.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_316_329.G(quantity = "ThermalConductance", unit = "W/K") = 9.99999999999999e-05 "Constant thermal conductance of material"; Real TC_316_370.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_316_370.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_316_370.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_316_370.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_316_370.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_316_370.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_316_370.G(quantity = "ThermalConductance", unit = "W/K") = 0.000305176190477418 "Constant thermal conductance of material"; Real TC_317_318.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_317_318.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_317_318.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_317_318.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_317_318.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_317_318.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_317_318.G(quantity = "ThermalConductance", unit = "W/K") = 8.57121313311934e-05 "Constant thermal conductance of material"; Real TC_317_371.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_317_371.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_317_371.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_317_371.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_317_371.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_317_371.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_317_371.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599834619625056 "Constant thermal conductance of material"; Real TC_317_1145.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_317_1145.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_317_1145.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_317_1145.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_317_1145.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_317_1145.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_317_1145.G(quantity = "ThermalConductance", unit = "W/K") = 2.04454387845391e-05 "Constant thermal conductance of material"; Real TC_318_319.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_318_319.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_318_319.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_318_319.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_318_319.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_318_319.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_318_319.G(quantity = "ThermalConductance", unit = "W/K") = 6.00011604518024e-05 "Constant thermal conductance of material"; Real TC_318_372.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_318_372.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_318_372.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_318_372.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_318_372.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_318_372.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_318_372.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150096096096094 "Constant thermal conductance of material"; Real TC_318_1146.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_318_1146.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_318_1146.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_318_1146.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_318_1146.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_318_1146.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_318_1146.G(quantity = "ThermalConductance", unit = "W/K") = 5.11140199944566e-05 "Constant thermal conductance of material"; Real TC_319_320.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_319_320.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_319_320.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_319_320.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_319_320.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_319_320.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_319_320.G(quantity = "ThermalConductance", unit = "W/K") = 6.00007470212527e-05 "Constant thermal conductance of material"; Real TC_319_373.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_319_373.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_319_373.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_319_373.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_319_373.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_319_373.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_319_373.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150027100271001 "Constant thermal conductance of material"; Real TC_319_1147.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_319_1147.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_319_1147.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_319_1147.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_319_1147.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_319_1147.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_319_1147.G(quantity = "ThermalConductance", unit = "W/K") = 5.11133103616002e-05 "Constant thermal conductance of material"; Real TC_320_321.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_320_321.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_320_321.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_320_321.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_320_321.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_320_321.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_320_321.G(quantity = "ThermalConductance", unit = "W/K") = 5.99991283124137e-05 "Constant thermal conductance of material"; Real TC_320_374.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_320_374.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_320_374.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_320_374.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_320_374.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_320_374.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_320_374.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149968231556652 "Constant thermal conductance of material"; Real TC_320_1148.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_320_1148.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_320_1148.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_320_1148.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_320_1148.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_320_1148.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_320_1148.G(quantity = "ThermalConductance", unit = "W/K") = 5.11131810300532e-05 "Constant thermal conductance of material"; Real TC_321_322.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_321_322.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_321_322.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_321_322.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_321_322.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_321_322.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_321_322.G(quantity = "ThermalConductance", unit = "W/K") = 5.9999999999996e-05 "Constant thermal conductance of material"; Real TC_321_375.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_321_375.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_321_375.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_321_375.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_321_375.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_321_375.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_321_375.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150010309278334 "Constant thermal conductance of material"; Real TC_321_1149.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_321_1149.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_321_1149.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_321_1149.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_321_1149.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_321_1149.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_321_1149.G(quantity = "ThermalConductance", unit = "W/K") = 5.11148452594313e-05 "Constant thermal conductance of material"; Real TC_322_323.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_322_323.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_322_323.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_322_323.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_322_323.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_322_323.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_322_323.G(quantity = "ThermalConductance", unit = "W/K") = 6.00024360535954e-05 "Constant thermal conductance of material"; Real TC_322_376.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_322_376.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_322_376.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_322_376.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_322_376.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_322_376.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_322_376.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149968911917107 "Constant thermal conductance of material"; Real TC_322_1150.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_322_1150.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_322_1150.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_322_1150.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_322_1150.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_322_1150.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_322_1150.G(quantity = "ThermalConductance", unit = "W/K") = 5.11142223777855e-05 "Constant thermal conductance of material"; Real TC_323_324.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_323_324.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_323_324.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_323_324.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_323_324.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_323_324.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_323_324.G(quantity = "ThermalConductance", unit = "W/K") = 6.00016791201397e-05 "Constant thermal conductance of material"; Real TC_323_377.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_323_377.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_323_377.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_323_377.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_323_377.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_323_377.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_323_377.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150006849315071 "Constant thermal conductance of material"; Real TC_323_1151.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_323_1151.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_323_1151.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_323_1151.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_323_1151.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_323_1151.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_323_1151.G(quantity = "ThermalConductance", unit = "W/K") = 5.11134447365392e-05 "Constant thermal conductance of material"; Real TC_324_325.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_324_325.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_324_325.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_324_325.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_324_325.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_324_325.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_324_325.G(quantity = "ThermalConductance", unit = "W/K") = 5.99992100169853e-05 "Constant thermal conductance of material"; Real TC_324_378.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_324_378.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_324_378.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_324_378.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_324_378.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_324_378.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_324_378.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150033704078196 "Constant thermal conductance of material"; Real TC_324_1152.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_324_1152.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_324_1152.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_324_1152.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_324_1152.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_324_1152.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_324_1152.G(quantity = "ThermalConductance", unit = "W/K") = 5.11142696874911e-05 "Constant thermal conductance of material"; Real TC_325_326.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_325_326.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_325_326.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_325_326.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_325_326.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_325_326.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_325_326.G(quantity = "ThermalConductance", unit = "W/K") = 5.99983332638859e-05 "Constant thermal conductance of material"; Real TC_325_379.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_325_379.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_325_379.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_325_379.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_325_379.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_325_379.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_325_379.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150000000000007 "Constant thermal conductance of material"; Real TC_325_1153.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_325_1153.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_325_1153.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_325_1153.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_325_1153.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_325_1153.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_325_1153.G(quantity = "ThermalConductance", unit = "W/K") = 5.11151917094397e-05 "Constant thermal conductance of material"; Real TC_326_327.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_326_327.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_326_327.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_326_327.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_326_327.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_326_327.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_326_327.G(quantity = "ThermalConductance", unit = "W/K") = 8.57165436112801e-05 "Constant thermal conductance of material"; Real TC_326_380.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_326_380.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_326_380.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_326_380.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_326_380.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_326_380.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_326_380.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149979518689199 "Constant thermal conductance of material"; Real TC_326_1154.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_326_1154.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_326_1154.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_326_1154.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_326_1154.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_326_1154.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_326_1154.G(quantity = "ThermalConductance", unit = "W/K") = 5.1114964491225e-05 "Constant thermal conductance of material"; Real TC_327_328.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_327_328.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_327_328.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_327_328.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_327_328.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_327_328.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_327_328.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199923700524574 "Constant thermal conductance of material"; Real TC_327_381.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_327_381.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_327_381.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_327_381.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_327_381.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_327_381.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_327_381.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599948051947955 "Constant thermal conductance of material"; Real TC_327_1155.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_327_1155.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_327_1155.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_327_1155.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_327_1155.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_327_1155.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_327_1155.G(quantity = "ThermalConductance", unit = "W/K") = 2.04456565400308e-05 "Constant thermal conductance of material"; Real TC_328_330.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_328_330.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_328_330.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_328_330.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_328_330.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_328_330.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_328_330.G(quantity = "ThermalConductance", unit = "W/K") = 9.99983737986436e-05 "Constant thermal conductance of material"; Real TC_328_382.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_328_382.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_328_382.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_328_382.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_328_382.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_328_382.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_328_382.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299989451476795 "Constant thermal conductance of material"; Real TC_329_331.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_329_331.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_329_331.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_329_331.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_329_331.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_329_331.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_329_331.G(quantity = "ThermalConductance", unit = "W/K") = 4.00007588926807e-05 "Constant thermal conductance of material"; Real TC_329_383.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_329_383.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_329_383.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_329_383.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_329_383.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_329_383.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_329_383.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149979209979211 "Constant thermal conductance of material"; Real TC_329_1145.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_329_1145.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_329_1145.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_329_1145.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_329_1145.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_329_1145.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_329_1145.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124594194595627 "Constant thermal conductance of material"; Real TC_330_332.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_330_332.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_330_332.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_330_332.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_330_332.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_330_332.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_330_332.G(quantity = "ThermalConductance", unit = "W/K") = 4e-05 "Constant thermal conductance of material"; Real TC_330_384.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_330_384.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_330_384.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_330_384.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_330_384.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_330_384.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_330_384.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149900423728734 "Constant thermal conductance of material"; Real TC_330_1155.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_330_1155.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_330_1155.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_330_1155.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_330_1155.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_330_1155.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_330_1155.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124595488867611 "Constant thermal conductance of material"; Real TC_331_333.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_331_333.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_331_333.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_331_333.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_331_333.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_331_333.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_331_333.G(quantity = "ThermalConductance", unit = "W/K") = 3.52940784209122e-05 "Constant thermal conductance of material"; Real TC_331_385.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_331_385.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_331_385.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_331_385.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_331_385.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_331_385.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_331_385.G(quantity = "ThermalConductance", unit = "W/K") = 0.00300004792026077 "Constant thermal conductance of material"; Real TC_331_1156.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_331_1156.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_331_1156.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_331_1156.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_331_1156.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_331_1156.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_331_1156.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249199051975019 "Constant thermal conductance of material"; Real TC_332_334.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_332_334.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_332_334.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_332_334.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_332_334.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_332_334.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_332_334.G(quantity = "ThermalConductance", unit = "W/K") = 3.52942228475025e-05 "Constant thermal conductance of material"; Real TC_332_386.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_332_386.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_332_386.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_332_386.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_332_386.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_332_386.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_332_386.G(quantity = "ThermalConductance", unit = "W/K") = 0.00300016109544905 "Constant thermal conductance of material"; Real TC_332_1166.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_332_1166.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_332_1166.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_332_1166.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_332_1166.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_332_1166.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_332_1166.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249201496577555 "Constant thermal conductance of material"; Real TC_333_335.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_333_335.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_333_335.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_333_335.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_333_335.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_333_335.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_333_335.G(quantity = "ThermalConductance", unit = "W/K") = 4.28578982154658e-05 "Constant thermal conductance of material"; Real TC_333_387.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_333_387.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_333_387.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_333_387.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_333_387.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_333_387.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_333_387.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209992059290641 "Constant thermal conductance of material"; Real TC_333_1167.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_333_1167.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_333_1167.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_333_1167.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_333_1167.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_333_1167.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_333_1167.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174440289658757 "Constant thermal conductance of material"; Real TC_334_336.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_334_336.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_334_336.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_334_336.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_334_336.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_334_336.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_334_336.G(quantity = "ThermalConductance", unit = "W/K") = 4.28562684580192e-05 "Constant thermal conductance of material"; Real TC_334_388.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_334_388.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_334_388.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_334_388.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_334_388.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_334_388.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_334_388.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209993312314894 "Constant thermal conductance of material"; Real TC_334_1173.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_334_1173.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_334_1173.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_334_1173.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_334_1173.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_334_1173.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_334_1173.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174441188025313 "Constant thermal conductance of material"; Real TC_335_337.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_335_337.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_335_337.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_335_337.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_335_337.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_335_337.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_335_337.G(quantity = "ThermalConductance", unit = "W/K") = 4.28569659442715e-05 "Constant thermal conductance of material"; Real TC_335_389.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_335_389.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_335_389.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_335_389.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_335_389.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_335_389.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_335_389.G(quantity = "ThermalConductance", unit = "W/K") = 0.00210009372071221 "Constant thermal conductance of material"; Real TC_335_1174.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_335_1174.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_335_1174.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_335_1174.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_335_1174.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_335_1174.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_335_1174.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174440863143877 "Constant thermal conductance of material"; Real TC_336_338.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_336_338.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_336_338.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_336_338.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_336_338.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_336_338.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_336_338.G(quantity = "ThermalConductance", unit = "W/K") = 4.28571428571419e-05 "Constant thermal conductance of material"; Real TC_336_390.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_336_390.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_336_390.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_336_390.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_336_390.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_336_390.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_336_390.G(quantity = "ThermalConductance", unit = "W/K") = 0.0021000829026511 "Constant thermal conductance of material"; Real TC_336_1180.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_336_1180.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_336_1180.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_336_1180.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_336_1180.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_336_1180.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_336_1180.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174441585561397 "Constant thermal conductance of material"; Real TC_337_339.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_337_339.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_337_339.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_337_339.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_337_339.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_337_339.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_337_339.G(quantity = "ThermalConductance", unit = "W/K") = 2.85718085106401e-05 "Constant thermal conductance of material"; Real TC_337_391.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_337_391.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_337_391.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_337_391.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_337_391.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_337_391.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_337_391.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209976600723249 "Constant thermal conductance of material"; Real TC_337_1181.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_337_1181.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_337_1181.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_337_1181.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_337_1181.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_337_1181.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_337_1181.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174441409658207 "Constant thermal conductance of material"; Real TC_338_340.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_338_340.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_338_340.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_338_340.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_338_340.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_338_340.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_338_340.G(quantity = "ThermalConductance", unit = "W/K") = 2.85722685482144e-05 "Constant thermal conductance of material"; Real TC_338_392.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_338_392.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_338_392.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_338_392.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_338_392.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_338_392.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_338_392.G(quantity = "ThermalConductance", unit = "W/K") = 0.00209996731969935 "Constant thermal conductance of material"; Real TC_338_1187.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_338_1187.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_338_1187.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_338_1187.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_338_1187.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_338_1187.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_338_1187.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174440757587056 "Constant thermal conductance of material"; Real TC_339_341.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_339_341.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_339_341.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_339_341.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_339_341.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_339_341.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_339_341.G(quantity = "ThermalConductance", unit = "W/K") = 3.15801493192799e-05 "Constant thermal conductance of material"; Real TC_339_393.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_339_393.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_339_393.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_339_393.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_339_393.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_339_393.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_339_393.G(quantity = "ThermalConductance", unit = "W/K") = 0.00419896429544834 "Constant thermal conductance of material"; Real TC_339_1188.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_339_1188.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_339_1188.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_339_1188.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_339_1188.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_339_1188.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_339_1188.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348885147240706 "Constant thermal conductance of material"; Real TC_340_342.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_340_342.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_340_342.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_340_342.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_340_342.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_340_342.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_340_342.G(quantity = "ThermalConductance", unit = "W/K") = 3.15792664443774e-05 "Constant thermal conductance of material"; Real TC_340_394.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_340_394.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_340_394.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_340_394.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_340_394.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_340_394.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_340_394.G(quantity = "ThermalConductance", unit = "W/K") = 0.00419995806654517 "Constant thermal conductance of material"; Real TC_340_1198.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_340_1198.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_340_1198.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_340_1198.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_340_1198.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_340_1198.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_340_1198.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348882994925744 "Constant thermal conductance of material"; Real TC_341_343.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_341_343.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_341_343.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_341_343.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_341_343.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_341_343.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_341_343.G(quantity = "ThermalConductance", unit = "W/K") = 5.99989415749382e-05 "Constant thermal conductance of material"; Real TC_341_395.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_341_395.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_341_395.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_341_395.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_341_395.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_341_395.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_341_395.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150018425901551 "Constant thermal conductance of material"; Real TC_341_1199.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_341_1199.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_341_1199.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_341_1199.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_341_1199.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_341_1199.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_341_1199.G(quantity = "ThermalConductance", unit = "W/K") = 0.00012460105318147 "Constant thermal conductance of material"; Real TC_342_344.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_342_344.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_342_344.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_342_344.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_342_344.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_342_344.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_342_344.G(quantity = "ThermalConductance", unit = "W/K") = 5.99972074839426e-05 "Constant thermal conductance of material"; Real TC_342_396.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_342_396.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_342_396.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_342_396.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_342_396.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_342_396.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_342_396.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149999235392167 "Constant thermal conductance of material"; Real TC_342_1206.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_342_1206.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_342_1206.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_342_1206.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_342_1206.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_342_1206.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_342_1206.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124599751443819 "Constant thermal conductance of material"; Real TC_343_345.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_343_345.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_343_345.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_343_345.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_343_345.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_343_345.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_343_345.G(quantity = "ThermalConductance", unit = "W/K") = 6.00016836434058e-05 "Constant thermal conductance of material"; Real TC_343_397.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_343_397.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_343_397.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_343_397.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_343_397.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_343_397.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_343_397.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149997678737221 "Constant thermal conductance of material"; Real TC_343_1207.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_343_1207.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_343_1207.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_343_1207.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_343_1207.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_343_1207.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_343_1207.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601543435304 "Constant thermal conductance of material"; Real TC_344_346.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_344_346.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_344_346.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_344_346.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_344_346.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_344_346.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_344_346.G(quantity = "ThermalConductance", unit = "W/K") = 6.00880361173914e-05 "Constant thermal conductance of material"; Real TC_344_398.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_344_398.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_344_398.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_344_398.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_344_398.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_344_398.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_344_398.G(quantity = "ThermalConductance", unit = "W/K") = 0.0015000152077377 "Constant thermal conductance of material"; Real TC_344_1214.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_344_1214.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_344_1214.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_344_1214.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_344_1214.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_344_1214.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_344_1214.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601439993896 "Constant thermal conductance of material"; Real TC_345_347.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_345_347.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_345_347.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_345_347.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_345_347.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_345_347.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_345_347.G(quantity = "ThermalConductance", unit = "W/K") = 5.99959382615747e-05 "Constant thermal conductance of material"; Real TC_345_399.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_345_399.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_345_399.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_345_399.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_345_399.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_345_399.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_345_399.G(quantity = "ThermalConductance", unit = "W/K") = 0.0015001494489073 "Constant thermal conductance of material"; Real TC_345_1215.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_345_1215.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_345_1215.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_345_1215.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_345_1215.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_345_1215.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_345_1215.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600936172113 "Constant thermal conductance of material"; Real TC_346_348.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_346_348.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_346_348.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_346_348.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_346_348.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_346_348.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_346_348.G(quantity = "ThermalConductance", unit = "W/K") = 6.00025335698012e-05 "Constant thermal conductance of material"; Real TC_346_400.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_346_400.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_346_400.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_346_400.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_346_400.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_346_400.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_346_400.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149998475098356 "Constant thermal conductance of material"; Real TC_346_1222.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_346_1222.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_346_1222.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_346_1222.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_346_1222.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_346_1222.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_346_1222.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600847891714 "Constant thermal conductance of material"; Real TC_347_349.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_347_349.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_347_349.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_347_349.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_347_349.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_347_349.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_347_349.G(quantity = "ThermalConductance", unit = "W/K") = 5.9991685720223e-05 "Constant thermal conductance of material"; Real TC_347_401.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_347_401.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_347_401.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_347_401.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_347_401.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_347_401.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_347_401.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149992656777799 "Constant thermal conductance of material"; Real TC_347_1223.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_347_1223.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_347_1223.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_347_1223.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_347_1223.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_347_1223.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_347_1223.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600539682772 "Constant thermal conductance of material"; Real TC_348_350.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_348_350.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_348_350.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_348_350.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_348_350.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_348_350.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_348_350.G(quantity = "ThermalConductance", unit = "W/K") = 6.00014382798162e-05 "Constant thermal conductance of material"; Real TC_348_402.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_348_402.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_348_402.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_348_402.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_348_402.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_348_402.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_348_402.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149999235251832 "Constant thermal conductance of material"; Real TC_348_1230.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_348_1230.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_348_1230.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_348_1230.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_348_1230.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_348_1230.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_348_1230.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600148985584 "Constant thermal conductance of material"; Real TC_349_351.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_349_351.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_349_351.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_349_351.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_349_351.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_349_351.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_349_351.G(quantity = "ThermalConductance", unit = "W/K") = 5.99993640092855e-05 "Constant thermal conductance of material"; Real TC_349_403.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_349_403.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_349_403.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_349_403.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_349_403.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_349_403.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_349_403.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150000000000005 "Constant thermal conductance of material"; Real TC_349_1231.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_349_1231.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_349_1231.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_349_1231.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_349_1231.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_349_1231.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_349_1231.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124599767633406 "Constant thermal conductance of material"; Real TC_350_352.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_350_352.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_350_352.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_350_352.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_350_352.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_350_352.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_350_352.G(quantity = "ThermalConductance", unit = "W/K") = 5.9999104022937e-05 "Constant thermal conductance of material"; Real TC_350_404.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_350_404.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_350_404.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_350_404.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_350_404.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_350_404.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_350_404.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150000763137409 "Constant thermal conductance of material"; Real TC_350_1238.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_350_1238.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_350_1238.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_350_1238.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_350_1238.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_350_1238.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_350_1238.G(quantity = "ThermalConductance", unit = "W/K") = 0.00012460010596619 "Constant thermal conductance of material"; Real TC_351_353.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_351_353.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_351_353.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_351_353.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_351_353.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_351_353.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_351_353.G(quantity = "ThermalConductance", unit = "W/K") = 3.00001986899708e-05 "Constant thermal conductance of material"; Real TC_351_405.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_351_405.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_351_405.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_351_405.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_351_405.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_351_405.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_351_405.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150010004001607 "Constant thermal conductance of material"; Real TC_351_1239.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_351_1239.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_351_1239.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_351_1239.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_351_1239.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_351_1239.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_351_1239.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601205894835 "Constant thermal conductance of material"; Real TC_352_354.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_352_354.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_352_354.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_352_354.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_352_354.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_352_354.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_352_354.G(quantity = "ThermalConductance", unit = "W/K") = 2.99999451354332e-05 "Constant thermal conductance of material"; Real TC_352_406.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_352_406.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_352_406.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_352_406.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_352_406.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_352_406.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_352_406.G(quantity = "ThermalConductance", unit = "W/K") = 0.0015000082706145 "Constant thermal conductance of material"; Real TC_352_1246.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_352_1246.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_352_1246.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_352_1246.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_352_1246.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_352_1246.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_352_1246.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601343897302 "Constant thermal conductance of material"; Real TC_353_355.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_353_355.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_353_355.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_353_355.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_353_355.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_353_355.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_353_355.G(quantity = "ThermalConductance", unit = "W/K") = 3.00000990167635e-05 "Constant thermal conductance of material"; Real TC_353_407.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_353_407.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_353_407.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_353_407.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_353_407.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_353_407.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_353_407.G(quantity = "ThermalConductance", unit = "W/K") = 0.0045000656368967 "Constant thermal conductance of material"; Real TC_353_1247.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_353_1247.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_353_1247.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_353_1247.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_353_1247.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_353_1247.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_353_1247.G(quantity = "ThermalConductance", unit = "W/K") = 0.00037379599208705 "Constant thermal conductance of material"; Real TC_354_356.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_354_356.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_354_356.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_354_356.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_354_356.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_354_356.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_354_356.G(quantity = "ThermalConductance", unit = "W/K") = 3.00009458426276e-05 "Constant thermal conductance of material"; Real TC_354_408.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_354_408.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_354_408.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_354_408.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_354_408.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_354_408.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_354_408.G(quantity = "ThermalConductance", unit = "W/K") = 0.00450012901561088 "Constant thermal conductance of material"; Real TC_354_1257.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_354_1257.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_354_1257.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_354_1257.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_354_1257.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_354_1257.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_354_1257.G(quantity = "ThermalConductance", unit = "W/K") = 0.000373801265047949 "Constant thermal conductance of material"; Real TC_355_357.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_355_357.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_355_357.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_355_357.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_355_357.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_355_357.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_355_357.G(quantity = "ThermalConductance", unit = "W/K") = 0.000100001911278454 "Constant thermal conductance of material"; Real TC_355_409.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_355_409.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_355_409.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_355_409.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_355_409.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_355_409.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_355_409.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150022988505741 "Constant thermal conductance of material"; Real TC_355_1258.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_355_1258.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_355_1258.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_355_1258.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_355_1258.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_355_1258.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_355_1258.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124599016468129 "Constant thermal conductance of material"; Real TC_356_369.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_356_369.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_356_369.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_356_369.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_356_369.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_356_369.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_356_369.G(quantity = "ThermalConductance", unit = "W/K") = 9.99980872592338e-05 "Constant thermal conductance of material"; Real TC_356_410.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_356_410.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_356_410.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_356_410.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_356_410.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_356_410.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_356_410.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150026501766767 "Constant thermal conductance of material"; Real TC_356_1268.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_356_1268.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_356_1268.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_356_1268.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_356_1268.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_356_1268.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_356_1268.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601385875271 "Constant thermal conductance of material"; Real TC_357_358.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_357_358.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_357_358.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_357_358.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_357_358.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_357_358.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_357_358.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200022796352596 "Constant thermal conductance of material"; Real TC_357_411.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_357_411.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_357_411.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_357_411.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_357_411.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_357_411.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_357_411.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299540816326469 "Constant thermal conductance of material"; Real TC_358_359.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_358_359.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_358_359.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_358_359.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_358_359.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_358_359.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_358_359.G(quantity = "ThermalConductance", unit = "W/K") = 8.5712911988845e-05 "Constant thermal conductance of material"; Real TC_358_412.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_358_412.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_358_412.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_358_412.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_358_412.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_358_412.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_358_412.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599732620320772 "Constant thermal conductance of material"; Real TC_358_1258.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_358_1258.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_358_1258.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_358_1258.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_358_1258.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_358_1258.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_358_1258.G(quantity = "ThermalConductance", unit = "W/K") = 2.04451487314789e-05 "Constant thermal conductance of material"; Real TC_359_360.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_359_360.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_359_360.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_359_360.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_359_360.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_359_360.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_359_360.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000001e-05 "Constant thermal conductance of material"; Real TC_359_413.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_359_413.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_359_413.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_359_413.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_359_413.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_359_413.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_359_413.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149961038961043 "Constant thermal conductance of material"; Real TC_359_1259.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_359_1259.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_359_1259.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_359_1259.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_359_1259.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_359_1259.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_359_1259.G(quantity = "ThermalConductance", unit = "W/K") = 5.11126710705522e-05 "Constant thermal conductance of material"; Real TC_360_361.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_360_361.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_360_361.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_360_361.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_360_361.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_360_361.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_360_361.G(quantity = "ThermalConductance", unit = "W/K") = 5.99972022754829e-05 "Constant thermal conductance of material"; Real TC_360_414.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_360_414.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_360_414.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_360_414.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_360_414.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_360_414.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_360_414.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149769230769192 "Constant thermal conductance of material"; Real TC_360_1260.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_360_1260.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_360_1260.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_360_1260.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_360_1260.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_360_1260.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_360_1260.G(quantity = "ThermalConductance", unit = "W/K") = 5.11132372686041e-05 "Constant thermal conductance of material"; Real TC_361_362.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_361_362.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_361_362.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_361_362.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_361_362.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_361_362.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_361_362.G(quantity = "ThermalConductance", unit = "W/K") = 5.99972859275321e-05 "Constant thermal conductance of material"; Real TC_361_415.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_361_415.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_361_415.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_361_415.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_361_415.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_361_415.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_361_415.G(quantity = "ThermalConductance", unit = "W/K") = 0.00149925925925909 "Constant thermal conductance of material"; Real TC_361_1261.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_361_1261.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_361_1261.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_361_1261.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_361_1261.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_361_1261.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_361_1261.G(quantity = "ThermalConductance", unit = "W/K") = 5.11151501970349e-05 "Constant thermal conductance of material"; Real TC_362_363.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_362_363.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_362_363.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_362_363.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_362_363.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_362_363.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_362_363.G(quantity = "ThermalConductance", unit = "W/K") = 5.99721518987391e-05 "Constant thermal conductance of material"; Real TC_362_416.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_362_416.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_362_416.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_362_416.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_362_416.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_362_416.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_362_416.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150061674008808 "Constant thermal conductance of material"; Real TC_362_1262.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_362_1262.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_362_1262.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_362_1262.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_362_1262.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_362_1262.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_362_1262.G(quantity = "ThermalConductance", unit = "W/K") = 5.11129708847542e-05 "Constant thermal conductance of material"; Real TC_363_364.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_363_364.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_363_364.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_363_364.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_363_364.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_363_364.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_363_364.G(quantity = "ThermalConductance", unit = "W/K") = 5.99962623808602e-05 "Constant thermal conductance of material"; Real TC_363_417.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_363_417.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_363_417.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_363_417.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_363_417.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_363_417.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_363_417.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150023659305999 "Constant thermal conductance of material"; Real TC_363_1263.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_363_1263.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_363_1263.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_363_1263.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_363_1263.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_363_1263.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_363_1263.G(quantity = "ThermalConductance", unit = "W/K") = 5.11141023798012e-05 "Constant thermal conductance of material"; Real TC_364_365.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_364_365.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_364_365.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_364_365.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_364_365.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_364_365.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_364_365.G(quantity = "ThermalConductance", unit = "W/K") = 6.00017773038303e-05 "Constant thermal conductance of material"; Real TC_364_418.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_364_418.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_364_418.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_364_418.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_364_418.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_364_418.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_364_418.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150036791758639 "Constant thermal conductance of material"; Real TC_364_1264.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_364_1264.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_364_1264.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_364_1264.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_364_1264.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_364_1264.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_364_1264.G(quantity = "ThermalConductance", unit = "W/K") = 5.11139889526125e-05 "Constant thermal conductance of material"; Real TC_365_366.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_365_366.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_365_366.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_365_366.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_365_366.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_365_366.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_365_366.G(quantity = "ThermalConductance", unit = "W/K") = 6.00008973438622e-05 "Constant thermal conductance of material"; Real TC_365_419.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_365_419.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_365_419.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_365_419.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_365_419.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_365_419.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_365_419.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150036549707594 "Constant thermal conductance of material"; Real TC_365_1265.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_365_1265.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_365_1265.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_365_1265.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_365_1265.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_365_1265.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_365_1265.G(quantity = "ThermalConductance", unit = "W/K") = 5.11148979952735e-05 "Constant thermal conductance of material"; Real TC_366_367.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_366_367.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_366_367.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_366_367.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_366_367.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_366_367.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_366_367.G(quantity = "ThermalConductance", unit = "W/K") = 5.9999046688434e-05 "Constant thermal conductance of material"; Real TC_366_420.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_366_420.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_366_420.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_366_420.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_366_420.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_366_420.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_366_420.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014998256320838 "Constant thermal conductance of material"; Real TC_366_1266.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_366_1266.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_366_1266.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_366_1266.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_366_1266.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_366_1266.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_366_1266.G(quantity = "ThermalConductance", unit = "W/K") = 5.11147707119331e-05 "Constant thermal conductance of material"; Real TC_367_368.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_367_368.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_367_368.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_367_368.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_367_368.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_367_368.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_367_368.G(quantity = "ThermalConductance", unit = "W/K") = 8.57139217284959e-05 "Constant thermal conductance of material"; Real TC_367_421.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_367_421.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_367_421.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_367_421.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_367_421.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_367_421.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_367_421.G(quantity = "ThermalConductance", unit = "W/K") = 0.00150122641509381 "Constant thermal conductance of material"; Real TC_367_1267.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_367_1267.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_367_1267.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_367_1267.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_367_1267.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_367_1267.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_367_1267.G(quantity = "ThermalConductance", unit = "W/K") = 5.11129688318818e-05 "Constant thermal conductance of material"; Real TC_368_369.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_368_369.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_368_369.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_368_369.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_368_369.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_368_369.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_368_369.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199922928709063 "Constant thermal conductance of material"; Real TC_368_422.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_368_422.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_368_422.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_368_422.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_368_422.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_368_422.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_368_422.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600352716873168 "Constant thermal conductance of material"; Real TC_368_1268.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_368_1268.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_368_1268.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_368_1268.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_368_1268.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_368_1268.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_368_1268.G(quantity = "ThermalConductance", unit = "W/K") = 2.04455771127918e-05 "Constant thermal conductance of material"; Real TC_369_423.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_369_423.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_369_423.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_369_423.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_369_423.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_369_423.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_369_423.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299892086331174 "Constant thermal conductance of material"; Real TC_370_371.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_370_371.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_370_371.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_370_371.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_370_371.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_370_371.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_370_371.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200012626262626 "Constant thermal conductance of material"; Real TC_370_383.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_370_383.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_370_383.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_370_383.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_370_383.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_370_383.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_370_383.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010000177449693 "Constant thermal conductance of material"; Real TC_370_424.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_370_424.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_370_424.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_370_424.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_370_424.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_370_424.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_370_424.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300093984962344 "Constant thermal conductance of material"; Real TC_371_372.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_371_372.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_371_372.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_371_372.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_371_372.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_371_372.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_371_372.G(quantity = "ThermalConductance", unit = "W/K") = 8.57133575883579e-05 "Constant thermal conductance of material"; Real TC_371_1269.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_371_1269.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_371_1269.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_371_1269.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_371_1269.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_371_1269.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_371_1269.G(quantity = "ThermalConductance", unit = "W/K") = 2.04453730040862e-05 "Constant thermal conductance of material"; Real TC_372_373.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_372_373.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_372_373.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_372_373.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_372_373.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_372_373.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_372_373.G(quantity = "ThermalConductance", unit = "W/K") = 5.99996244272514e-05 "Constant thermal conductance of material"; Real TC_372_1270.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_372_1270.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_372_1270.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_372_1270.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_372_1270.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_372_1270.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_372_1270.G(quantity = "ThermalConductance", unit = "W/K") = 5.111487714223e-05 "Constant thermal conductance of material"; Real TC_373_374.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_373_374.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_373_374.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_373_374.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_373_374.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_373_374.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_373_374.G(quantity = "ThermalConductance", unit = "W/K") = 5.9999269859813e-05 "Constant thermal conductance of material"; Real TC_373_1271.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_373_1271.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_373_1271.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_373_1271.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_373_1271.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_373_1271.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_373_1271.G(quantity = "ThermalConductance", unit = "W/K") = 5.11140073999494e-05 "Constant thermal conductance of material"; Real TC_374_375.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_374_375.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_374_375.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_374_375.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_374_375.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_374_375.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_374_375.G(quantity = "ThermalConductance", unit = "W/K") = 6.00025976274996e-05 "Constant thermal conductance of material"; Real TC_374_1272.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_374_1272.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_374_1272.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_374_1272.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_374_1272.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_374_1272.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_374_1272.G(quantity = "ThermalConductance", unit = "W/K") = 5.11139922686727e-05 "Constant thermal conductance of material"; Real TC_375_376.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_375_376.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_375_376.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_375_376.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_375_376.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_375_376.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_375_376.G(quantity = "ThermalConductance", unit = "W/K") = 5.99800399201676e-05 "Constant thermal conductance of material"; Real TC_375_1273.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_375_1273.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_375_1273.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_375_1273.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_375_1273.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_375_1273.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_375_1273.G(quantity = "ThermalConductance", unit = "W/K") = 5.11143496960865e-05 "Constant thermal conductance of material"; Real TC_376_377.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_376_377.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_376_377.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_376_377.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_376_377.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_376_377.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_376_377.G(quantity = "ThermalConductance", unit = "W/K") = 5.99926470588275e-05 "Constant thermal conductance of material"; Real TC_376_1274.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_376_1274.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_376_1274.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_376_1274.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_376_1274.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_376_1274.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_376_1274.G(quantity = "ThermalConductance", unit = "W/K") = 5.1114754001168e-05 "Constant thermal conductance of material"; Real TC_377_378.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_377_378.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_377_378.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_377_378.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_377_378.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_377_378.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_377_378.G(quantity = "ThermalConductance", unit = "W/K") = 5.99991571139568e-05 "Constant thermal conductance of material"; Real TC_377_1275.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_377_1275.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_377_1275.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_377_1275.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_377_1275.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_377_1275.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_377_1275.G(quantity = "ThermalConductance", unit = "W/K") = 5.11136246295628e-05 "Constant thermal conductance of material"; Real TC_378_379.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_378_379.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_378_379.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_378_379.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_378_379.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_378_379.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_378_379.G(quantity = "ThermalConductance", unit = "W/K") = 6.00023544184591e-05 "Constant thermal conductance of material"; Real TC_378_1276.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_378_1276.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_378_1276.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_378_1276.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_378_1276.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_378_1276.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_378_1276.G(quantity = "ThermalConductance", unit = "W/K") = 5.1112756281445e-05 "Constant thermal conductance of material"; Real TC_379_380.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_379_380.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_379_380.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_379_380.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_379_380.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_379_380.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_379_380.G(quantity = "ThermalConductance", unit = "W/K") = 6e-05 "Constant thermal conductance of material"; Real TC_379_1277.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_379_1277.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_379_1277.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_379_1277.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_379_1277.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_379_1277.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_379_1277.G(quantity = "ThermalConductance", unit = "W/K") = 5.11149142577474e-05 "Constant thermal conductance of material"; Real TC_380_381.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_380_381.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_380_381.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_380_381.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_380_381.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_380_381.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_380_381.G(quantity = "ThermalConductance", unit = "W/K") = 8.5714285714286e-05 "Constant thermal conductance of material"; Real TC_380_1278.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_380_1278.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_380_1278.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_380_1278.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_380_1278.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_380_1278.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_380_1278.G(quantity = "ThermalConductance", unit = "W/K") = 5.111528813099e-05 "Constant thermal conductance of material"; Real TC_381_382.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_381_382.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_381_382.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_381_382.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_381_382.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_381_382.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_381_382.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199941444372144 "Constant thermal conductance of material"; Real TC_381_1279.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_381_1279.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_381_1279.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_381_1279.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_381_1279.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_381_1279.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_381_1279.G(quantity = "ThermalConductance", unit = "W/K") = 2.04457113241773e-05 "Constant thermal conductance of material"; Real TC_382_384.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_382_384.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_382_384.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_382_384.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_382_384.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_382_384.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_382_384.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_383_385.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_383_385.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_383_385.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_383_385.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_383_385.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_383_385.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_383_385.G(quantity = "ThermalConductance", unit = "W/K") = 4.00001986477057e-05 "Constant thermal conductance of material"; Real TC_383_1269.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_383_1269.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_383_1269.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_383_1269.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_383_1269.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_383_1269.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_383_1269.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124599098626978 "Constant thermal conductance of material"; Real TC_384_386.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_384_386.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_384_386.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_384_386.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_384_386.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_384_386.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_384_386.G(quantity = "ThermalConductance", unit = "W/K") = 3.9999357955731e-05 "Constant thermal conductance of material"; Real TC_384_1279.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_384_1279.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_384_1279.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_384_1279.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_384_1279.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_384_1279.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_384_1279.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601061829776 "Constant thermal conductance of material"; Real TC_385_387.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_385_387.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_385_387.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_385_387.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_385_387.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_385_387.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_385_387.G(quantity = "ThermalConductance", unit = "W/K") = 3.5294477926405e-05 "Constant thermal conductance of material"; Real TC_385_1280.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_385_1280.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_385_1280.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_385_1280.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_385_1280.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_385_1280.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_385_1280.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249200133637127 "Constant thermal conductance of material"; Real TC_386_388.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_386_388.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_386_388.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_386_388.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_386_388.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_386_388.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_386_388.G(quantity = "ThermalConductance", unit = "W/K") = 3.52934709827006e-05 "Constant thermal conductance of material"; Real TC_386_1290.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_386_1290.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_386_1290.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_386_1290.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_386_1290.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_386_1290.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_386_1290.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249202703071755 "Constant thermal conductance of material"; Real TC_387_389.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_387_389.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_387_389.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_387_389.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_387_389.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_387_389.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_387_389.G(quantity = "ThermalConductance", unit = "W/K") = 4.28557159266848e-05 "Constant thermal conductance of material"; Real TC_387_1291.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_387_1291.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_387_1291.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_387_1291.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_387_1291.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_387_1291.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_387_1291.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174440548538671 "Constant thermal conductance of material"; Real TC_388_390.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_388_390.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_388_390.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_388_390.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_388_390.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_388_390.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_388_390.G(quantity = "ThermalConductance", unit = "W/K") = 4.28567329900011e-05 "Constant thermal conductance of material"; Real TC_388_1301.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_388_1301.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_388_1301.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_388_1301.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_388_1301.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_388_1301.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_388_1301.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174441442344396 "Constant thermal conductance of material"; Real TC_389_391.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_389_391.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_389_391.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_389_391.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_389_391.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_389_391.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_389_391.G(quantity = "ThermalConductance", unit = "W/K") = 4.28602595016632e-05 "Constant thermal conductance of material"; Real TC_389_1302.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_389_1302.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_389_1302.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_389_1302.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_389_1302.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_389_1302.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_389_1302.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174441415712435 "Constant thermal conductance of material"; Real TC_390_392.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_390_392.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_390_392.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_390_392.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_390_392.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_390_392.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_390_392.G(quantity = "ThermalConductance", unit = "W/K") = 4.28575502637965e-05 "Constant thermal conductance of material"; Real TC_390_1312.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_390_1312.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_390_1312.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_390_1312.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_390_1312.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_390_1312.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_390_1312.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174440161764579 "Constant thermal conductance of material"; Real TC_391_393.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_391_393.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_391_393.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_391_393.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_391_393.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_391_393.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_391_393.G(quantity = "ThermalConductance", unit = "W/K") = 2.85703812316741e-05 "Constant thermal conductance of material"; Real TC_391_1313.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_391_1313.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_391_1313.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_391_1313.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_391_1313.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_391_1313.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_391_1313.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174441816564324 "Constant thermal conductance of material"; Real TC_392_394.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_392_394.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_392_394.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_392_394.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_392_394.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_392_394.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_392_394.G(quantity = "ThermalConductance", unit = "W/K") = 2.85707956760585e-05 "Constant thermal conductance of material"; Real TC_392_1323.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_392_1323.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_392_1323.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_392_1323.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_392_1323.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_392_1323.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_392_1323.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174440683208468 "Constant thermal conductance of material"; Real TC_393_395.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_393_395.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_393_395.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_393_395.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_393_395.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_393_395.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_393_395.G(quantity = "ThermalConductance", unit = "W/K") = 3.15761883607289e-05 "Constant thermal conductance of material"; Real TC_393_1324.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_393_1324.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_393_1324.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_393_1324.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_393_1324.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_393_1324.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_393_1324.G(quantity = "ThermalConductance", unit = "W/K") = 0.00034889279630749 "Constant thermal conductance of material"; Real TC_394_396.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_394_396.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_394_396.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_394_396.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_394_396.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_394_396.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_394_396.G(quantity = "ThermalConductance", unit = "W/K") = 3.15800610622412e-05 "Constant thermal conductance of material"; Real TC_394_1334.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_394_1334.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_394_1334.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_394_1334.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_394_1334.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_394_1334.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_394_1334.G(quantity = "ThermalConductance", unit = "W/K") = 0.00034887337024242 "Constant thermal conductance of material"; Real TC_395_397.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_395_397.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_395_397.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_395_397.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_395_397.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_395_397.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_395_397.G(quantity = "ThermalConductance", unit = "W/K") = 6.0002237386736e-05 "Constant thermal conductance of material"; Real TC_395_1335.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_395_1335.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_395_1335.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_395_1335.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_395_1335.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_395_1335.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_395_1335.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600022292725 "Constant thermal conductance of material"; Real TC_396_398.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_396_398.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_396_398.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_396_398.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_396_398.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_396_398.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_396_398.G(quantity = "ThermalConductance", unit = "W/K") = 6.00009004141933e-05 "Constant thermal conductance of material"; Real TC_396_1342.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_396_1342.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_396_1342.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_396_1342.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_396_1342.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_396_1342.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_396_1342.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601027136332 "Constant thermal conductance of material"; Real TC_397_399.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_397_399.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_397_399.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_397_399.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_397_399.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_397_399.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_397_399.G(quantity = "ThermalConductance", unit = "W/K") = 5.99981539597533e-05 "Constant thermal conductance of material"; Real TC_397_1343.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_397_1343.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_397_1343.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_397_1343.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_397_1343.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_397_1343.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_397_1343.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600682005506 "Constant thermal conductance of material"; Real TC_398_400.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_398_400.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_398_400.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_398_400.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_398_400.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_398_400.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_398_400.G(quantity = "ThermalConductance", unit = "W/K") = 5.98528301886181e-05 "Constant thermal conductance of material"; Real TC_398_1350.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_398_1350.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_398_1350.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_398_1350.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_398_1350.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_398_1350.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_398_1350.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600482282258 "Constant thermal conductance of material"; Real TC_399_401.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_399_401.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_399_401.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_399_401.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_399_401.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_399_401.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_399_401.G(quantity = "ThermalConductance", unit = "W/K") = 6.00023832221169e-05 "Constant thermal conductance of material"; Real TC_399_1351.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_399_1351.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_399_1351.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_399_1351.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_399_1351.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_399_1351.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_399_1351.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601675754755 "Constant thermal conductance of material"; Real TC_400_402.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_400_402.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_400_402.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_400_402.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_400_402.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_400_402.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_400_402.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000014e-05 "Constant thermal conductance of material"; Real TC_400_1358.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_400_1358.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_400_1358.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_400_1358.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_400_1358.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_400_1358.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_400_1358.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600736912447 "Constant thermal conductance of material"; Real TC_401_403.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_401_403.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_401_403.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_401_403.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_401_403.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_401_403.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_401_403.G(quantity = "ThermalConductance", unit = "W/K") = 5.99999999999996e-05 "Constant thermal conductance of material"; Real TC_401_1359.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_401_1359.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_401_1359.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_401_1359.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_401_1359.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_401_1359.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_401_1359.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600998714293 "Constant thermal conductance of material"; Real TC_402_404.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_402_404.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_402_404.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_402_404.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_402_404.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_402_404.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_402_404.G(quantity = "ThermalConductance", unit = "W/K") = 6.00007227261228e-05 "Constant thermal conductance of material"; Real TC_402_1369.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_402_1369.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_402_1369.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_402_1369.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_402_1369.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_402_1369.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_402_1369.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600606132881 "Constant thermal conductance of material"; Real TC_403_405.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_403_405.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_403_405.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_403_405.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_403_405.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_403_405.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_403_405.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000002e-05 "Constant thermal conductance of material"; Real TC_403_1370.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_403_1370.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_403_1370.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_403_1370.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_403_1370.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_403_1370.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_403_1370.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124599838761437 "Constant thermal conductance of material"; Real TC_404_406.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_404_406.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_404_406.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_404_406.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_404_406.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_404_406.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_404_406.G(quantity = "ThermalConductance", unit = "W/K") = 5.99999999999999e-05 "Constant thermal conductance of material"; Real TC_404_1380.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_404_1380.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_404_1380.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_404_1380.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_404_1380.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_404_1380.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_404_1380.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601461513746 "Constant thermal conductance of material"; Real TC_405_407.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_405_407.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_405_407.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_405_407.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_405_407.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_405_407.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_405_407.G(quantity = "ThermalConductance", unit = "W/K") = 3.00001220658423e-05 "Constant thermal conductance of material"; Real TC_405_1381.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_405_1381.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_405_1381.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_405_1381.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_405_1381.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_405_1381.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_405_1381.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600048574959 "Constant thermal conductance of material"; Real TC_406_408.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_406_408.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_406_408.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_406_408.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_406_408.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_406_408.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_406_408.G(quantity = "ThermalConductance", unit = "W/K") = 3.00006129523645e-05 "Constant thermal conductance of material"; Real TC_406_1391.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_406_1391.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_406_1391.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_406_1391.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_406_1391.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_406_1391.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_406_1391.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600619372364 "Constant thermal conductance of material"; Real TC_407_409.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_407_409.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_407_409.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_407_409.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_407_409.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_407_409.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_407_409.G(quantity = "ThermalConductance", unit = "W/K") = 3.00008053075965e-05 "Constant thermal conductance of material"; Real TC_407_1392.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_407_1392.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_407_1392.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_407_1392.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_407_1392.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_407_1392.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_407_1392.G(quantity = "ThermalConductance", unit = "W/K") = 0.000373809029117568 "Constant thermal conductance of material"; Real TC_408_410.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_408_410.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_408_410.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_408_410.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_408_410.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_408_410.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_408_410.G(quantity = "ThermalConductance", unit = "W/K") = 2.99991482699741e-05 "Constant thermal conductance of material"; Real TC_408_1402.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_408_1402.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_408_1402.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_408_1402.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_408_1402.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_408_1402.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_408_1402.G(quantity = "ThermalConductance", unit = "W/K") = 0.000373817355938061 "Constant thermal conductance of material"; Real TC_409_411.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_409_411.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_409_411.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_409_411.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_409_411.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_409_411.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_409_411.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_409_1403.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_409_1403.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_409_1403.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_409_1403.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_409_1403.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_409_1403.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_409_1403.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601733878493 "Constant thermal conductance of material"; Real TC_410_423.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_410_423.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_410_423.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_410_423.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_410_423.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_410_423.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_410_423.G(quantity = "ThermalConductance", unit = "W/K") = 9.99980342434785e-05 "Constant thermal conductance of material"; Real TC_410_1413.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_410_1413.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_410_1413.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_410_1413.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_410_1413.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_410_1413.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_410_1413.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600622133179 "Constant thermal conductance of material"; Real TC_411_412.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_411_412.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_411_412.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_411_412.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_411_412.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_411_412.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_411_412.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199973513831668 "Constant thermal conductance of material"; Real TC_412_413.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_412_413.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_412_413.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_412_413.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_412_413.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_412_413.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_412_413.G(quantity = "ThermalConductance", unit = "W/K") = 8.57142857142855e-05 "Constant thermal conductance of material"; Real TC_412_1403.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_412_1403.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_412_1403.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_412_1403.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_412_1403.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_412_1403.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_412_1403.G(quantity = "ThermalConductance", unit = "W/K") = 2.04453116899032e-05 "Constant thermal conductance of material"; Real TC_413_414.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_413_414.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_413_414.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_413_414.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_413_414.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_413_414.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_413_414.G(quantity = "ThermalConductance", unit = "W/K") = 5.99991151225555e-05 "Constant thermal conductance of material"; Real TC_413_1404.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_413_1404.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_413_1404.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_413_1404.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_413_1404.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_413_1404.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_413_1404.G(quantity = "ThermalConductance", unit = "W/K") = 5.11137764905511e-05 "Constant thermal conductance of material"; Real TC_414_415.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_414_415.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_414_415.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_414_415.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_414_415.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_414_415.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_414_415.G(quantity = "ThermalConductance", unit = "W/K") = 5.99990866328724e-05 "Constant thermal conductance of material"; Real TC_414_1405.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_414_1405.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_414_1405.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_414_1405.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_414_1405.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_414_1405.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_414_1405.G(quantity = "ThermalConductance", unit = "W/K") = 5.11132603292464e-05 "Constant thermal conductance of material"; Real TC_415_416.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_415_416.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_415_416.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_415_416.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_415_416.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_415_416.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_415_416.G(quantity = "ThermalConductance", unit = "W/K") = 6.00039687789376e-05 "Constant thermal conductance of material"; Real TC_415_1406.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_415_1406.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_415_1406.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_415_1406.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_415_1406.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_415_1406.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_415_1406.G(quantity = "ThermalConductance", unit = "W/K") = 5.11149471015421e-05 "Constant thermal conductance of material"; Real TC_416_417.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_416_417.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_416_417.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_416_417.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_416_417.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_416_417.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_416_417.G(quantity = "ThermalConductance", unit = "W/K") = 6.00152671755659e-05 "Constant thermal conductance of material"; Real TC_416_1407.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_416_1407.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_416_1407.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_416_1407.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_416_1407.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_416_1407.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_416_1407.G(quantity = "ThermalConductance", unit = "W/K") = 5.11143940745128e-05 "Constant thermal conductance of material"; Real TC_417_418.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_417_418.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_417_418.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_417_418.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_417_418.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_417_418.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_417_418.G(quantity = "ThermalConductance", unit = "W/K") = 5.99942965779448e-05 "Constant thermal conductance of material"; Real TC_417_1408.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_417_1408.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_417_1408.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_417_1408.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_417_1408.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_417_1408.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_417_1408.G(quantity = "ThermalConductance", unit = "W/K") = 5.11134770048689e-05 "Constant thermal conductance of material"; Real TC_418_419.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_418_419.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_418_419.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_418_419.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_418_419.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_418_419.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_418_419.G(quantity = "ThermalConductance", unit = "W/K") = 6.00017787264322e-05 "Constant thermal conductance of material"; Real TC_418_1409.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_418_1409.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_418_1409.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_418_1409.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_418_1409.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_418_1409.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_418_1409.G(quantity = "ThermalConductance", unit = "W/K") = 5.11140280828984e-05 "Constant thermal conductance of material"; Real TC_419_420.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_419_420.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_419_420.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_419_420.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_419_420.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_419_420.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_419_420.G(quantity = "ThermalConductance", unit = "W/K") = 5.99982229330486e-05 "Constant thermal conductance of material"; Real TC_419_1410.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_419_1410.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_419_1410.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_419_1410.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_419_1410.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_419_1410.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_419_1410.G(quantity = "ThermalConductance", unit = "W/K") = 5.1112409734107e-05 "Constant thermal conductance of material"; Real TC_420_421.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_420_421.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_420_421.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_420_421.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_420_421.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_420_421.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_420_421.G(quantity = "ThermalConductance", unit = "W/K") = 5.99985907553556e-05 "Constant thermal conductance of material"; Real TC_420_1411.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_420_1411.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_420_1411.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_420_1411.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_420_1411.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_420_1411.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_420_1411.G(quantity = "ThermalConductance", unit = "W/K") = 5.11135149121514e-05 "Constant thermal conductance of material"; Real TC_421_422.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_421_422.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_421_422.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_421_422.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_421_422.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_421_422.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_421_422.G(quantity = "ThermalConductance", unit = "W/K") = 8.57135479872963e-05 "Constant thermal conductance of material"; Real TC_421_1412.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_421_1412.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_421_1412.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_421_1412.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_421_1412.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_421_1412.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_421_1412.G(quantity = "ThermalConductance", unit = "W/K") = 5.11128647746382e-05 "Constant thermal conductance of material"; Real TC_422_423.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_422_423.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_422_423.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_422_423.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_422_423.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_422_423.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_422_423.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199992975061453 "Constant thermal conductance of material"; Real TC_422_1413.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_422_1413.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_422_1413.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_422_1413.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_422_1413.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_422_1413.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_422_1413.G(quantity = "ThermalConductance", unit = "W/K") = 2.04460328806291e-05 "Constant thermal conductance of material"; Real TC_425_426.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_425_426.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_425_426.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_425_426.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_425_426.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_425_426.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_425_426.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199996732026145 "Constant thermal conductance of material"; Real TC_425_438.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_425_438.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_425_438.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_425_438.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_425_438.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_425_438.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_425_438.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_425_479.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_425_479.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_425_479.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_425_479.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_425_479.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_425_479.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_425_479.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199999999999989 "Constant thermal conductance of material"; Real TC_426_427.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_426_427.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_426_427.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_426_427.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_426_427.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_426_427.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_426_427.G(quantity = "ThermalConductance", unit = "W/K") = 8.57149107455373e-05 "Constant thermal conductance of material"; Real TC_426_480.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_426_480.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_426_480.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_426_480.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_426_480.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_426_480.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_426_480.G(quantity = "ThermalConductance", unit = "W/K") = 0.000399820675105488 "Constant thermal conductance of material"; Real TC_426_1066.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_426_1066.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_426_1066.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_426_1066.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_426_1066.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_426_1066.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_426_1066.G(quantity = "ThermalConductance", unit = "W/K") = 2.04457851516675e-05 "Constant thermal conductance of material"; Real TC_427_428.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_427_428.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_427_428.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_427_428.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_427_428.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_427_428.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_427_428.G(quantity = "ThermalConductance", unit = "W/K") = 5.99988052806597e-05 "Constant thermal conductance of material"; Real TC_427_481.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_427_481.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_427_481.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_427_481.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_427_481.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_427_481.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_427_481.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100004098360656 "Constant thermal conductance of material"; Real TC_427_1067.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_427_1067.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_427_1067.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_427_1067.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_427_1067.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_427_1067.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_427_1067.G(quantity = "ThermalConductance", unit = "W/K") = 5.11148628980614e-05 "Constant thermal conductance of material"; Real TC_428_429.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_428_429.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_428_429.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_428_429.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_428_429.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_428_429.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_428_429.G(quantity = "ThermalConductance", unit = "W/K") = 6.00007625438462e-05 "Constant thermal conductance of material"; Real TC_428_482.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_428_482.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_428_482.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_428_482.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_428_482.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_428_482.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_428_482.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999957805907255 "Constant thermal conductance of material"; Real TC_428_1068.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_428_1068.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_428_1068.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_428_1068.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_428_1068.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_428_1068.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_428_1068.G(quantity = "ThermalConductance", unit = "W/K") = 5.11131003918231e-05 "Constant thermal conductance of material"; Real TC_429_430.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_429_430.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_429_430.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_429_430.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_429_430.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_429_430.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_429_430.G(quantity = "ThermalConductance", unit = "W/K") = 6.0000866551126e-05 "Constant thermal conductance of material"; Real TC_429_483.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_429_483.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_429_483.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_429_483.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_429_483.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_429_483.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_429_483.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999687917967011 "Constant thermal conductance of material"; Real TC_429_1069.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_429_1069.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_429_1069.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_429_1069.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_429_1069.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_429_1069.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_429_1069.G(quantity = "ThermalConductance", unit = "W/K") = 5.11147051386643e-05 "Constant thermal conductance of material"; Real TC_430_431.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_430_431.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_430_431.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_430_431.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_430_431.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_430_431.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_430_431.G(quantity = "ThermalConductance", unit = "W/K") = 6.001529636711e-05 "Constant thermal conductance of material"; Real TC_430_484.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_430_484.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_430_484.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_430_484.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_430_484.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_430_484.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_430_484.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999900249376497 "Constant thermal conductance of material"; Real TC_430_1070.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_430_1070.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_430_1070.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_430_1070.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_430_1070.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_430_1070.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_430_1070.G(quantity = "ThermalConductance", unit = "W/K") = 5.1113204599573e-05 "Constant thermal conductance of material"; Real TC_431_432.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_431_432.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_431_432.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_431_432.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_431_432.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_431_432.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_431_432.G(quantity = "ThermalConductance", unit = "W/K") = 6.00048100048104e-05 "Constant thermal conductance of material"; Real TC_431_485.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_431_485.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_431_485.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_431_485.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_431_485.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_431_485.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_431_485.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100037253858421 "Constant thermal conductance of material"; Real TC_431_1071.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_431_1071.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_431_1071.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_431_1071.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_431_1071.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_431_1071.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_431_1071.G(quantity = "ThermalConductance", unit = "W/K") = 5.11140484278249e-05 "Constant thermal conductance of material"; Real TC_432_433.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_432_433.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_432_433.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_432_433.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_432_433.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_432_433.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_432_433.G(quantity = "ThermalConductance", unit = "W/K") = 6.00024730030495e-05 "Constant thermal conductance of material"; Real TC_432_486.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_432_486.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_432_486.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_432_486.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_432_486.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_432_486.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_432_486.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999895941727332 "Constant thermal conductance of material"; Real TC_432_1072.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_432_1072.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_432_1072.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_432_1072.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_432_1072.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_432_1072.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_432_1072.G(quantity = "ThermalConductance", unit = "W/K") = 5.11138672899871e-05 "Constant thermal conductance of material"; Real TC_433_434.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_433_434.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_433_434.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_433_434.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_433_434.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_433_434.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_433_434.G(quantity = "ThermalConductance", unit = "W/K") = 5.99992160551894e-05 "Constant thermal conductance of material"; Real TC_433_487.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_433_487.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_433_487.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_433_487.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_433_487.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_433_487.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_433_487.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999725651577511 "Constant thermal conductance of material"; Real TC_433_1073.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_433_1073.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_433_1073.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_433_1073.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_433_1073.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_433_1073.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_433_1073.G(quantity = "ThermalConductance", unit = "W/K") = 5.11150620337804e-05 "Constant thermal conductance of material"; Real TC_434_435.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_434_435.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_434_435.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_434_435.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_434_435.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_434_435.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_434_435.G(quantity = "ThermalConductance", unit = "W/K") = 5.99987376659443e-05 "Constant thermal conductance of material"; Real TC_434_488.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_434_488.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_434_488.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_434_488.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_434_488.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_434_488.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_434_488.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999927299163959 "Constant thermal conductance of material"; Real TC_434_1074.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_434_1074.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_434_1074.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_434_1074.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_434_1074.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_434_1074.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_434_1074.G(quantity = "ThermalConductance", unit = "W/K") = 5.11149620472836e-05 "Constant thermal conductance of material"; Real TC_435_436.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_435_436.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_435_436.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_435_436.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_435_436.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_435_436.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_435_436.G(quantity = "ThermalConductance", unit = "W/K") = 8.57149431635148e-05 "Constant thermal conductance of material"; Real TC_435_489.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_435_489.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_435_489.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_435_489.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_435_489.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_435_489.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_435_489.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100005989817319 "Constant thermal conductance of material"; Real TC_435_1075.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_435_1075.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_435_1075.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_435_1075.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_435_1075.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_435_1075.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_435_1075.G(quantity = "ThermalConductance", unit = "W/K") = 5.11143478969952e-05 "Constant thermal conductance of material"; Real TC_436_437.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_436_437.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_436_437.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_436_437.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_436_437.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_436_437.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_436_437.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199959910913116 "Constant thermal conductance of material"; Real TC_436_490.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_436_490.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_436_490.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_436_490.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_436_490.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_436_490.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_436_490.G(quantity = "ThermalConductance", unit = "W/K") = 0.000399876543209815 "Constant thermal conductance of material"; Real TC_436_1076.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_436_1076.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_436_1076.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_436_1076.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_436_1076.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_436_1076.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_436_1076.G(quantity = "ThermalConductance", unit = "W/K") = 2.04455241524413e-05 "Constant thermal conductance of material"; Real TC_437_439.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_437_439.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_437_439.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_437_439.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_437_439.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_437_439.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_437_439.G(quantity = "ThermalConductance", unit = "W/K") = 9.99983308017159e-05 "Constant thermal conductance of material"; Real TC_437_491.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_437_491.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_437_491.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_437_491.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_437_491.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_437_491.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_437_491.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200024820739114 "Constant thermal conductance of material"; Real TC_438_440.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_438_440.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_438_440.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_438_440.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_438_440.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_438_440.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_438_440.G(quantity = "ThermalConductance", unit = "W/K") = 4.00008655073676e-05 "Constant thermal conductance of material"; Real TC_438_492.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_438_492.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_438_492.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_438_492.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_438_492.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_438_492.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_438_492.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999900875598877 "Constant thermal conductance of material"; Real TC_438_1066.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_438_1066.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_438_1066.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_438_1066.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_438_1066.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_438_1066.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_438_1066.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124597506355163 "Constant thermal conductance of material"; Real TC_439_441.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_439_441.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_439_441.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_439_441.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_439_441.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_439_441.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_439_441.G(quantity = "ThermalConductance", unit = "W/K") = 3.99994436795037e-05 "Constant thermal conductance of material"; Real TC_439_493.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_439_493.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_439_493.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_439_493.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_439_493.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_439_493.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_439_493.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999974776138223 "Constant thermal conductance of material"; Real TC_439_1076.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_439_1076.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_439_1076.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_439_1076.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_439_1076.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_439_1076.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_439_1076.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124607849215698 "Constant thermal conductance of material"; Real TC_440_442.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_440_442.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_440_442.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_440_442.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_440_442.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_440_442.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_440_442.G(quantity = "ThermalConductance", unit = "W/K") = 3.52944793764508e-05 "Constant thermal conductance of material"; Real TC_440_494.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_440_494.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_440_494.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_440_494.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_440_494.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_440_494.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_440_494.G(quantity = "ThermalConductance", unit = "W/K") = 0.00200000000000003 "Constant thermal conductance of material"; Real TC_440_1077.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_440_1077.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_440_1077.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_440_1077.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_440_1077.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_440_1077.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_440_1077.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249203532883064 "Constant thermal conductance of material"; Real TC_441_443.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_441_443.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_441_443.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_441_443.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_441_443.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_441_443.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_441_443.G(quantity = "ThermalConductance", unit = "W/K") = 3.52941420959443e-05 "Constant thermal conductance of material"; Real TC_441_495.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_441_495.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_441_495.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_441_495.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_441_495.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_441_495.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_441_495.G(quantity = "ThermalConductance", unit = "W/K") = 0.00200003961651216 "Constant thermal conductance of material"; Real TC_441_1087.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_441_1087.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_441_1087.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_441_1087.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_441_1087.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_441_1087.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_441_1087.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249200784166985 "Constant thermal conductance of material"; Real TC_442_444.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_442_444.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_442_444.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_442_444.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_442_444.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_442_444.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_442_444.G(quantity = "ThermalConductance", unit = "W/K") = 4.28563004894158e-05 "Constant thermal conductance of material"; Real TC_442_496.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_442_496.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_442_496.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_442_496.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_442_496.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_442_496.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_442_496.G(quantity = "ThermalConductance", unit = "W/K") = 0.00140000750201617 "Constant thermal conductance of material"; Real TC_442_1088.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_442_1088.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_442_1088.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_442_1088.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_442_1088.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_442_1088.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_442_1088.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174440879641166 "Constant thermal conductance of material"; Real TC_443_445.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_443_445.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_443_445.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_443_445.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_443_445.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_443_445.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_443_445.G(quantity = "ThermalConductance", unit = "W/K") = 4.28571428571431e-05 "Constant thermal conductance of material"; Real TC_443_497.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_443_497.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_443_497.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_443_497.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_443_497.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_443_497.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_443_497.G(quantity = "ThermalConductance", unit = "W/K") = 0.00140001032151519 "Constant thermal conductance of material"; Real TC_443_1094.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_443_1094.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_443_1094.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_443_1094.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_443_1094.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_443_1094.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_443_1094.G(quantity = "ThermalConductance", unit = "W/K") = 0.00017443988587026 "Constant thermal conductance of material"; Real TC_444_446.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_444_446.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_444_446.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_444_446.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_444_446.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_444_446.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_444_446.G(quantity = "ThermalConductance", unit = "W/K") = 4.28587780798392e-05 "Constant thermal conductance of material"; Real TC_444_498.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_444_498.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_444_498.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_444_498.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_444_498.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_444_498.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_444_498.G(quantity = "ThermalConductance", unit = "W/K") = 0.00139999280911803 "Constant thermal conductance of material"; Real TC_444_1095.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_444_1095.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_444_1095.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_444_1095.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_444_1095.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_444_1095.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_444_1095.G(quantity = "ThermalConductance", unit = "W/K") = 0.00017444045456137 "Constant thermal conductance of material"; Real TC_445_447.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_445_447.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_445_447.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_445_447.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_445_447.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_445_447.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_445_447.G(quantity = "ThermalConductance", unit = "W/K") = 4.28559398496227e-05 "Constant thermal conductance of material"; Real TC_445_499.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_445_499.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_445_499.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_445_499.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_445_499.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_445_499.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_445_499.G(quantity = "ThermalConductance", unit = "W/K") = 0.00139999806094451 "Constant thermal conductance of material"; Real TC_445_1030.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_445_1030.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_445_1030.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_445_1030.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_445_1030.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_445_1030.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_445_1030.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174439719377647 "Constant thermal conductance of material"; Real TC_446_448.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_446_448.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_446_448.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_446_448.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_446_448.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_446_448.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_446_448.G(quantity = "ThermalConductance", unit = "W/K") = 2.85725855436309e-05 "Constant thermal conductance of material"; Real TC_446_500.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_446_500.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_446_500.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_446_500.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_446_500.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_446_500.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_446_500.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014000035560613 "Constant thermal conductance of material"; Real TC_446_1031.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_446_1031.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_446_1031.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_446_1031.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_446_1031.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_446_1031.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_446_1031.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174441279985633 "Constant thermal conductance of material"; Real TC_447_449.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_447_449.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_447_449.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_447_449.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_447_449.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_447_449.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_447_449.G(quantity = "ThermalConductance", unit = "W/K") = 2.85715472826993e-05 "Constant thermal conductance of material"; Real TC_447_501.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_447_501.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_447_501.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_447_501.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_447_501.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_447_501.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_447_501.G(quantity = "ThermalConductance", unit = "W/K") = 0.00140002851575495 "Constant thermal conductance of material"; Real TC_447_1037.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_447_1037.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_447_1037.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_447_1037.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_447_1037.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_447_1037.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_447_1037.G(quantity = "ThermalConductance", unit = "W/K") = 0.000174440260868273 "Constant thermal conductance of material"; Real TC_448_450.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_448_450.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_448_450.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_448_450.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_448_450.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_448_450.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_448_450.G(quantity = "ThermalConductance", unit = "W/K") = 3.15785277703959e-05 "Constant thermal conductance of material"; Real TC_448_502.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_448_502.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_448_502.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_448_502.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_448_502.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_448_502.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_448_502.G(quantity = "ThermalConductance", unit = "W/K") = 0.00280008490465915 "Constant thermal conductance of material"; Real TC_448_1038.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_448_1038.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_448_1038.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_448_1038.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_448_1038.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_448_1038.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_448_1038.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348877107592589 "Constant thermal conductance of material"; Real TC_449_451.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_449_451.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_449_451.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_449_451.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_449_451.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_449_451.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_449_451.G(quantity = "ThermalConductance", unit = "W/K") = 3.15792851698822e-05 "Constant thermal conductance of material"; Real TC_449_503.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_449_503.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_449_503.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_449_503.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_449_503.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_449_503.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_449_503.G(quantity = "ThermalConductance", unit = "W/K") = 0.00279998170006405 "Constant thermal conductance of material"; Real TC_449_1048.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_449_1048.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_449_1048.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_449_1048.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_449_1048.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_449_1048.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_449_1048.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348887109687751 "Constant thermal conductance of material"; Real TC_450_452.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_450_452.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_450_452.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_450_452.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_450_452.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_450_452.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_450_452.G(quantity = "ThermalConductance", unit = "W/K") = 6.00039580447236e-05 "Constant thermal conductance of material"; Real TC_450_504.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_450_504.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_450_504.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_450_504.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_450_504.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_450_504.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_450_504.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000001 "Constant thermal conductance of material"; Real TC_450_1049.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_450_1049.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_450_1049.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_450_1049.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_450_1049.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_450_1049.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_450_1049.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001246010904509 "Constant thermal conductance of material"; Real TC_451_453.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_451_453.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_451_453.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_451_453.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_451_453.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_451_453.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_451_453.G(quantity = "ThermalConductance", unit = "W/K") = 5.99972855591781e-05 "Constant thermal conductance of material"; Real TC_451_505.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_451_505.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_451_505.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_451_505.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_451_505.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_451_505.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_451_505.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999982026026311 "Constant thermal conductance of material"; Real TC_451_1059.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_451_1059.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_451_1059.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_451_1059.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_451_1059.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_451_1059.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_451_1059.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600855031393 "Constant thermal conductance of material"; Real TC_452_454.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_452_454.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_452_454.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_452_454.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_452_454.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_452_454.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_452_454.G(quantity = "ThermalConductance", unit = "W/K") = 5.99963359226149e-05 "Constant thermal conductance of material"; Real TC_452_506.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_452_506.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_452_506.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_452_506.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_452_506.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_452_506.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_452_506.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_452_1060.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_452_1060.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_452_1060.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_452_1060.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_452_1060.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_452_1060.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_452_1060.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600136652329 "Constant thermal conductance of material"; Real TC_453_455.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_453_455.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_453_455.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_453_455.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_453_455.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_453_455.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_453_455.G(quantity = "ThermalConductance", unit = "W/K") = 6.00308123249126e-05 "Constant thermal conductance of material"; Real TC_453_507.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_453_507.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_453_507.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_453_507.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_453_507.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_453_507.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_453_507.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999981861384707 "Constant thermal conductance of material"; Real TC_453_976.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_453_976.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_453_976.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_453_976.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_453_976.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_453_976.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_453_976.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601287600358 "Constant thermal conductance of material"; Real TC_454_456.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_454_456.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_454_456.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_454_456.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_454_456.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_454_456.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_454_456.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000018e-05 "Constant thermal conductance of material"; Real TC_454_508.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_454_508.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_454_508.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_454_508.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_454_508.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_454_508.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_454_508.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999995 "Constant thermal conductance of material"; Real TC_454_977.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_454_977.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_454_977.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_454_977.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_454_977.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_454_977.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_454_977.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124599815585859 "Constant thermal conductance of material"; Real TC_455_457.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_455_457.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_455_457.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_455_457.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_455_457.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_455_457.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_455_457.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000014e-05 "Constant thermal conductance of material"; Real TC_455_509.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_455_509.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_455_509.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_455_509.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_455_509.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_455_509.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_455_509.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100002737800816 "Constant thermal conductance of material"; Real TC_455_984.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_455_984.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_455_984.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_455_984.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_455_984.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_455_984.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_455_984.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601293418781 "Constant thermal conductance of material"; Real TC_456_458.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_456_458.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_456_458.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_456_458.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_456_458.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_456_458.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_456_458.G(quantity = "ThermalConductance", unit = "W/K") = 6.00038925652067e-05 "Constant thermal conductance of material"; Real TC_456_510.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_456_510.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_456_510.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_456_510.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_456_510.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_456_510.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_456_510.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_456_985.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_456_985.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_456_985.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_456_985.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_456_985.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_456_985.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_456_985.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601527966341 "Constant thermal conductance of material"; Real TC_457_459.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_457_459.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_457_459.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_457_459.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_457_459.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_457_459.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_457_459.G(quantity = "ThermalConductance", unit = "W/K") = 6.00021502293574e-05 "Constant thermal conductance of material"; Real TC_457_511.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_457_511.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_457_511.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_457_511.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_457_511.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_457_511.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_457_511.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999963488325392 "Constant thermal conductance of material"; Real TC_457_989.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_457_989.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_457_989.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_457_989.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_457_989.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_457_989.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_457_989.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601417462431 "Constant thermal conductance of material"; Real TC_458_460.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_458_460.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_458_460.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_458_460.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_458_460.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_458_460.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_458_460.G(quantity = "ThermalConductance", unit = "W/K") = 5.99978530022185e-05 "Constant thermal conductance of material"; Real TC_458_512.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_458_512.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_458_512.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_458_512.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_458_512.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_458_512.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_458_512.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999980729949511 "Constant thermal conductance of material"; Real TC_458_990.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_458_990.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_458_990.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_458_990.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_458_990.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_458_990.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_458_990.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600911460747 "Constant thermal conductance of material"; Real TC_459_461.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_459_461.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_459_461.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_459_461.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_459_461.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_459_461.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_459_461.G(quantity = "ThermalConductance", unit = "W/K") = 5.99992927739175e-05 "Constant thermal conductance of material"; Real TC_459_513.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_459_513.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_459_513.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_459_513.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_459_513.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_459_513.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_459_513.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000910838062 "Constant thermal conductance of material"; Real TC_459_997.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_459_997.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_459_997.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_459_997.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_459_997.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_459_997.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_459_997.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124599777489023 "Constant thermal conductance of material"; Real TC_460_462.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_460_462.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_460_462.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_460_462.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_460_462.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_460_462.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_460_462.G(quantity = "ThermalConductance", unit = "W/K") = 2.99996989266735e-05 "Constant thermal conductance of material"; Real TC_460_514.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_460_514.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_460_514.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_460_514.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_460_514.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_460_514.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_460_514.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100002002683596 "Constant thermal conductance of material"; Real TC_460_998.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_460_998.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_460_998.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_460_998.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_460_998.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_460_998.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_460_998.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600091620453 "Constant thermal conductance of material"; Real TC_461_463.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_461_463.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_461_463.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_461_463.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_461_463.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_461_463.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_461_463.G(quantity = "ThermalConductance", unit = "W/K") = 3e-05 "Constant thermal conductance of material"; Real TC_461_515.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_461_515.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_461_515.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_461_515.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_461_515.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_461_515.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_461_515.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999961234299889 "Constant thermal conductance of material"; Real TC_461_1005.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_461_1005.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_461_1005.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_461_1005.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_461_1005.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_461_1005.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_461_1005.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124600699806644 "Constant thermal conductance of material"; Real TC_462_464.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_462_464.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_462_464.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_462_464.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_462_464.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_462_464.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_462_464.G(quantity = "ThermalConductance", unit = "W/K") = 2.9999840362696e-05 "Constant thermal conductance of material"; Real TC_462_516.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_462_516.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_462_516.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_462_516.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_462_516.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_462_516.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_462_516.G(quantity = "ThermalConductance", unit = "W/K") = 0.00299997607483793 "Constant thermal conductance of material"; Real TC_462_1006.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_462_1006.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_462_1006.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_462_1006.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_462_1006.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_462_1006.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_462_1006.G(quantity = "ThermalConductance", unit = "W/K") = 0.000373796379137432 "Constant thermal conductance of material"; Real TC_463_465.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_463_465.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_463_465.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_463_465.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_463_465.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_463_465.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_463_465.G(quantity = "ThermalConductance", unit = "W/K") = 2.99993326740963e-05 "Constant thermal conductance of material"; Real TC_463_517.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_463_517.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_463_517.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_463_517.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_463_517.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_463_517.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_463_517.G(quantity = "ThermalConductance", unit = "W/K") = 0.00299997857158163 "Constant thermal conductance of material"; Real TC_463_1016.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_463_1016.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_463_1016.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_463_1016.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_463_1016.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_463_1016.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_463_1016.G(quantity = "ThermalConductance", unit = "W/K") = 0.00037381238935145 "Constant thermal conductance of material"; Real TC_464_466.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_464_466.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_464_466.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_464_466.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_464_466.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_464_466.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_464_466.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_464_518.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_464_518.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_464_518.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_464_518.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_464_518.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_464_518.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_464_518.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100004209640078 "Constant thermal conductance of material"; Real TC_464_1017.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_464_1017.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_464_1017.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_464_1017.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_464_1017.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_464_1017.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_464_1017.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124599140145472 "Constant thermal conductance of material"; Real TC_465_478.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_465_478.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_465_478.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_465_478.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_465_478.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_465_478.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_465_478.G(quantity = "ThermalConductance", unit = "W/K") = 9.99999999999994e-05 "Constant thermal conductance of material"; Real TC_465_519.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_465_519.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_465_519.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_465_519.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_465_519.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_465_519.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_465_519.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999956 "Constant thermal conductance of material"; Real TC_465_1027.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_465_1027.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_465_1027.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_465_1027.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_465_1027.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_465_1027.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_465_1027.G(quantity = "ThermalConductance", unit = "W/K") = 0.000124601220883077 "Constant thermal conductance of material"; Real TC_466_467.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_466_467.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_466_467.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_466_467.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_466_467.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_466_467.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_466_467.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200029850746258 "Constant thermal conductance of material"; Real TC_466_520.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_466_520.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_466_520.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_466_520.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_466_520.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_466_520.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_466_520.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199949999999992 "Constant thermal conductance of material"; Real TC_467_468.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_467_468.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_467_468.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_467_468.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_467_468.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_467_468.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_467_468.G(quantity = "ThermalConductance", unit = "W/K") = 8.57132477597488e-05 "Constant thermal conductance of material"; Real TC_467_521.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_467_521.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_467_521.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_467_521.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_467_521.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_467_521.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_467_521.G(quantity = "ThermalConductance", unit = "W/K") = 0.000400736842105148 "Constant thermal conductance of material"; Real TC_467_1017.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_467_1017.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_467_1017.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_467_1017.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_467_1017.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_467_1017.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_467_1017.G(quantity = "ThermalConductance", unit = "W/K") = 2.04450930317403e-05 "Constant thermal conductance of material"; Real TC_468_469.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_468_469.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_468_469.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_468_469.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_468_469.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_468_469.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_468_469.G(quantity = "ThermalConductance", unit = "W/K") = 5.99986259332199e-05 "Constant thermal conductance of material"; Real TC_468_522.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_468_522.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_468_522.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_468_522.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_468_522.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_468_522.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_468_522.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100037470726004 "Constant thermal conductance of material"; Real TC_468_1018.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_468_1018.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_468_1018.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_468_1018.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_468_1018.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_468_1018.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_468_1018.G(quantity = "ThermalConductance", unit = "W/K") = 5.11138576553221e-05 "Constant thermal conductance of material"; Real TC_469_470.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_469_470.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_469_470.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_469_470.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_469_470.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_469_470.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_469_470.G(quantity = "ThermalConductance", unit = "W/K") = 5.99981010254468e-05 "Constant thermal conductance of material"; Real TC_469_523.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_469_523.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_469_523.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_469_523.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_469_523.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_469_523.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_469_523.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100016574585633 "Constant thermal conductance of material"; Real TC_469_1019.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_469_1019.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_469_1019.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_469_1019.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_469_1019.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_469_1019.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_469_1019.G(quantity = "ThermalConductance", unit = "W/K") = 5.111481591955e-05 "Constant thermal conductance of material"; Real TC_470_471.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_470_471.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_470_471.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_470_471.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_470_471.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_470_471.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_470_471.G(quantity = "ThermalConductance", unit = "W/K") = 6.00070462232248e-05 "Constant thermal conductance of material"; Real TC_470_524.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_470_524.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_470_524.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_470_524.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_470_524.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_470_524.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_470_524.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999823008849478 "Constant thermal conductance of material"; Real TC_470_1020.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_470_1020.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_470_1020.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_470_1020.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_470_1020.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_470_1020.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_470_1020.G(quantity = "ThermalConductance", unit = "W/K") = 5.11144479989554e-05 "Constant thermal conductance of material"; Real TC_471_472.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_471_472.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_471_472.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_471_472.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_471_472.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_471_472.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_471_472.G(quantity = "ThermalConductance", unit = "W/K") = 6.00344827586231e-05 "Constant thermal conductance of material"; Real TC_471_525.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_471_525.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_471_525.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_471_525.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_471_525.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_471_525.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_471_525.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100038716814172 "Constant thermal conductance of material"; Real TC_471_1021.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_471_1021.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_471_1021.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_471_1021.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_471_1021.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_471_1021.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_471_1021.G(quantity = "ThermalConductance", unit = "W/K") = 5.11135231270188e-05 "Constant thermal conductance of material"; Real TC_472_473.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_472_473.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_472_473.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_472_473.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_472_473.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_472_473.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_472_473.G(quantity = "ThermalConductance", unit = "W/K") = 5.99981981981998e-05 "Constant thermal conductance of material"; Real TC_472_526.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_472_526.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_472_526.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_472_526.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_472_526.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_472_526.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_472_526.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100024777006938 "Constant thermal conductance of material"; Real TC_472_1022.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_472_1022.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_472_1022.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_472_1022.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_472_1022.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_472_1022.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_472_1022.G(quantity = "ThermalConductance", unit = "W/K") = 5.11146328578975e-05 "Constant thermal conductance of material"; Real TC_473_474.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_473_474.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_473_474.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_473_474.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_473_474.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_473_474.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_473_474.G(quantity = "ThermalConductance", unit = "W/K") = 6.00026431718051e-05 "Constant thermal conductance of material"; Real TC_473_527.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_473_527.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_473_527.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_473_527.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_473_527.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_473_527.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_473_527.G(quantity = "ThermalConductance", unit = "W/K") = 0.0010001376778339 "Constant thermal conductance of material"; Real TC_473_1023.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_473_1023.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_473_1023.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_473_1023.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_473_1023.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_473_1023.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_473_1023.G(quantity = "ThermalConductance", unit = "W/K") = 5.11135821741315e-05 "Constant thermal conductance of material"; Real TC_474_475.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_474_475.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_474_475.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_474_475.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_474_475.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_474_475.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_474_475.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000003e-05 "Constant thermal conductance of material"; Real TC_474_528.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_474_528.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_474_528.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_474_528.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_474_528.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_474_528.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_474_528.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000007 "Constant thermal conductance of material"; Real TC_474_1024.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_474_1024.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_474_1024.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_474_1024.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_474_1024.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_474_1024.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_474_1024.G(quantity = "ThermalConductance", unit = "W/K") = 5.11129006455881e-05 "Constant thermal conductance of material"; Real TC_475_476.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_475_476.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_475_476.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_475_476.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_475_476.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_475_476.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_475_476.G(quantity = "ThermalConductance", unit = "W/K") = 5.99985559914321e-05 "Constant thermal conductance of material"; Real TC_475_529.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_475_529.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_475_529.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_475_529.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_475_529.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_475_529.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_475_529.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999843749999971 "Constant thermal conductance of material"; Real TC_475_1025.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_475_1025.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_475_1025.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_475_1025.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_475_1025.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_475_1025.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_475_1025.G(quantity = "ThermalConductance", unit = "W/K") = 5.11140162844567e-05 "Constant thermal conductance of material"; Real TC_476_477.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_476_477.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_476_477.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_476_477.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_476_477.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_476_477.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_476_477.G(quantity = "ThermalConductance", unit = "W/K") = 8.57124422535937e-05 "Constant thermal conductance of material"; Real TC_476_530.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_476_530.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_476_530.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_476_530.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_476_530.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_476_530.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_476_530.G(quantity = "ThermalConductance", unit = "W/K") = 0.0010001386481803 "Constant thermal conductance of material"; Real TC_476_1026.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_476_1026.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_476_1026.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_476_1026.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_476_1026.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_476_1026.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_476_1026.G(quantity = "ThermalConductance", unit = "W/K") = 5.11146727916354e-05 "Constant thermal conductance of material"; Real TC_477_478.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_477_478.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_477_478.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_477_478.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_477_478.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_477_478.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_477_478.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200036747818098 "Constant thermal conductance of material"; Real TC_477_531.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_477_531.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_477_531.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_477_531.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_477_531.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_477_531.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_477_531.G(quantity = "ThermalConductance", unit = "W/K") = 0.000400228758169985 "Constant thermal conductance of material"; Real TC_477_1027.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_477_1027.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_477_1027.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_477_1027.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_477_1027.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_477_1027.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_477_1027.G(quantity = "ThermalConductance", unit = "W/K") = 2.04457948305879e-05 "Constant thermal conductance of material"; Real TC_478_532.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_478_532.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_478_532.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_478_532.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_478_532.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_478_532.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_478_532.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199968907889628 "Constant thermal conductance of material"; Real TC_479_480.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_479_480.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_479_480.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_479_480.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_479_480.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_479_480.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_479_480.G(quantity = "ThermalConductance", unit = "W/K") = 0.00040004361098996 "Constant thermal conductance of material"; Real TC_479_492.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_479_492.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_479_492.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_479_492.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_479_492.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_479_492.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_479_492.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200011088113543 "Constant thermal conductance of material"; Real TC_479_533.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_479_533.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_479_533.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_479_533.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_479_533.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_479_533.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_479_533.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200005094243511 "Constant thermal conductance of material"; Real TC_480_481.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_480_481.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_480_481.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_480_481.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_480_481.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_480_481.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_480_481.G(quantity = "ThermalConductance", unit = "W/K") = 0.000171426956128449 "Constant thermal conductance of material"; Real TC_480_534.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_480_534.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_480_534.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_480_534.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_480_534.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_480_534.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_480_534.G(quantity = "ThermalConductance", unit = "W/K") = 0.000400018399264033 "Constant thermal conductance of material"; Real TC_480_920.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_480_920.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_480_920.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_480_920.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_480_920.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_480_920.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_480_920.G(quantity = "ThermalConductance", unit = "W/K") = 4.08906766269215e-05 "Constant thermal conductance of material"; Real TC_481_482.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_481_482.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_481_482.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_481_482.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_481_482.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_481_482.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_481_482.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119999602314529 "Constant thermal conductance of material"; Real TC_481_535.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_481_535.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_481_535.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_481_535.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_481_535.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_481_535.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_481_535.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100008080155138 "Constant thermal conductance of material"; Real TC_481_921.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_481_921.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_481_921.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_481_921.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_481_921.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_481_921.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_481_921.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102226289044455 "Constant thermal conductance of material"; Real TC_482_483.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_482_483.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_482_483.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_482_483.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_482_483.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_482_483.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_482_483.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120003794346424 "Constant thermal conductance of material"; Real TC_482_536.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_482_536.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_482_536.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_482_536.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_482_536.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_482_536.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_482_536.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100006423845313 "Constant thermal conductance of material"; Real TC_482_922.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_482_922.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_482_922.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_482_922.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_482_922.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_482_922.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_482_922.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010222665489715 "Constant thermal conductance of material"; Real TC_483_484.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_483_484.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_483_484.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_483_484.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_483_484.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_483_484.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_483_484.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119994905756495 "Constant thermal conductance of material"; Real TC_483_537.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_483_537.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_483_537.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_483_537.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_483_537.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_483_537.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_483_537.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999939360863486 "Constant thermal conductance of material"; Real TC_483_923.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_483_923.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_483_923.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_483_923.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_483_923.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_483_923.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_483_923.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010222715343104 "Constant thermal conductance of material"; Real TC_484_485.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_484_485.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_484_485.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_484_485.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_484_485.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_484_485.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_484_485.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119992703392924 "Constant thermal conductance of material"; Real TC_484_538.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_484_538.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_484_538.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_484_538.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_484_538.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_484_538.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_484_538.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999995 "Constant thermal conductance of material"; Real TC_484_924.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_484_924.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_484_924.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_484_924.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_484_924.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_484_924.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_484_924.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102226536652051 "Constant thermal conductance of material"; Real TC_485_486.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_485_486.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_485_486.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_485_486.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_485_486.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_485_486.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_485_486.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119988098071894 "Constant thermal conductance of material"; Real TC_485_539.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_485_539.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_485_539.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_485_539.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_485_539.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_485_539.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_485_539.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999987 "Constant thermal conductance of material"; Real TC_485_925.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_485_925.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_485_925.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_485_925.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_485_925.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_485_925.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_485_925.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102228208973107 "Constant thermal conductance of material"; Real TC_486_487.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_486_487.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_486_487.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_486_487.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_486_487.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_486_487.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_486_487.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119998386576315 "Constant thermal conductance of material"; Real TC_486_540.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_486_540.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_486_540.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_486_540.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_486_540.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_486_540.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_486_540.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999941058587762 "Constant thermal conductance of material"; Real TC_486_926.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_486_926.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_486_926.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_486_926.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_486_926.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_486_926.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_486_926.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102229082688945 "Constant thermal conductance of material"; Real TC_487_488.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_487_488.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_487_488.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_487_488.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_487_488.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_487_488.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_487_488.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119999233011197 "Constant thermal conductance of material"; Real TC_487_541.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_487_541.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_487_541.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_487_541.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_487_541.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_487_541.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_487_541.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999939283545842 "Constant thermal conductance of material"; Real TC_487_927.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_487_927.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_487_927.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_487_927.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_487_927.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_487_927.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_487_927.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102227315686464 "Constant thermal conductance of material"; Real TC_488_489.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_488_489.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_488_489.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_488_489.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_488_489.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_488_489.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_488_489.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120000415636236 "Constant thermal conductance of material"; Real TC_488_542.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_488_542.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_488_542.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_488_542.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_488_542.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_488_542.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_488_542.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999987 "Constant thermal conductance of material"; Real TC_488_928.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_488_928.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_488_928.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_488_928.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_488_928.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_488_928.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_488_928.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001022265321955 "Constant thermal conductance of material"; Real TC_489_490.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_489_490.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_489_490.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_489_490.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_489_490.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_489_490.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_489_490.G(quantity = "ThermalConductance", unit = "W/K") = 0.000171426194042269 "Constant thermal conductance of material"; Real TC_489_543.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_489_543.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_489_543.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_489_543.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_489_543.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_489_543.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_489_543.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100008521516831 "Constant thermal conductance of material"; Real TC_489_929.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_489_929.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_489_929.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_489_929.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_489_929.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_489_929.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_489_929.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102227669237979 "Constant thermal conductance of material"; Real TC_490_491.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_490_491.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_490_491.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_490_491.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_490_491.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_490_491.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_490_491.G(quantity = "ThermalConductance", unit = "W/K") = 0.000400050929462711 "Constant thermal conductance of material"; Real TC_490_544.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_490_544.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_490_544.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_490_544.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_490_544.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_490_544.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_490_544.G(quantity = "ThermalConductance", unit = "W/K") = 0.00039993920972644 "Constant thermal conductance of material"; Real TC_490_930.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_490_930.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_490_930.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_490_930.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_490_930.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_490_930.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_490_930.G(quantity = "ThermalConductance", unit = "W/K") = 4.08915837242115e-05 "Constant thermal conductance of material"; Real TC_491_493.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_491_493.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_491_493.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_491_493.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_491_493.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_491_493.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_491_493.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199996403265835 "Constant thermal conductance of material"; Real TC_491_545.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_491_545.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_491_545.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_491_545.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_491_545.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_491_545.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_491_545.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199984625521637 "Constant thermal conductance of material"; Real TC_492_494.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_492_494.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_492_494.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_492_494.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_492_494.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_492_494.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_492_494.G(quantity = "ThermalConductance", unit = "W/K") = 7.99997887236531e-05 "Constant thermal conductance of material"; Real TC_492_546.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_492_546.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_492_546.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_492_546.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_492_546.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_492_546.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_492_546.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100034334763953 "Constant thermal conductance of material"; Real TC_492_920.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_492_920.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_492_920.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_492_920.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_492_920.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_492_920.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_492_920.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249193827542859 "Constant thermal conductance of material"; Real TC_493_495.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_493_495.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_493_495.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_493_495.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_493_495.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_493_495.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_493_495.G(quantity = "ThermalConductance", unit = "W/K") = 7.99997942656699e-05 "Constant thermal conductance of material"; Real TC_493_558.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_493_558.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_493_558.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_493_558.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_493_558.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_493_558.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_493_558.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000001 "Constant thermal conductance of material"; Real TC_493_930.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_493_930.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_493_930.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_493_930.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_493_930.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_493_930.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_493_930.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249206021085072 "Constant thermal conductance of material"; Real TC_494_496.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_494_496.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_494_496.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_494_496.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_494_496.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_494_496.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_494_496.G(quantity = "ThermalConductance", unit = "W/K") = 7.05880883797599e-05 "Constant thermal conductance of material"; Real TC_494_559.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_494_559.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_494_559.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_494_559.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_494_559.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_494_559.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_494_559.G(quantity = "ThermalConductance", unit = "W/K") = 0.002000071880391 "Constant thermal conductance of material"; Real TC_494_931.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_494_931.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_494_931.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_494_931.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_494_931.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_494_931.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_494_931.G(quantity = "ThermalConductance", unit = "W/K") = 0.000498388409842331 "Constant thermal conductance of material"; Real TC_495_497.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_495_497.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_495_497.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_495_497.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_495_497.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_495_497.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_495_497.G(quantity = "ThermalConductance", unit = "W/K") = 7.05881141315263e-05 "Constant thermal conductance of material"; Real TC_495_571.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_495_571.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_495_571.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_495_571.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_495_571.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_495_571.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_495_571.G(quantity = "ThermalConductance", unit = "W/K") = 0.00200000000000002 "Constant thermal conductance of material"; Real TC_495_941.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_495_941.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_495_941.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_495_941.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_495_941.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_495_941.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_495_941.G(quantity = "ThermalConductance", unit = "W/K") = 0.000498396249691587 "Constant thermal conductance of material"; Real TC_496_498.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_496_498.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_496_498.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_496_498.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_496_498.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_496_498.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_496_498.G(quantity = "ThermalConductance", unit = "W/K") = 8.57169972477949e-05 "Constant thermal conductance of material"; Real TC_496_572.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_496_572.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_496_572.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_496_572.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_496_572.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_496_572.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_496_572.G(quantity = "ThermalConductance", unit = "W/K") = 0.0014000103912298 "Constant thermal conductance of material"; Real TC_496_942.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_496_942.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_496_942.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_496_942.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_496_942.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_496_942.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_496_942.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348884111342818 "Constant thermal conductance of material"; Real TC_497_499.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_497_499.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_497_499.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_497_499.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_497_499.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_497_499.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_497_499.G(quantity = "ThermalConductance", unit = "W/K") = 8.57142857142857e-05 "Constant thermal conductance of material"; Real TC_497_584.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_497_584.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_497_584.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_497_584.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_497_584.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_497_584.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_497_584.G(quantity = "ThermalConductance", unit = "W/K") = 0.00139999550793973 "Constant thermal conductance of material"; Real TC_497_952.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_497_952.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_497_952.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_497_952.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_497_952.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_497_952.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_497_952.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348882509739594 "Constant thermal conductance of material"; Real TC_498_500.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_498_500.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_498_500.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_498_500.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_498_500.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_498_500.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_498_500.G(quantity = "ThermalConductance", unit = "W/K") = 8.5717872273655e-05 "Constant thermal conductance of material"; Real TC_498_585.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_498_585.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_498_585.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_498_585.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_498_585.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_498_585.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_498_585.G(quantity = "ThermalConductance", unit = "W/K") = 0.00140001915341892 "Constant thermal conductance of material"; Real TC_498_953.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_498_953.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_498_953.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_498_953.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_498_953.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_498_953.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_498_953.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348880664488673 "Constant thermal conductance of material"; Real TC_499_501.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_499_501.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_499_501.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_499_501.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_499_501.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_499_501.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_499_501.G(quantity = "ThermalConductance", unit = "W/K") = 8.57172285930072e-05 "Constant thermal conductance of material"; Real TC_499_597.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_499_597.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_499_597.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_499_597.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_499_597.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_499_597.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_499_597.G(quantity = "ThermalConductance", unit = "W/K") = 0.00140002025521573 "Constant thermal conductance of material"; Real TC_499_963.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_499_963.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_499_963.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_499_963.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_499_963.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_499_963.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_499_963.G(quantity = "ThermalConductance", unit = "W/K") = 0.0003488812772029 "Constant thermal conductance of material"; Real TC_500_502.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_500_502.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_500_502.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_500_502.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_500_502.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_500_502.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_500_502.G(quantity = "ThermalConductance", unit = "W/K") = 5.7147772892374e-05 "Constant thermal conductance of material"; Real TC_500_598.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_500_598.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_500_598.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_500_598.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_500_598.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_500_598.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_500_598.G(quantity = "ThermalConductance", unit = "W/K") = 0.00140002787974537 "Constant thermal conductance of material"; Real TC_500_964.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_500_964.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_500_964.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_500_964.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_500_964.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_500_964.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_500_964.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348880724917632 "Constant thermal conductance of material"; Real TC_501_503.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_501_503.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_501_503.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_501_503.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_501_503.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_501_503.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_501_503.G(quantity = "ThermalConductance", unit = "W/K") = 5.71430368599825e-05 "Constant thermal conductance of material"; Real TC_501_610.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_501_610.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_501_610.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_501_610.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_501_610.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_501_610.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_501_610.G(quantity = "ThermalConductance", unit = "W/K") = 0.00139998827644152 "Constant thermal conductance of material"; Real TC_501_974.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_501_974.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_501_974.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_501_974.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_501_974.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_501_974.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_501_974.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348881254802694 "Constant thermal conductance of material"; Real TC_502_504.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_502_504.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_502_504.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_502_504.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_502_504.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_502_504.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_502_504.G(quantity = "ThermalConductance", unit = "W/K") = 6.31575574475855e-05 "Constant thermal conductance of material"; Real TC_502_611.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_502_611.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_502_611.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_502_611.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_502_611.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_502_611.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_502_611.G(quantity = "ThermalConductance", unit = "W/K") = 0.00279998204103625 "Constant thermal conductance of material"; Real TC_502_843.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_502_843.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_502_843.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_502_843.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_502_843.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_502_843.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_502_843.G(quantity = "ThermalConductance", unit = "W/K") = 0.000697755543426069 "Constant thermal conductance of material"; Real TC_503_505.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_503_505.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_503_505.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_503_505.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_503_505.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_503_505.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_503_505.G(quantity = "ThermalConductance", unit = "W/K") = 6.31585828212841e-05 "Constant thermal conductance of material"; Real TC_503_623.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_503_623.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_503_623.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_503_623.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_503_623.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_503_623.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_503_623.G(quantity = "ThermalConductance", unit = "W/K") = 0.00279996331284968 "Constant thermal conductance of material"; Real TC_503_853.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_503_853.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_503_853.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_503_853.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_503_853.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_503_853.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_503_853.G(quantity = "ThermalConductance", unit = "W/K") = 0.000697748016328027 "Constant thermal conductance of material"; Real TC_504_506.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_504_506.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_504_506.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_504_506.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_504_506.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_504_506.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_504_506.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120001940993789 "Constant thermal conductance of material"; Real TC_504_624.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_504_624.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_504_624.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_504_624.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_504_624.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_504_624.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_504_624.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999999 "Constant thermal conductance of material"; Real TC_504_854.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_504_854.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_504_854.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_504_854.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_504_854.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_504_854.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_504_854.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249201666862784 "Constant thermal conductance of material"; Real TC_505_507.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_505_507.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_505_507.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_505_507.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_505_507.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_505_507.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_505_507.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119996683800362 "Constant thermal conductance of material"; Real TC_505_636.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_505_636.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_505_636.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_505_636.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_505_636.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_505_636.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_505_636.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999995 "Constant thermal conductance of material"; Real TC_505_864.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_505_864.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_505_864.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_505_864.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_505_864.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_505_864.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_505_864.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249202630867646 "Constant thermal conductance of material"; Real TC_506_508.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_506_508.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_506_508.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_506_508.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_506_508.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_506_508.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_506_508.G(quantity = "ThermalConductance", unit = "W/K") = 0.00011999727835613 "Constant thermal conductance of material"; Real TC_506_637.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_506_637.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_506_637.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_506_637.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_506_637.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_506_637.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_506_637.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999972 "Constant thermal conductance of material"; Real TC_506_865.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_506_865.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_506_865.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_506_865.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_506_865.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_506_865.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_506_865.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249203413712493 "Constant thermal conductance of material"; Real TC_507_509.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_507_509.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_507_509.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_507_509.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_507_509.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_507_509.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_507_509.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120017084282487 "Constant thermal conductance of material"; Real TC_507_649.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_507_649.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_507_649.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_507_649.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_507_649.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_507_649.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_507_649.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999992 "Constant thermal conductance of material"; Real TC_507_875.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_507_875.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_507_875.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_507_875.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_507_875.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_507_875.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_507_875.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249202609561666 "Constant thermal conductance of material"; Real TC_508_510.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_508_510.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_508_510.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_508_510.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_508_510.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_508_510.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_508_510.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120001339674459 "Constant thermal conductance of material"; Real TC_508_650.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_508_650.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_508_650.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_508_650.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_508_650.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_508_650.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_508_650.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000002 "Constant thermal conductance of material"; Real TC_508_876.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_508_876.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_508_876.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_508_876.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_508_876.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_508_876.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_508_876.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249200728529106 "Constant thermal conductance of material"; Real TC_509_511.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_509_511.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_509_511.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_509_511.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_509_511.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_509_511.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_509_511.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119993087955768 "Constant thermal conductance of material"; Real TC_509_662.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_509_662.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_509_662.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_509_662.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_509_662.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_509_662.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_509_662.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999980620906171 "Constant thermal conductance of material"; Real TC_509_886.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_509_886.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_509_886.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_509_886.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_509_886.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_509_886.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_509_886.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249201765711693 "Constant thermal conductance of material"; Real TC_510_512.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_510_512.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_510_512.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_510_512.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_510_512.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_510_512.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_510_512.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119979736575489 "Constant thermal conductance of material"; Real TC_510_663.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_510_663.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_510_663.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_510_663.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_510_663.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_510_663.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_510_663.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100005924521594 "Constant thermal conductance of material"; Real TC_510_887.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_510_887.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_510_887.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_510_887.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_510_887.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_510_887.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_510_887.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249202491836827 "Constant thermal conductance of material"; Real TC_511_513.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_511_513.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_511_513.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_511_513.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_511_513.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_511_513.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_511_513.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120000710757311 "Constant thermal conductance of material"; Real TC_511_675.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_511_675.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_511_675.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_511_675.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_511_675.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_511_675.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_511_675.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999995 "Constant thermal conductance of material"; Real TC_511_897.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_511_897.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_511_897.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_511_897.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_511_897.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_511_897.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_511_897.G(quantity = "ThermalConductance", unit = "W/K") = 0.00024919982917949 "Constant thermal conductance of material"; Real TC_512_514.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_512_514.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_512_514.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_512_514.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_512_514.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_512_514.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_512_514.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120003848374062 "Constant thermal conductance of material"; Real TC_512_676.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_512_676.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_512_676.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_512_676.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_512_676.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_512_676.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_512_676.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100006623393829 "Constant thermal conductance of material"; Real TC_512_898.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_512_898.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_512_898.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_512_898.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_512_898.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_512_898.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_512_898.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249199721901037 "Constant thermal conductance of material"; Real TC_513_515.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_513_515.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_513_515.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_513_515.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_513_515.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_513_515.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_513_515.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120000400368338 "Constant thermal conductance of material"; Real TC_513_688.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_513_688.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_513_688.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_513_688.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_513_688.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_513_688.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_513_688.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999992 "Constant thermal conductance of material"; Real TC_513_908.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_513_908.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_513_908.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_513_908.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_513_908.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_513_908.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_513_908.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249201798839721 "Constant thermal conductance of material"; Real TC_514_516.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_514_516.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_514_516.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_514_516.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_514_516.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_514_516.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_514_516.G(quantity = "ThermalConductance", unit = "W/K") = 5.99998396433669e-05 "Constant thermal conductance of material"; Real TC_514_689.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_514_689.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_514_689.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_514_689.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_514_689.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_514_689.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_514_689.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999994 "Constant thermal conductance of material"; Real TC_514_909.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_514_909.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_514_909.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_514_909.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_514_909.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_514_909.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_514_909.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249203756023352 "Constant thermal conductance of material"; Real TC_515_517.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_515_517.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_515_517.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_515_517.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_515_517.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_515_517.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_515_517.G(quantity = "ThermalConductance", unit = "W/K") = 6.00011281299195e-05 "Constant thermal conductance of material"; Real TC_515_701.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_515_701.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_515_701.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_515_701.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_515_701.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_515_701.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_515_701.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000001 "Constant thermal conductance of material"; Real TC_515_919.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_515_919.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_515_919.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_515_919.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_515_919.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_515_919.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_515_919.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249201017258027 "Constant thermal conductance of material"; Real TC_516_518.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_516_518.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_516_518.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_516_518.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_516_518.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_516_518.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_516_518.G(quantity = "ThermalConductance", unit = "W/K") = 5.99991380982137e-05 "Constant thermal conductance of material"; Real TC_516_702.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_516_702.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_516_702.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_516_702.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_516_702.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_516_702.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_516_702.G(quantity = "ThermalConductance", unit = "W/K") = 0.00300023702299121 "Constant thermal conductance of material"; Real TC_516_832.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_516_832.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_516_832.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_516_832.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_516_832.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_516_832.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_516_832.G(quantity = "ThermalConductance", unit = "W/K") = 0.000747603345049867 "Constant thermal conductance of material"; Real TC_517_519.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_517_519.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_517_519.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_517_519.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_517_519.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_517_519.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_517_519.G(quantity = "ThermalConductance", unit = "W/K") = 5.99991184378719e-05 "Constant thermal conductance of material"; Real TC_517_714.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_517_714.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_517_714.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_517_714.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_517_714.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_517_714.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_517_714.G(quantity = "ThermalConductance", unit = "W/K") = 0.00299988305461352 "Constant thermal conductance of material"; Real TC_517_842.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_517_842.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_517_842.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_517_842.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_517_842.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_517_842.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_517_842.G(quantity = "ThermalConductance", unit = "W/K") = 0.000747600693276767 "Constant thermal conductance of material"; Real TC_518_520.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_518_520.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_518_520.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_518_520.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_518_520.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_518_520.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_518_520.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199997963671907 "Constant thermal conductance of material"; Real TC_518_715.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_518_715.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_518_715.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_518_715.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_518_715.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_518_715.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_518_715.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100011123470535 "Constant thermal conductance of material"; Real TC_518_821.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_518_821.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_518_821.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_518_821.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_518_821.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_518_821.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_518_821.G(quantity = "ThermalConductance", unit = "W/K") = 0.00024919430506262 "Constant thermal conductance of material"; Real TC_519_532.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_519_532.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_519_532.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_519_532.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_519_532.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_519_532.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_519_532.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199997918791234 "Constant thermal conductance of material"; Real TC_519_727.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_519_727.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_519_727.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_519_727.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_519_727.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_519_727.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_519_727.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999782135076313 "Constant thermal conductance of material"; Real TC_519_831.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_519_831.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_519_831.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_519_831.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_519_831.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_519_831.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_519_831.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249194437836551 "Constant thermal conductance of material"; Real TC_520_521.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_520_521.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_520_521.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_520_521.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_520_521.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_520_521.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_520_521.G(quantity = "ThermalConductance", unit = "W/K") = 0.000399900124843937 "Constant thermal conductance of material"; Real TC_520_728.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_520_728.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_520_728.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_520_728.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_520_728.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_520_728.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_520_728.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200036036036033 "Constant thermal conductance of material"; Real TC_521_522.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_521_522.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_521_522.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_521_522.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_521_522.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_521_522.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_521_522.G(quantity = "ThermalConductance", unit = "W/K") = 0.000171428210951299 "Constant thermal conductance of material"; Real TC_521_729.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_521_729.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_521_729.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_521_729.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_521_729.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_521_729.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_521_729.G(quantity = "ThermalConductance", unit = "W/K") = 0.000400000000000006 "Constant thermal conductance of material"; Real TC_521_821.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_521_821.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_521_821.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_521_821.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_521_821.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_521_821.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_521_821.G(quantity = "ThermalConductance", unit = "W/K") = 4.08917549320614e-05 "Constant thermal conductance of material"; Real TC_522_523.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_522_523.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_522_523.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_522_523.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_522_523.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_522_523.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_522_523.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119999545361551 "Constant thermal conductance of material"; Real TC_522_730.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_522_730.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_522_730.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_522_730.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_522_730.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_522_730.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_522_730.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999985 "Constant thermal conductance of material"; Real TC_522_822.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_522_822.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_522_822.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_522_822.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_522_822.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_522_822.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_522_822.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102229137840193 "Constant thermal conductance of material"; Real TC_523_524.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_523_524.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_523_524.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_523_524.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_523_524.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_523_524.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_523_524.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120000944331651 "Constant thermal conductance of material"; Real TC_523_731.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_523_731.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_523_731.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_523_731.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_523_731.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_523_731.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_523_731.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000001 "Constant thermal conductance of material"; Real TC_523_823.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_523_823.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_523_823.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_523_823.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_523_823.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_523_823.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_523_823.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102228995999238 "Constant thermal conductance of material"; Real TC_524_525.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_524_525.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_524_525.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_524_525.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_524_525.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_524_525.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_524_525.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119995703852207 "Constant thermal conductance of material"; Real TC_524_732.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_524_732.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_524_732.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_524_732.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_524_732.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_524_732.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_524_732.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999987 "Constant thermal conductance of material"; Real TC_524_824.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_524_824.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_524_824.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_524_824.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_524_824.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_524_824.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_524_824.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102225947198462 "Constant thermal conductance of material"; Real TC_525_526.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_525_526.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_525_526.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_525_526.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_525_526.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_525_526.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_525_526.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120022805017077 "Constant thermal conductance of material"; Real TC_525_733.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_525_733.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_525_733.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_525_733.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_525_733.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_525_733.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_525_733.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000002 "Constant thermal conductance of material"; Real TC_525_825.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_525_825.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_525_825.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_525_825.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_525_825.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_525_825.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_525_825.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102228133261087 "Constant thermal conductance of material"; Real TC_526_527.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_526_527.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_526_527.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_526_527.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_526_527.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_526_527.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_526_527.G(quantity = "ThermalConductance", unit = "W/K") = 0.00011999124496586 "Constant thermal conductance of material"; Real TC_526_734.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_526_734.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_526_734.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_526_734.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_526_734.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_526_734.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_526_734.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100006964758323 "Constant thermal conductance of material"; Real TC_526_826.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_526_826.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_526_826.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_526_826.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_526_826.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_526_826.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_526_826.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102226279643961 "Constant thermal conductance of material"; Real TC_527_528.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_527_528.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_527_528.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_527_528.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_527_528.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_527_528.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_527_528.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120001741553465 "Constant thermal conductance of material"; Real TC_527_735.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_527_735.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_527_735.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_527_735.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_527_735.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_527_735.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_527_735.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000002 "Constant thermal conductance of material"; Real TC_527_827.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_527_827.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_527_827.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_527_827.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_527_827.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_527_827.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_527_827.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102227550956017 "Constant thermal conductance of material"; Real TC_528_529.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_528_529.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_528_529.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_528_529.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_528_529.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_528_529.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_528_529.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119993770024919 "Constant thermal conductance of material"; Real TC_528_736.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_528_736.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_528_736.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_528_736.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_528_736.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_528_736.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_528_736.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000001 "Constant thermal conductance of material"; Real TC_528_828.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_528_828.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_528_828.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_528_828.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_528_828.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_528_828.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_528_828.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102228485032787 "Constant thermal conductance of material"; Real TC_529_530.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_529_530.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_529_530.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_529_530.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_529_530.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_529_530.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_529_530.G(quantity = "ThermalConductance", unit = "W/K") = 0.00012000191040214 "Constant thermal conductance of material"; Real TC_529_737.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_529_737.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_529_737.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_529_737.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_529_737.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_529_737.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_529_737.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999991 "Constant thermal conductance of material"; Real TC_529_829.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_529_829.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_529_829.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_529_829.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_529_829.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_529_829.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_529_829.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010222914349277 "Constant thermal conductance of material"; Real TC_530_531.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_530_531.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_530_531.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_530_531.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_530_531.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_530_531.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_530_531.G(quantity = "ThermalConductance", unit = "W/K") = 0.000171428571428571 "Constant thermal conductance of material"; Real TC_530_738.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_530_738.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_530_738.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_530_738.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_530_738.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_530_738.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_530_738.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_530_830.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_530_830.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_530_830.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_530_830.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_530_830.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_530_830.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_530_830.G(quantity = "ThermalConductance", unit = "W/K") = 0.000102226218529083 "Constant thermal conductance of material"; Real TC_531_532.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_531_532.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_531_532.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_531_532.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_531_532.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_531_532.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_531_532.G(quantity = "ThermalConductance", unit = "W/K") = 0.000399914917753818 "Constant thermal conductance of material"; Real TC_531_739.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_531_739.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_531_739.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_531_739.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_531_739.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_531_739.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_531_739.G(quantity = "ThermalConductance", unit = "W/K") = 0.000400044336067381 "Constant thermal conductance of material"; Real TC_531_831.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_531_831.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_531_831.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_531_831.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_531_831.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_531_831.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_531_831.G(quantity = "ThermalConductance", unit = "W/K") = 4.08917632541536e-05 "Constant thermal conductance of material"; Real TC_532_740.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_532_740.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_532_740.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_532_740.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_532_740.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_532_740.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_532_740.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200032608695655 "Constant thermal conductance of material"; Real TC_533_534.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_533_534.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_533_534.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_533_534.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_533_534.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_533_534.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_533_534.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200007170000718 "Constant thermal conductance of material"; Real TC_533_546.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_533_546.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_533_546.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_533_546.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_533_546.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_533_546.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_533_546.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_534_535.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_534_535.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_534_535.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_534_535.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_534_535.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_534_535.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_534_535.G(quantity = "ThermalConductance", unit = "W/K") = 8.5713727253181e-05 "Constant thermal conductance of material"; Real TC_534_547.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_534_547.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_534_547.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_534_547.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_534_547.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_534_547.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_534_547.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199997011848023 "Constant thermal conductance of material"; Real TC_535_536.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_535_536.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_535_536.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_535_536.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_535_536.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_535_536.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_535_536.G(quantity = "ThermalConductance", unit = "W/K") = 5.99996260424068e-05 "Constant thermal conductance of material"; Real TC_535_548.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_535_548.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_535_548.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_535_548.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_535_548.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_535_548.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_535_548.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499995117235185 "Constant thermal conductance of material"; Real TC_536_537.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_536_537.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_536_537.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_536_537.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_536_537.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_536_537.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_536_537.G(quantity = "ThermalConductance", unit = "W/K") = 5.9998533670589e-05 "Constant thermal conductance of material"; Real TC_536_549.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_536_549.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_536_549.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_536_549.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_536_549.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_536_549.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_536_549.G(quantity = "ThermalConductance", unit = "W/K") = 0.0005 "Constant thermal conductance of material"; Real TC_537_538.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_537_538.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_537_538.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_537_538.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_537_538.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_537_538.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_537_538.G(quantity = "ThermalConductance", unit = "W/K") = 6.0002446782482e-05 "Constant thermal conductance of material"; Real TC_537_550.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_537_550.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_537_550.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_537_550.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_537_550.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_537_550.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_537_550.G(quantity = "ThermalConductance", unit = "W/K") = 0.0005 "Constant thermal conductance of material"; Real TC_538_539.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_538_539.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_538_539.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_538_539.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_538_539.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_538_539.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_538_539.G(quantity = "ThermalConductance", unit = "W/K") = 5.99965253648343e-05 "Constant thermal conductance of material"; Real TC_538_551.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_538_551.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_538_551.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_538_551.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_538_551.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_538_551.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_538_551.G(quantity = "ThermalConductance", unit = "W/K") = 0.000500003821665787 "Constant thermal conductance of material"; Real TC_539_540.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_539_540.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_539_540.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_539_540.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_539_540.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_539_540.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_539_540.G(quantity = "ThermalConductance", unit = "W/K") = 6.00046019328123e-05 "Constant thermal conductance of material"; Real TC_539_552.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_539_552.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_539_552.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_539_552.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_539_552.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_539_552.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_539_552.G(quantity = "ThermalConductance", unit = "W/K") = 0.000500003802830828 "Constant thermal conductance of material"; Real TC_540_541.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_540_541.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_540_541.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_540_541.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_540_541.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_540_541.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_540_541.G(quantity = "ThermalConductance", unit = "W/K") = 6.00007756748367e-05 "Constant thermal conductance of material"; Real TC_540_553.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_540_553.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_540_553.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_540_553.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_540_553.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_540_553.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_540_553.G(quantity = "ThermalConductance", unit = "W/K") = 0.000500000000000001 "Constant thermal conductance of material"; Real TC_541_542.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_541_542.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_541_542.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_541_542.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_541_542.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_541_542.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_541_542.G(quantity = "ThermalConductance", unit = "W/K") = 6.00014606003069e-05 "Constant thermal conductance of material"; Real TC_541_554.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_541_554.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_541_554.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_541_554.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_541_554.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_541_554.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_541_554.G(quantity = "ThermalConductance", unit = "W/K") = 0.000500003928439546 "Constant thermal conductance of material"; Real TC_542_543.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_542_543.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_542_543.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_542_543.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_542_543.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_542_543.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_542_543.G(quantity = "ThermalConductance", unit = "W/K") = 5.99992239639917e-05 "Constant thermal conductance of material"; Real TC_542_555.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_542_555.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_542_555.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_542_555.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_542_555.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_542_555.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_542_555.G(quantity = "ThermalConductance", unit = "W/K") = 0.000500004173866587 "Constant thermal conductance of material"; Real TC_543_544.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_543_544.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_543_544.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_543_544.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_543_544.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_543_544.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_543_544.G(quantity = "ThermalConductance", unit = "W/K") = 8.57151628021201e-05 "Constant thermal conductance of material"; Real TC_543_556.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_543_556.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_543_556.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_543_556.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_543_556.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_543_556.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_543_556.G(quantity = "ThermalConductance", unit = "W/K") = 0.0004999950445495 "Constant thermal conductance of material"; Real TC_544_545.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_544_545.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_544_545.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_544_545.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_544_545.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_544_545.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_544_545.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199992545657848 "Constant thermal conductance of material"; Real TC_544_557.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_544_557.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_544_557.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_544_557.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_544_557.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_544_557.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_544_557.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199997007152905 "Constant thermal conductance of material"; Real TC_545_558.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_545_558.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_545_558.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_545_558.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_545_558.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_545_558.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_545_558.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001 "Constant thermal conductance of material"; Real TC_546_547.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_546_547.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_546_547.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_546_547.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_546_547.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_546_547.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_546_547.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_546_559.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_546_559.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_546_559.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_546_559.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_546_559.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_546_559.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_546_559.G(quantity = "ThermalConductance", unit = "W/K") = 4.00006538280269e-05 "Constant thermal conductance of material"; Real TC_547_548.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_547_548.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_547_548.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_547_548.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_547_548.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_547_548.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_547_548.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428576375662292 "Constant thermal conductance of material"; Real TC_547_560.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_547_560.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_547_560.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_547_560.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_547_560.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_547_560.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_547_560.G(quantity = "ThermalConductance", unit = "W/K") = 7.99991225761165e-05 "Constant thermal conductance of material"; Real TC_547_920.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_547_920.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_547_920.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_547_920.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_547_920.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_547_920.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_547_920.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249199663016007 "Constant thermal conductance of material"; Real TC_548_549.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_548_549.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_548_549.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_548_549.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_548_549.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_548_549.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_548_549.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299995857555128 "Constant thermal conductance of material"; Real TC_548_561.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_548_561.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_548_561.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_548_561.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_548_561.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_548_561.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_548_561.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200000332973167 "Constant thermal conductance of material"; Real TC_548_921.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_548_921.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_548_921.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_548_921.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_548_921.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_548_921.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_548_921.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623002963271742 "Constant thermal conductance of material"; Real TC_549_550.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_549_550.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_549_550.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_549_550.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_549_550.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_549_550.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_549_550.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300002960068673 "Constant thermal conductance of material"; Real TC_549_562.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_549_562.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_549_562.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_549_562.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_549_562.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_549_562.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_549_562.G(quantity = "ThermalConductance", unit = "W/K") = 0.00019999707414126 "Constant thermal conductance of material"; Real TC_549_922.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_549_922.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_549_922.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_549_922.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_549_922.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_549_922.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_549_922.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623002580417675 "Constant thermal conductance of material"; Real TC_550_551.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_550_551.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_550_551.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_550_551.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_550_551.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_550_551.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_550_551.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300013114754099 "Constant thermal conductance of material"; Real TC_550_563.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_550_563.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_550_563.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_550_563.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_550_563.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_550_563.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_550_563.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199995770865492 "Constant thermal conductance of material"; Real TC_550_923.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_550_923.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_550_923.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_550_923.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_550_923.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_550_923.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_550_923.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623002213417564 "Constant thermal conductance of material"; Real TC_551_552.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_551_552.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_551_552.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_551_552.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_551_552.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_551_552.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_551_552.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299971639251298 "Constant thermal conductance of material"; Real TC_551_564.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_551_564.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_551_564.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_551_564.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_551_564.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_551_564.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_551_564.G(quantity = "ThermalConductance", unit = "W/K") = 0.00019999697266176 "Constant thermal conductance of material"; Real TC_551_924.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_551_924.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_551_924.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_551_924.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_551_924.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_551_924.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_551_924.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623000809500233 "Constant thermal conductance of material"; Real TC_552_553.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_552_553.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_552_553.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_552_553.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_552_553.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_552_553.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_552_553.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299981600735974 "Constant thermal conductance of material"; Real TC_552_565.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_552_565.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_552_565.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_552_565.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_552_565.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_552_565.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_552_565.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199999726140317 "Constant thermal conductance of material"; Real TC_552_925.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_552_925.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_552_925.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_552_925.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_552_925.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_552_925.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_552_925.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623002262853719 "Constant thermal conductance of material"; Real TC_553_554.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_553_554.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_553_554.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_553_554.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_553_554.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_553_554.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_553_554.G(quantity = "ThermalConductance", unit = "W/K") = 0.00030001249453364 "Constant thermal conductance of material"; Real TC_553_566.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_553_566.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_553_566.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_553_566.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_553_566.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_553_566.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_553_566.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200006344591305 "Constant thermal conductance of material"; Real TC_553_926.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_553_926.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_553_926.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_553_926.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_553_926.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_553_926.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_553_926.G(quantity = "ThermalConductance", unit = "W/K") = 0.00062299647697337 "Constant thermal conductance of material"; Real TC_554_555.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_554_555.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_554_555.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_554_555.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_554_555.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_554_555.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_554_555.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000002 "Constant thermal conductance of material"; Real TC_554_567.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_554_567.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_554_567.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_554_567.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_554_567.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_554_567.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_554_567.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200002532211845 "Constant thermal conductance of material"; Real TC_554_927.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_554_927.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_554_927.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_554_927.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_554_927.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_554_927.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_554_927.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623005111713744 "Constant thermal conductance of material"; Real TC_555_556.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_555_556.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_555_556.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_555_556.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_555_556.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_555_556.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_555_556.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299994321247054 "Constant thermal conductance of material"; Real TC_555_568.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_555_568.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_555_568.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_555_568.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_555_568.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_555_568.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_555_568.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199994082577629 "Constant thermal conductance of material"; Real TC_555_928.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_555_928.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_555_928.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_555_928.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_555_928.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_555_928.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_555_928.G(quantity = "ThermalConductance", unit = "W/K") = 0.00062300259672601 "Constant thermal conductance of material"; Real TC_556_557.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_556_557.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_556_557.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_556_557.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_556_557.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_556_557.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_556_557.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428571428571428 "Constant thermal conductance of material"; Real TC_556_569.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_556_569.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_556_569.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_556_569.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_556_569.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_556_569.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_556_569.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200006747865987 "Constant thermal conductance of material"; Real TC_556_929.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_556_929.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_556_929.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_556_929.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_556_929.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_556_929.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_556_929.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623007813214763 "Constant thermal conductance of material"; Real TC_557_558.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_557_558.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_557_558.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_557_558.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_557_558.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_557_558.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_557_558.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_557_570.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_557_570.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_557_570.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_557_570.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_557_570.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_557_570.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_557_570.G(quantity = "ThermalConductance", unit = "W/K") = 8.0000678115517e-05 "Constant thermal conductance of material"; Real TC_557_930.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_557_930.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_557_930.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_557_930.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_557_930.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_557_930.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_557_930.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249201654040021 "Constant thermal conductance of material"; Real TC_558_571.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_558_571.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_558_571.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_558_571.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_558_571.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_558_571.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_558_571.G(quantity = "ThermalConductance", unit = "W/K") = 4.00004284421308e-05 "Constant thermal conductance of material"; Real TC_559_560.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_559_560.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_559_560.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_559_560.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_559_560.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_559_560.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_559_560.G(quantity = "ThermalConductance", unit = "W/K") = 0.00200005848551752 "Constant thermal conductance of material"; Real TC_559_572.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_559_572.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_559_572.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_559_572.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_559_572.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_559_572.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_559_572.G(quantity = "ThermalConductance", unit = "W/K") = 3.52944251326415e-05 "Constant thermal conductance of material"; Real TC_560_561.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_560_561.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_560_561.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_560_561.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_560_561.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_560_561.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_560_561.G(quantity = "ThermalConductance", unit = "W/K") = 0.000857149046168065 "Constant thermal conductance of material"; Real TC_560_573.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_560_573.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_560_573.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_560_573.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_560_573.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_560_573.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_560_573.G(quantity = "ThermalConductance", unit = "W/K") = 7.05874426243314e-05 "Constant thermal conductance of material"; Real TC_560_931.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_560_931.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_560_931.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_560_931.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_560_931.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_560_931.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_560_931.G(quantity = "ThermalConductance", unit = "W/K") = 0.00049840289893974 "Constant thermal conductance of material"; Real TC_561_562.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_561_562.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_561_562.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_561_562.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_561_562.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_561_562.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_561_562.G(quantity = "ThermalConductance", unit = "W/K") = 0.0005999987124353 "Constant thermal conductance of material"; Real TC_561_574.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_561_574.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_561_574.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_561_574.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_561_574.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_561_574.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_561_574.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176471899592037 "Constant thermal conductance of material"; Real TC_561_932.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_561_932.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_561_932.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_561_932.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_561_932.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_561_932.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_561_932.G(quantity = "ThermalConductance", unit = "W/K") = 0.00124600077616264 "Constant thermal conductance of material"; Real TC_562_563.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_562_563.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_562_563.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_562_563.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_562_563.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_562_563.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_562_563.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600003356380478 "Constant thermal conductance of material"; Real TC_562_575.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_562_575.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_562_575.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_562_575.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_562_575.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_562_575.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_562_575.G(quantity = "ThermalConductance", unit = "W/K") = 0.00017647383325365 "Constant thermal conductance of material"; Real TC_562_933.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_562_933.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_562_933.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_562_933.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_562_933.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_562_933.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_562_933.G(quantity = "ThermalConductance", unit = "W/K") = 0.00124600489522941 "Constant thermal conductance of material"; Real TC_563_564.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_563_564.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_563_564.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_563_564.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_563_564.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_563_564.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_563_564.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599981592833486 "Constant thermal conductance of material"; Real TC_563_576.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_563_576.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_563_576.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_563_576.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_563_576.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_563_576.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_563_576.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176469496550412 "Constant thermal conductance of material"; Real TC_563_934.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_563_934.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_563_934.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_563_934.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_563_934.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_563_934.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_563_934.G(quantity = "ThermalConductance", unit = "W/K") = 0.00124600257122587 "Constant thermal conductance of material"; Real TC_564_565.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_564_565.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_564_565.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_564_565.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_564_565.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_564_565.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_564_565.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599999999999948 "Constant thermal conductance of material"; Real TC_564_577.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_564_577.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_564_577.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_564_577.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_564_577.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_564_577.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_564_577.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176470588235294 "Constant thermal conductance of material"; Real TC_564_935.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_564_935.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_564_935.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_564_935.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_564_935.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_564_935.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_564_935.G(quantity = "ThermalConductance", unit = "W/K") = 0.00124600323901363 "Constant thermal conductance of material"; Real TC_565_566.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_565_566.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_565_566.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_565_566.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_565_566.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_565_566.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_565_566.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600000000000003 "Constant thermal conductance of material"; Real TC_565_578.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_565_578.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_565_578.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_565_578.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_565_578.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_565_578.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_565_578.G(quantity = "ThermalConductance", unit = "W/K") = 0.00017647134313801 "Constant thermal conductance of material"; Real TC_565_936.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_565_936.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_565_936.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_565_936.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_565_936.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_565_936.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_565_936.G(quantity = "ThermalConductance", unit = "W/K") = 0.00124600614189039 "Constant thermal conductance of material"; Real TC_566_567.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_566_567.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_566_567.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_566_567.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_566_567.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_566_567.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_566_567.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600006624051921 "Constant thermal conductance of material"; Real TC_566_579.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_566_579.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_566_579.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_566_579.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_566_579.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_566_579.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_566_579.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176471667356791 "Constant thermal conductance of material"; Real TC_566_937.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_566_937.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_566_937.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_566_937.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_566_937.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_566_937.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_566_937.G(quantity = "ThermalConductance", unit = "W/K") = 0.00124600883284695 "Constant thermal conductance of material"; Real TC_567_568.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_567_568.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_567_568.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_567_568.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_567_568.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_567_568.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_567_568.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599991396739366 "Constant thermal conductance of material"; Real TC_567_580.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_567_580.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_567_580.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_567_580.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_567_580.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_567_580.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_567_580.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176469204900877 "Constant thermal conductance of material"; Real TC_567_938.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_567_938.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_567_938.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_567_938.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_567_938.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_567_938.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_567_938.G(quantity = "ThermalConductance", unit = "W/K") = 0.00124600833450391 "Constant thermal conductance of material"; Real TC_568_569.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_568_569.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_568_569.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_568_569.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_568_569.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_568_569.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_568_569.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600001301846019 "Constant thermal conductance of material"; Real TC_568_581.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_568_581.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_568_581.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_568_581.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_568_581.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_568_581.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_568_581.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176470292196354 "Constant thermal conductance of material"; Real TC_568_939.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_568_939.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_568_939.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_568_939.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_568_939.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_568_939.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_568_939.G(quantity = "ThermalConductance", unit = "W/K") = 0.00124601024907196 "Constant thermal conductance of material"; Real TC_569_570.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_569_570.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_569_570.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_569_570.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_569_570.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_569_570.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_569_570.G(quantity = "ThermalConductance", unit = "W/K") = 0.000857130898339846 "Constant thermal conductance of material"; Real TC_569_582.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_569_582.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_569_582.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_569_582.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_569_582.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_569_582.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_569_582.G(quantity = "ThermalConductance", unit = "W/K") = 0.000176473645233795 "Constant thermal conductance of material"; Real TC_569_940.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_569_940.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_569_940.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_569_940.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_569_940.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_569_940.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_569_940.G(quantity = "ThermalConductance", unit = "W/K") = 0.00124601055066169 "Constant thermal conductance of material"; Real TC_570_571.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_570_571.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_570_571.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_570_571.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_570_571.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_570_571.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_570_571.G(quantity = "ThermalConductance", unit = "W/K") = 0.00200009473135766 "Constant thermal conductance of material"; Real TC_570_583.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_570_583.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_570_583.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_570_583.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_570_583.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_570_583.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_570_583.G(quantity = "ThermalConductance", unit = "W/K") = 7.05906539494259e-05 "Constant thermal conductance of material"; Real TC_570_941.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_570_941.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_570_941.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_570_941.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_570_941.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_570_941.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_570_941.G(quantity = "ThermalConductance", unit = "W/K") = 0.000498402726868971 "Constant thermal conductance of material"; Real TC_571_584.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_571_584.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_571_584.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_571_584.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_571_584.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_571_584.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_571_584.G(quantity = "ThermalConductance", unit = "W/K") = 3.52938041463602e-05 "Constant thermal conductance of material"; Real TC_572_573.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_572_573.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_572_573.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_572_573.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_572_573.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_572_573.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_572_573.G(quantity = "ThermalConductance", unit = "W/K") = 0.001399958532034 "Constant thermal conductance of material"; Real TC_572_585.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_572_585.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_572_585.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_572_585.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_572_585.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_572_585.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_572_585.G(quantity = "ThermalConductance", unit = "W/K") = 4.28571428571429e-05 "Constant thermal conductance of material"; Real TC_573_574.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_573_574.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_573_574.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_573_574.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_573_574.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_573_574.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_573_574.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599984973909243 "Constant thermal conductance of material"; Real TC_573_586.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_573_586.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_573_586.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_573_586.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_573_586.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_573_586.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_573_586.G(quantity = "ThermalConductance", unit = "W/K") = 8.57142857142862e-05 "Constant thermal conductance of material"; Real TC_573_942.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_573_942.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_573_942.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_573_942.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_573_942.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_573_942.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_573_942.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348884360515551 "Constant thermal conductance of material"; Real TC_574_575.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_574_575.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_574_575.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_574_575.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_574_575.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_574_575.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_574_575.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420000326251856 "Constant thermal conductance of material"; Real TC_574_587.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_574_587.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_574_587.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_574_587.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_574_587.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_574_587.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_574_587.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214285714285713 "Constant thermal conductance of material"; Real TC_574_943.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_574_943.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_574_943.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_574_943.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_574_943.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_574_943.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_574_943.G(quantity = "ThermalConductance", unit = "W/K") = 0.00087220225672247 "Constant thermal conductance of material"; Real TC_575_576.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_575_576.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_575_576.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_575_576.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_575_576.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_575_576.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_575_576.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420004465282428 "Constant thermal conductance of material"; Real TC_575_588.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_575_588.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_575_588.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_575_588.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_575_588.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_575_588.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_575_588.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214288034211167 "Constant thermal conductance of material"; Real TC_575_944.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_575_944.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_575_944.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_575_944.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_575_944.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_575_944.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_575_944.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872207268444366 "Constant thermal conductance of material"; Real TC_576_577.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_576_577.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_576_577.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_576_577.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_576_577.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_576_577.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_576_577.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419997706685013 "Constant thermal conductance of material"; Real TC_576_589.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_576_589.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_576_589.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_576_589.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_576_589.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_576_589.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_576_589.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214282906804088 "Constant thermal conductance of material"; Real TC_576_945.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_576_945.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_576_945.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_576_945.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_576_945.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_576_945.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_576_945.G(quantity = "ThermalConductance", unit = "W/K") = 0.00087220570935553 "Constant thermal conductance of material"; Real TC_577_578.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_577_578.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_577_578.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_577_578.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_577_578.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_577_578.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_577_578.G(quantity = "ThermalConductance", unit = "W/K") = 0.00042000050801392 "Constant thermal conductance of material"; Real TC_577_590.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_577_590.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_577_590.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_577_590.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_577_590.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_577_590.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_577_590.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214283342740464 "Constant thermal conductance of material"; Real TC_577_946.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_577_946.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_577_946.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_577_946.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_577_946.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_577_946.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_577_946.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872203230086364 "Constant thermal conductance of material"; Real TC_578_579.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_578_579.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_578_579.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_578_579.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_578_579.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_578_579.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_578_579.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420016004267808 "Constant thermal conductance of material"; Real TC_578_591.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_578_591.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_578_591.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_578_591.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_578_591.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_578_591.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_578_591.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214288993985031 "Constant thermal conductance of material"; Real TC_578_947.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_578_947.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_578_947.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_578_947.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_578_947.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_578_947.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_578_947.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872198732638329 "Constant thermal conductance of material"; Real TC_579_580.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_579_580.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_579_580.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_579_580.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_579_580.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_579_580.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_579_580.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420001955771619 "Constant thermal conductance of material"; Real TC_579_592.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_579_592.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_579_592.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_579_592.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_579_592.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_579_592.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_579_592.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214277924060889 "Constant thermal conductance of material"; Real TC_579_948.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_579_948.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_579_948.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_579_948.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_579_948.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_579_948.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_579_948.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872204875894913 "Constant thermal conductance of material"; Real TC_580_581.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_580_581.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_580_581.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_580_581.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_580_581.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_580_581.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_580_581.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419996875340281 "Constant thermal conductance of material"; Real TC_580_593.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_580_593.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_580_593.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_580_593.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_580_593.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_580_593.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_580_593.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214283239797686 "Constant thermal conductance of material"; Real TC_580_949.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_580_949.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_580_949.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_580_949.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_580_949.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_580_949.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_580_949.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872199779654792 "Constant thermal conductance of material"; Real TC_581_582.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_581_582.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_581_582.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_581_582.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_581_582.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_581_582.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_581_582.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419996774063471 "Constant thermal conductance of material"; Real TC_581_594.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_581_594.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_581_594.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_581_594.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_581_594.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_581_594.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_581_594.G(quantity = "ThermalConductance", unit = "W/K") = 0.00021428441472789 "Constant thermal conductance of material"; Real TC_581_950.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_581_950.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_581_950.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_581_950.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_581_950.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_581_950.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_581_950.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872206487569449 "Constant thermal conductance of material"; Real TC_582_583.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_582_583.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_582_583.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_582_583.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_582_583.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_582_583.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_582_583.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600012488877094 "Constant thermal conductance of material"; Real TC_582_595.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_582_595.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_582_595.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_582_595.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_582_595.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_582_595.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_582_595.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214283881891179 "Constant thermal conductance of material"; Real TC_582_951.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_582_951.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_582_951.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_582_951.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_582_951.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_582_951.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_582_951.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872205521853752 "Constant thermal conductance of material"; Real TC_583_584.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_583_584.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_583_584.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_583_584.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_583_584.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_583_584.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_583_584.G(quantity = "ThermalConductance", unit = "W/K") = 0.00139999636251205 "Constant thermal conductance of material"; Real TC_583_596.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_583_596.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_583_596.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_583_596.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_583_596.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_583_596.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_583_596.G(quantity = "ThermalConductance", unit = "W/K") = 8.5714617654577e-05 "Constant thermal conductance of material"; Real TC_583_952.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_583_952.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_583_952.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_583_952.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_583_952.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_583_952.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_583_952.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348879288579685 "Constant thermal conductance of material"; Real TC_584_597.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_584_597.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_584_597.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_584_597.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_584_597.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_584_597.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_584_597.G(quantity = "ThermalConductance", unit = "W/K") = 4.28577798586495e-05 "Constant thermal conductance of material"; Real TC_585_586.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_585_586.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_585_586.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_585_586.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_585_586.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_585_586.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_585_586.G(quantity = "ThermalConductance", unit = "W/K") = 0.00139998900676085 "Constant thermal conductance of material"; Real TC_585_598.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_585_598.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_585_598.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_585_598.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_585_598.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_585_598.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_585_598.G(quantity = "ThermalConductance", unit = "W/K") = 4.28591352859168e-05 "Constant thermal conductance of material"; Real TC_586_587.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_586_587.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_586_587.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_586_587.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_586_587.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_586_587.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_586_587.G(quantity = "ThermalConductance", unit = "W/K") = 0.00059999456403566 "Constant thermal conductance of material"; Real TC_586_599.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_586_599.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_586_599.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_586_599.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_586_599.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_586_599.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_586_599.G(quantity = "ThermalConductance", unit = "W/K") = 8.57075293227351e-05 "Constant thermal conductance of material"; Real TC_586_953.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_586_953.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_586_953.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_586_953.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_586_953.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_586_953.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_586_953.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348879242505013 "Constant thermal conductance of material"; Real TC_587_588.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_587_588.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_587_588.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_587_588.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_587_588.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_587_588.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_587_588.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419998835615351 "Constant thermal conductance of material"; Real TC_587_600.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_587_600.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_587_600.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_587_600.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_587_600.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_587_600.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_587_600.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214313551815764 "Constant thermal conductance of material"; Real TC_587_954.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_587_954.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_587_954.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_587_954.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_587_954.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_587_954.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_587_954.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872198287406546 "Constant thermal conductance of material"; Real TC_588_589.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_588_589.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_588_589.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_588_589.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_588_589.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_588_589.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_588_589.G(quantity = "ThermalConductance", unit = "W/K") = 0.00041999933787989 "Constant thermal conductance of material"; Real TC_588_601.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_588_601.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_588_601.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_588_601.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_588_601.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_588_601.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_588_601.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214727611940457 "Constant thermal conductance of material"; Real TC_588_955.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_588_955.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_588_955.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_588_955.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_588_955.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_588_955.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_588_955.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872201951723396 "Constant thermal conductance of material"; Real TC_589_590.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_589_590.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_589_590.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_589_590.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_589_590.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_589_590.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_589_590.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419999788205145 "Constant thermal conductance of material"; Real TC_589_602.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_589_602.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_589_602.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_589_602.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_589_602.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_589_602.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_589_602.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214289670451394 "Constant thermal conductance of material"; Real TC_589_956.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_589_956.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_589_956.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_589_956.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_589_956.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_589_956.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_589_956.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872206379326478 "Constant thermal conductance of material"; Real TC_590_591.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_590_591.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_590_591.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_590_591.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_590_591.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_590_591.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_590_591.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420009894755774 "Constant thermal conductance of material"; Real TC_590_603.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_590_603.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_590_603.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_590_603.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_590_603.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_590_603.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_590_603.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214283513888178 "Constant thermal conductance of material"; Real TC_590_957.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_590_957.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_590_957.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_590_957.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_590_957.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_590_957.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_590_957.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872199851440635 "Constant thermal conductance of material"; Real TC_591_592.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_591_592.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_591_592.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_591_592.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_591_592.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_591_592.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_591_592.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420006030453787 "Constant thermal conductance of material"; Real TC_591_604.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_591_604.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_591_604.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_591_604.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_591_604.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_591_604.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_591_604.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214286954257441 "Constant thermal conductance of material"; Real TC_591_958.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_591_958.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_591_958.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_591_958.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_591_958.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_591_958.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_591_958.G(quantity = "ThermalConductance", unit = "W/K") = 0.00087220440719472 "Constant thermal conductance of material"; Real TC_592_593.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_592_593.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_592_593.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_592_593.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_592_593.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_592_593.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_592_593.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419996411820487 "Constant thermal conductance of material"; Real TC_592_605.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_592_605.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_592_605.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_592_605.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_592_605.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_592_605.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_592_605.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214277470545808 "Constant thermal conductance of material"; Real TC_592_959.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_592_959.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_592_959.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_592_959.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_592_959.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_592_959.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_592_959.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872204206179898 "Constant thermal conductance of material"; Real TC_593_594.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_593_594.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_593_594.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_593_594.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_593_594.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_593_594.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_593_594.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419998755467056 "Constant thermal conductance of material"; Real TC_593_606.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_593_606.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_593_606.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_593_606.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_593_606.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_593_606.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_593_606.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214296028880866 "Constant thermal conductance of material"; Real TC_593_960.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_593_960.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_593_960.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_593_960.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_593_960.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_593_960.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_593_960.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872203381560007 "Constant thermal conductance of material"; Real TC_594_595.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_594_595.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_594_595.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_594_595.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_594_595.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_594_595.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_594_595.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419997836583375 "Constant thermal conductance of material"; Real TC_594_607.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_594_607.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_594_607.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_594_607.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_594_607.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_594_607.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_594_607.G(quantity = "ThermalConductance", unit = "W/K") = 0.000215509090910289 "Constant thermal conductance of material"; Real TC_594_961.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_594_961.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_594_961.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_594_961.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_594_961.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_594_961.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_594_961.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872204250582628 "Constant thermal conductance of material"; Real TC_595_596.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_595_596.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_595_596.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_595_596.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_595_596.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_595_596.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_595_596.G(quantity = "ThermalConductance", unit = "W/K") = 0.00059998731024856 "Constant thermal conductance of material"; Real TC_595_608.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_595_608.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_595_608.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_595_608.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_595_608.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_595_608.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_595_608.G(quantity = "ThermalConductance", unit = "W/K") = 0.000214287492221523 "Constant thermal conductance of material"; Real TC_595_962.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_595_962.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_595_962.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_595_962.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_595_962.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_595_962.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_595_962.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872196391683348 "Constant thermal conductance of material"; Real TC_596_597.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_596_597.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_596_597.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_596_597.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_596_597.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_596_597.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_596_597.G(quantity = "ThermalConductance", unit = "W/K") = 0.00140002257039141 "Constant thermal conductance of material"; Real TC_596_609.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_596_609.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_596_609.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_596_609.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_596_609.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_596_609.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_596_609.G(quantity = "ThermalConductance", unit = "W/K") = 8.5709876543207e-05 "Constant thermal conductance of material"; Real TC_596_963.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_596_963.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_596_963.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_596_963.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_596_963.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_596_963.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_596_963.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348879913543613 "Constant thermal conductance of material"; Real TC_597_610.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_597_610.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_597_610.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_597_610.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_597_610.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_597_610.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_597_610.G(quantity = "ThermalConductance", unit = "W/K") = 4.28594950603721e-05 "Constant thermal conductance of material"; Real TC_598_599.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_598_599.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_598_599.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_598_599.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_598_599.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_598_599.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_598_599.G(quantity = "ThermalConductance", unit = "W/K") = 0.001399988938359 "Constant thermal conductance of material"; Real TC_598_611.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_598_611.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_598_611.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_598_611.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_598_611.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_598_611.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_598_611.G(quantity = "ThermalConductance", unit = "W/K") = 2.85709510279134e-05 "Constant thermal conductance of material"; Real TC_599_600.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_599_600.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_599_600.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_599_600.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_599_600.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_599_600.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_599_600.G(quantity = "ThermalConductance", unit = "W/K") = 0.000599992477012144 "Constant thermal conductance of material"; Real TC_599_612.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_599_612.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_599_612.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_599_612.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_599_612.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_599_612.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_599_612.G(quantity = "ThermalConductance", unit = "W/K") = 5.71424942849861e-05 "Constant thermal conductance of material"; Real TC_599_964.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_599_964.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_599_964.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_599_964.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_599_964.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_599_964.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_599_964.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348883208569168 "Constant thermal conductance of material"; Real TC_600_601.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_600_601.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_600_601.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_600_601.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_600_601.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_600_601.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_600_601.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419999352352579 "Constant thermal conductance of material"; Real TC_600_613.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_600_613.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_600_613.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_600_613.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_600_613.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_600_613.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_600_613.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142862552063614 "Constant thermal conductance of material"; Real TC_600_965.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_600_965.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_600_965.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_600_965.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_600_965.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_600_965.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_600_965.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872202208161236 "Constant thermal conductance of material"; Real TC_601_602.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_601_602.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_601_602.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_601_602.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_601_602.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_601_602.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_601_602.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419996487222271 "Constant thermal conductance of material"; Real TC_601_614.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_601_614.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_601_614.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_601_614.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_601_614.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_601_614.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_601_614.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142857142857143 "Constant thermal conductance of material"; Real TC_601_966.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_601_966.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_601_966.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_601_966.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_601_966.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_601_966.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_601_966.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872203376447472 "Constant thermal conductance of material"; Real TC_602_603.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_602_603.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_602_603.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_602_603.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_602_603.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_602_603.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_602_603.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420000339737383 "Constant thermal conductance of material"; Real TC_602_615.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_602_615.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_602_615.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_602_615.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_602_615.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_602_615.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_602_615.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142852382909248 "Constant thermal conductance of material"; Real TC_602_967.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_602_967.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_602_967.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_602_967.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_602_967.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_602_967.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_602_967.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872206499088605 "Constant thermal conductance of material"; Real TC_603_604.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_603_604.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_603_604.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_603_604.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_603_604.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_603_604.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_603_604.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419993643498031 "Constant thermal conductance of material"; Real TC_603_616.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_603_616.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_603_616.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_603_616.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_603_616.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_603_616.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_603_616.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142856542566602 "Constant thermal conductance of material"; Real TC_603_968.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_603_968.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_603_968.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_603_968.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_603_968.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_603_968.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_603_968.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872206493406704 "Constant thermal conductance of material"; Real TC_604_605.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_604_605.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_604_605.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_604_605.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_604_605.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_604_605.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_604_605.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419992068887387 "Constant thermal conductance of material"; Real TC_604_617.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_604_617.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_604_617.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_604_617.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_604_617.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_604_617.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_604_617.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142856615489116 "Constant thermal conductance of material"; Real TC_604_969.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_604_969.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_604_969.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_604_969.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_604_969.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_604_969.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_604_969.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872205756406432 "Constant thermal conductance of material"; Real TC_605_606.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_605_606.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_605_606.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_605_606.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_605_606.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_605_606.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_605_606.G(quantity = "ThermalConductance", unit = "W/K") = 0.000420008721461826 "Constant thermal conductance of material"; Real TC_605_618.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_605_618.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_605_618.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_605_618.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_605_618.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_605_618.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_605_618.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142857695282289 "Constant thermal conductance of material"; Real TC_605_970.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_605_970.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_605_970.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_605_970.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_605_970.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_605_970.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_605_970.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872203182628408 "Constant thermal conductance of material"; Real TC_606_607.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_606_607.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_606_607.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_606_607.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_606_607.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_606_607.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_606_607.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419996873860262 "Constant thermal conductance of material"; Real TC_606_619.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_606_619.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_606_619.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_606_619.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_606_619.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_606_619.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_606_619.G(quantity = "ThermalConductance", unit = "W/K") = 0.00014285578936398 "Constant thermal conductance of material"; Real TC_606_971.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_606_971.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_606_971.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_606_971.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_606_971.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_606_971.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_606_971.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872203321118756 "Constant thermal conductance of material"; Real TC_607_608.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_607_608.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_607_608.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_607_608.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_607_608.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_607_608.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_607_608.G(quantity = "ThermalConductance", unit = "W/K") = 0.000419998157229293 "Constant thermal conductance of material"; Real TC_607_620.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_607_620.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_607_620.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_607_620.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_607_620.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_607_620.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_607_620.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142856676354374 "Constant thermal conductance of material"; Real TC_607_972.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_607_972.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_607_972.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_607_972.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_607_972.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_607_972.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_607_972.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872207373039487 "Constant thermal conductance of material"; Real TC_608_609.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_608_609.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_608_609.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_608_609.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_608_609.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_608_609.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_608_609.G(quantity = "ThermalConductance", unit = "W/K") = 0.000600016898484367 "Constant thermal conductance of material"; Real TC_608_621.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_608_621.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_608_621.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_608_621.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_608_621.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_608_621.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_608_621.G(quantity = "ThermalConductance", unit = "W/K") = 0.000142864923747276 "Constant thermal conductance of material"; Real TC_608_973.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_608_973.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_608_973.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_608_973.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_608_973.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_608_973.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_608_973.G(quantity = "ThermalConductance", unit = "W/K") = 0.000872208460487507 "Constant thermal conductance of material"; Real TC_609_610.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_609_610.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_609_610.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_609_610.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_609_610.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_609_610.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_609_610.G(quantity = "ThermalConductance", unit = "W/K") = 0.001399984638132 "Constant thermal conductance of material"; Real TC_609_622.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_609_622.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_609_622.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_609_622.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_609_622.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_609_622.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_609_622.G(quantity = "ThermalConductance", unit = "W/K") = 5.71503523884275e-05 "Constant thermal conductance of material"; Real TC_609_974.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_609_974.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_609_974.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_609_974.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_609_974.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_609_974.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_609_974.G(quantity = "ThermalConductance", unit = "W/K") = 0.000348882595356099 "Constant thermal conductance of material"; Real TC_610_623.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_610_623.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_610_623.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_610_623.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_610_623.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_610_623.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_610_623.G(quantity = "ThermalConductance", unit = "W/K") = 2.856926078474e-05 "Constant thermal conductance of material"; Real TC_611_612.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_611_612.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_611_612.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_611_612.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_611_612.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_611_612.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_611_612.G(quantity = "ThermalConductance", unit = "W/K") = 0.00279990345160512 "Constant thermal conductance of material"; Real TC_611_624.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_611_624.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_611_624.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_611_624.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_611_624.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_611_624.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_611_624.G(quantity = "ThermalConductance", unit = "W/K") = 3.15794315150394e-05 "Constant thermal conductance of material"; Real TC_612_613.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_612_613.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_612_613.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_612_613.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_612_613.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_612_613.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_612_613.G(quantity = "ThermalConductance", unit = "W/K") = 0.00120000703074192 "Constant thermal conductance of material"; Real TC_612_625.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_612_625.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_612_625.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_612_625.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_612_625.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_612_625.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_612_625.G(quantity = "ThermalConductance", unit = "W/K") = 6.31581602623398e-05 "Constant thermal conductance of material"; Real TC_612_843.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_612_843.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_612_843.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_612_843.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_612_843.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_612_843.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_612_843.G(quantity = "ThermalConductance", unit = "W/K") = 0.000697768389179015 "Constant thermal conductance of material"; Real TC_613_614.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_613_614.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_613_614.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_613_614.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_613_614.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_613_614.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_613_614.G(quantity = "ThermalConductance", unit = "W/K") = 0.000839990494122809 "Constant thermal conductance of material"; Real TC_613_626.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_613_626.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_613_626.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_613_626.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_613_626.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_613_626.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_613_626.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157899819727019 "Constant thermal conductance of material"; Real TC_613_844.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_613_844.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_613_844.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_613_844.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_613_844.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_613_844.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_613_844.G(quantity = "ThermalConductance", unit = "W/K") = 0.00174445986716427 "Constant thermal conductance of material"; Real TC_614_615.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_614_615.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_614_615.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_614_615.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_614_615.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_614_615.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_614_615.G(quantity = "ThermalConductance", unit = "W/K") = 0.000839999342710665 "Constant thermal conductance of material"; Real TC_614_627.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_614_627.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_614_627.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_614_627.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_614_627.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_614_627.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_614_627.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157895342812734 "Constant thermal conductance of material"; Real TC_614_845.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_614_845.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_614_845.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_614_845.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_614_845.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_614_845.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_614_845.G(quantity = "ThermalConductance", unit = "W/K") = 0.0017443469094068 "Constant thermal conductance of material"; Real TC_615_616.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_615_616.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_615_616.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_615_616.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_615_616.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_615_616.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_615_616.G(quantity = "ThermalConductance", unit = "W/K") = 0.000839973485905649 "Constant thermal conductance of material"; Real TC_615_628.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_615_628.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_615_628.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_615_628.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_615_628.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_615_628.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_615_628.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157899854156536 "Constant thermal conductance of material"; Real TC_615_846.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_615_846.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_615_846.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_615_846.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_615_846.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_615_846.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_615_846.G(quantity = "ThermalConductance", unit = "W/K") = 0.00174439828801611 "Constant thermal conductance of material"; Real TC_616_617.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_616_617.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_616_617.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_616_617.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_616_617.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_616_617.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_616_617.G(quantity = "ThermalConductance", unit = "W/K") = 0.000839994997498751 "Constant thermal conductance of material"; Real TC_616_629.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_616_629.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_616_629.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_616_629.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_616_629.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_616_629.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_616_629.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157901449275363 "Constant thermal conductance of material"; Real TC_616_847.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_616_847.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_616_847.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_616_847.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_616_847.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_616_847.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_616_847.G(quantity = "ThermalConductance", unit = "W/K") = 0.00174445231518678 "Constant thermal conductance of material"; Real TC_617_618.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_617_618.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_617_618.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_617_618.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_617_618.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_617_618.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_617_618.G(quantity = "ThermalConductance", unit = "W/K") = 0.000839999999999927 "Constant thermal conductance of material"; Real TC_617_630.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_617_630.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_617_630.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_617_630.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_617_630.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_617_630.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_617_630.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157895577199429 "Constant thermal conductance of material"; Real TC_617_848.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_617_848.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_617_848.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_617_848.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_617_848.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_617_848.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_617_848.G(quantity = "ThermalConductance", unit = "W/K") = 0.00174443160537116 "Constant thermal conductance of material"; Real TC_618_619.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_618_619.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_618_619.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_618_619.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_618_619.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_618_619.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_618_619.G(quantity = "ThermalConductance", unit = "W/K") = 0.000839969469533138 "Constant thermal conductance of material"; Real TC_618_631.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_618_631.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_618_631.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_618_631.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_618_631.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_618_631.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_618_631.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157895024703287 "Constant thermal conductance of material"; Real TC_618_849.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_618_849.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_618_849.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_618_849.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_618_849.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_618_849.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_618_849.G(quantity = "ThermalConductance", unit = "W/K") = 0.00174441762365689 "Constant thermal conductance of material"; Real TC_619_620.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_619_620.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_619_620.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_619_620.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_619_620.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_619_620.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_619_620.G(quantity = "ThermalConductance", unit = "W/K") = 0.000840000000000002 "Constant thermal conductance of material"; Real TC_619_632.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_619_632.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_619_632.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_619_632.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_619_632.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_619_632.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_619_632.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157892516069142 "Constant thermal conductance of material"; Real TC_619_850.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_619_850.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_619_850.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_619_850.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_619_850.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_619_850.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_619_850.G(quantity = "ThermalConductance", unit = "W/K") = 0.00174438091954683 "Constant thermal conductance of material"; Real TC_620_621.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_620_621.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_620_621.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_620_621.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_620_621.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_620_621.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_620_621.G(quantity = "ThermalConductance", unit = "W/K") = 0.000840017088363378 "Constant thermal conductance of material"; Real TC_620_633.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_620_633.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_620_633.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_620_633.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_620_633.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_620_633.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_620_633.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157899215680713 "Constant thermal conductance of material"; Real TC_620_851.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_620_851.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_620_851.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_620_851.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_620_851.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_620_851.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_620_851.G(quantity = "ThermalConductance", unit = "W/K") = 0.0017443914502738 "Constant thermal conductance of material"; Real TC_621_622.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_621_622.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_621_622.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_621_622.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_621_622.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_621_622.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_621_622.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012 "Constant thermal conductance of material"; Real TC_621_634.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_621_634.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_621_634.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_621_634.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_621_634.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_621_634.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_621_634.G(quantity = "ThermalConductance", unit = "W/K") = 0.000157892152851649 "Constant thermal conductance of material"; Real TC_621_852.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_621_852.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_621_852.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_621_852.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_621_852.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_621_852.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_621_852.G(quantity = "ThermalConductance", unit = "W/K") = 0.00174434862187085 "Constant thermal conductance of material"; Real TC_622_623.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_622_623.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_622_623.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_622_623.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_622_623.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_622_623.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_622_623.G(quantity = "ThermalConductance", unit = "W/K") = 0.00279990152028068 "Constant thermal conductance of material"; Real TC_622_635.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_622_635.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_622_635.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_622_635.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_622_635.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_622_635.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_622_635.G(quantity = "ThermalConductance", unit = "W/K") = 6.31601765725994e-05 "Constant thermal conductance of material"; Real TC_622_853.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_622_853.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_622_853.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_622_853.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_622_853.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_622_853.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_622_853.G(quantity = "ThermalConductance", unit = "W/K") = 0.000697753391360296 "Constant thermal conductance of material"; Real TC_623_636.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_623_636.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_623_636.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_623_636.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_623_636.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_623_636.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_623_636.G(quantity = "ThermalConductance", unit = "W/K") = 3.15777962468839e-05 "Constant thermal conductance of material"; Real TC_624_625.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_624_625.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_624_625.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_624_625.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_624_625.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_624_625.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_624_625.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999986004786368 "Constant thermal conductance of material"; Real TC_624_637.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_624_637.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_624_637.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_624_637.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_624_637.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_624_637.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_624_637.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000033e-05 "Constant thermal conductance of material"; Real TC_625_626.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_625_626.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_625_626.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_625_626.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_625_626.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_625_626.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_625_626.G(quantity = "ThermalConductance", unit = "W/K") = 0.00042856051981229 "Constant thermal conductance of material"; Real TC_625_638.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_625_638.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_625_638.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_625_638.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_625_638.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_625_638.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_625_638.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120004803073964 "Constant thermal conductance of material"; Real TC_625_854.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_625_854.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_625_854.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_625_854.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_625_854.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_625_854.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_625_854.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249200549353091 "Constant thermal conductance of material"; Real TC_626_627.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_626_627.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_626_627.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_626_627.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_626_627.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_626_627.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_626_627.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299997589606382 "Constant thermal conductance of material"; Real TC_626_639.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_626_639.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_626_639.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_626_639.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_626_639.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_626_639.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_626_639.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300005389092473 "Constant thermal conductance of material"; Real TC_626_855.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_626_855.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_626_855.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_626_855.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_626_855.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_626_855.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_626_855.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623004326205102 "Constant thermal conductance of material"; Real TC_627_628.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_627_628.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_627_628.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_627_628.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_627_628.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_627_628.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_627_628.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299996544813766 "Constant thermal conductance of material"; Real TC_627_640.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_627_640.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_627_640.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_627_640.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_627_640.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_627_640.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_627_640.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300007144898546 "Constant thermal conductance of material"; Real TC_627_856.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_627_856.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_627_856.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_627_856.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_627_856.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_627_856.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_627_856.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622997000577814 "Constant thermal conductance of material"; Real TC_628_629.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_628_629.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_628_629.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_628_629.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_628_629.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_628_629.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_628_629.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299995631280031 "Constant thermal conductance of material"; Real TC_628_641.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_628_641.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_628_641.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_628_641.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_628_641.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_628_641.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_628_641.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299996782600299 "Constant thermal conductance of material"; Real TC_628_857.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_628_857.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_628_857.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_628_857.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_628_857.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_628_857.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_628_857.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623009628713799 "Constant thermal conductance of material"; Real TC_629_630.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_629_630.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_629_630.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_629_630.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_629_630.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_629_630.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_629_630.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299988986784148 "Constant thermal conductance of material"; Real TC_629_642.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_629_642.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_629_642.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_629_642.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_629_642.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_629_642.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_629_642.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003140309011 "Constant thermal conductance of material"; Real TC_629_858.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_629_858.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_629_858.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_629_858.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_629_858.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_629_858.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_629_858.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623001683788335 "Constant thermal conductance of material"; Real TC_630_631.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_630_631.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_630_631.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_630_631.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_630_631.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_630_631.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_630_631.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003257647327 "Constant thermal conductance of material"; Real TC_630_643.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_630_643.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_630_643.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_630_643.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_630_643.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_630_643.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_630_643.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300006216457033 "Constant thermal conductance of material"; Real TC_630_859.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_630_859.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_630_859.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_630_859.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_630_859.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_630_859.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_630_859.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622997706210411 "Constant thermal conductance of material"; Real TC_631_632.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_631_632.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_631_632.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_631_632.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_631_632.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_631_632.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_631_632.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299986366734842 "Constant thermal conductance of material"; Real TC_631_644.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_631_644.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_631_644.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_631_644.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_631_644.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_631_644.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_631_644.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999291368156 "Constant thermal conductance of material"; Real TC_631_860.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_631_860.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_631_860.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_631_860.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_631_860.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_631_860.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_631_860.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622997169491364 "Constant thermal conductance of material"; Real TC_632_633.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_632_633.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_632_633.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_632_633.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_632_633.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_632_633.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_632_633.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299998383629398 "Constant thermal conductance of material"; Real TC_632_645.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_632_645.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_632_645.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_632_645.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_632_645.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_632_645.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_632_645.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300001898145512 "Constant thermal conductance of material"; Real TC_632_861.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_632_861.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_632_861.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_632_861.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_632_861.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_632_861.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_632_861.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622997327659359 "Constant thermal conductance of material"; Real TC_633_634.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_633_634.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_633_634.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_633_634.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_633_634.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_633_634.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_633_634.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300002234986479 "Constant thermal conductance of material"; Real TC_633_646.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_633_646.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_633_646.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_633_646.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_633_646.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_633_646.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_633_646.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000704855751 "Constant thermal conductance of material"; Real TC_633_862.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_633_862.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_633_862.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_633_862.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_633_862.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_633_862.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_633_862.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623002697331946 "Constant thermal conductance of material"; Real TC_634_635.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_634_635.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_634_635.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_634_635.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_634_635.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_634_635.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_634_635.G(quantity = "ThermalConductance", unit = "W/K") = 0.00042857546830626 "Constant thermal conductance of material"; Real TC_634_647.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_634_647.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_634_647.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_634_647.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_634_647.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_634_647.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_634_647.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029999244161145 "Constant thermal conductance of material"; Real TC_634_863.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_634_863.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_634_863.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_634_863.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_634_863.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_634_863.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_634_863.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623005598181977 "Constant thermal conductance of material"; Real TC_635_636.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_635_636.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_635_636.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_635_636.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_635_636.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_635_636.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_635_636.G(quantity = "ThermalConductance", unit = "W/K") = 0.0010000195114337 "Constant thermal conductance of material"; Real TC_635_648.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_635_648.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_635_648.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_635_648.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_635_648.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_635_648.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_635_648.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001199924779712 "Constant thermal conductance of material"; Real TC_635_864.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_635_864.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_635_864.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_635_864.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_635_864.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_635_864.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_635_864.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249200058581008 "Constant thermal conductance of material"; Real TC_636_649.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_636_649.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_636_649.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_636_649.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_636_649.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_636_649.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_636_649.G(quantity = "ThermalConductance", unit = "W/K") = 6.00007067137807e-05 "Constant thermal conductance of material"; Real TC_637_638.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_637_638.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_637_638.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_637_638.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_637_638.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_637_638.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_637_638.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999993 "Constant thermal conductance of material"; Real TC_637_650.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_637_650.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_637_650.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_637_650.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_637_650.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_637_650.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_637_650.G(quantity = "ThermalConductance", unit = "W/K") = 5.99981661470727e-05 "Constant thermal conductance of material"; Real TC_638_639.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_638_639.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_638_639.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_638_639.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_638_639.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_638_639.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_638_639.G(quantity = "ThermalConductance", unit = "W/K") = 0.00042856462973539 "Constant thermal conductance of material"; Real TC_638_651.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_638_651.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_638_651.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_638_651.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_638_651.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_638_651.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_638_651.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119998004191198 "Constant thermal conductance of material"; Real TC_638_865.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_638_865.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_638_865.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_638_865.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_638_865.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_638_865.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_638_865.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249198992443325 "Constant thermal conductance of material"; Real TC_639_640.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_639_640.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_639_640.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_639_640.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_639_640.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_639_640.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_639_640.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299998859645122 "Constant thermal conductance of material"; Real TC_639_652.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_639_652.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_639_652.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_639_652.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_639_652.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_639_652.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_639_652.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299994152730677 "Constant thermal conductance of material"; Real TC_639_866.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_639_866.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_639_866.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_639_866.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_639_866.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_639_866.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_639_866.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623003243679102 "Constant thermal conductance of material"; Real TC_640_641.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_640_641.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_640_641.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_640_641.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_640_641.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_640_641.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_640_641.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300001640070192 "Constant thermal conductance of material"; Real TC_640_653.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_640_653.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_640_653.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_640_653.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_640_653.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_640_653.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_640_653.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300001440652327 "Constant thermal conductance of material"; Real TC_640_867.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_640_867.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_640_867.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_640_867.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_640_867.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_640_867.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_640_867.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623009905571351 "Constant thermal conductance of material"; Real TC_641_642.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_641_642.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_641_642.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_641_642.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_641_642.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_641_642.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_641_642.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300004227793521 "Constant thermal conductance of material"; Real TC_641_654.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_641_654.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_641_654.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_641_654.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_641_654.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_641_654.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_641_654.G(quantity = "ThermalConductance", unit = "W/K") = 0.00030000384916409 "Constant thermal conductance of material"; Real TC_641_868.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_641_868.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_641_868.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_641_868.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_641_868.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_641_868.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_641_868.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622997441692954 "Constant thermal conductance of material"; Real TC_642_643.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_642_643.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_642_643.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_642_643.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_642_643.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_642_643.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_642_643.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299985538684018 "Constant thermal conductance of material"; Real TC_642_655.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_642_655.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_642_655.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_642_655.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_642_655.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_642_655.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_642_655.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300002958317309 "Constant thermal conductance of material"; Real TC_642_869.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_642_869.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_642_869.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_642_869.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_642_869.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_642_869.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_642_869.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623009366578089 "Constant thermal conductance of material"; Real TC_643_644.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_643_644.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_643_644.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_643_644.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_643_644.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_643_644.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_643_644.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299995953219215 "Constant thermal conductance of material"; Real TC_643_656.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_643_656.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_643_656.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_643_656.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_643_656.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_643_656.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_643_656.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299992282164079 "Constant thermal conductance of material"; Real TC_643_870.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_643_870.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_643_870.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_643_870.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_643_870.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_643_870.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_643_870.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623000658652796 "Constant thermal conductance of material"; Real TC_644_645.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_644_645.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_644_645.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_644_645.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_644_645.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_644_645.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_644_645.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999996 "Constant thermal conductance of material"; Real TC_644_657.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_644_657.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_644_657.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_644_657.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_644_657.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_644_657.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_644_657.G(quantity = "ThermalConductance", unit = "W/K") = 0.0003 "Constant thermal conductance of material"; Real TC_644_871.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_644_871.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_644_871.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_644_871.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_644_871.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_644_871.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_644_871.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623000567793731 "Constant thermal conductance of material"; Real TC_645_646.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_645_646.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_645_646.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_645_646.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_645_646.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_645_646.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_645_646.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300001281344901 "Constant thermal conductance of material"; Real TC_645_658.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_645_658.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_645_658.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_645_658.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_645_658.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_645_658.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_645_658.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029998908832997 "Constant thermal conductance of material"; Real TC_645_872.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_645_872.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_645_872.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_645_872.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_645_872.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_645_872.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_645_872.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622998118486203 "Constant thermal conductance of material"; Real TC_646_647.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_646_647.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_646_647.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_646_647.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_646_647.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_646_647.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_646_647.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029999928864608 "Constant thermal conductance of material"; Real TC_646_659.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_646_659.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_646_659.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_646_659.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_646_659.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_646_659.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_646_659.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300006807583654 "Constant thermal conductance of material"; Real TC_646_873.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_646_873.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_646_873.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_646_873.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_646_873.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_646_873.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_646_873.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622999608590326 "Constant thermal conductance of material"; Real TC_647_648.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_647_648.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_647_648.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_647_648.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_647_648.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_647_648.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_647_648.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428560792197156 "Constant thermal conductance of material"; Real TC_647_660.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_647_660.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_647_660.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_647_660.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_647_660.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_647_660.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_647_660.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300020576131685 "Constant thermal conductance of material"; Real TC_647_874.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_647_874.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_647_874.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_647_874.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_647_874.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_647_874.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_647_874.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622997340750416 "Constant thermal conductance of material"; Real TC_648_649.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_648_649.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_648_649.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_648_649.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_648_649.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_648_649.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_648_649.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999993 "Constant thermal conductance of material"; Real TC_648_661.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_648_661.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_648_661.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_648_661.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_648_661.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_648_661.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_648_661.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120002464268117 "Constant thermal conductance of material"; Real TC_648_875.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_648_875.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_648_875.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_648_875.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_648_875.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_648_875.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_648_875.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249201263738709 "Constant thermal conductance of material"; Real TC_649_662.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_649_662.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_649_662.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_649_662.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_649_662.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_649_662.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_649_662.G(quantity = "ThermalConductance", unit = "W/K") = 6.00149981252279e-05 "Constant thermal conductance of material"; Real TC_650_651.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_650_651.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_650_651.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_650_651.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_650_651.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_650_651.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_650_651.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_650_663.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_650_663.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_650_663.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_650_663.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_650_663.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_650_663.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_650_663.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000016e-05 "Constant thermal conductance of material"; Real TC_651_652.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_651_652.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_651_652.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_651_652.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_651_652.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_651_652.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_651_652.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428566795316707 "Constant thermal conductance of material"; Real TC_651_664.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_651_664.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_651_664.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_651_664.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_651_664.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_651_664.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_651_664.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120002436350349 "Constant thermal conductance of material"; Real TC_651_876.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_651_876.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_651_876.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_651_876.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_651_876.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_651_876.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_651_876.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249200540168778 "Constant thermal conductance of material"; Real TC_652_653.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_652_653.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_652_653.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_652_653.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_652_653.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_652_653.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_652_653.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000474849591 "Constant thermal conductance of material"; Real TC_652_665.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_652_665.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_652_665.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_652_665.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_652_665.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_652_665.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_652_665.G(quantity = "ThermalConductance", unit = "W/K") = 0.0003 "Constant thermal conductance of material"; Real TC_652_877.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_652_877.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_652_877.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_652_877.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_652_877.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_652_877.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_652_877.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622998724931596 "Constant thermal conductance of material"; Real TC_653_654.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_653_654.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_653_654.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_653_654.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_653_654.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_653_654.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_653_654.G(quantity = "ThermalConductance", unit = "W/K") = 0.00030000431660887 "Constant thermal conductance of material"; Real TC_653_666.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_653_666.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_653_666.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_653_666.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_653_666.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_653_666.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_653_666.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299998832007661 "Constant thermal conductance of material"; Real TC_653_878.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_653_878.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_653_878.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_653_878.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_653_878.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_653_878.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_653_878.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623006977904543 "Constant thermal conductance of material"; Real TC_654_655.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_654_655.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_654_655.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_654_655.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_654_655.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_654_655.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_654_655.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300015015015026 "Constant thermal conductance of material"; Real TC_654_667.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_654_667.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_654_667.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_654_667.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_654_667.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_654_667.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_654_667.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300001591435953 "Constant thermal conductance of material"; Real TC_654_879.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_654_879.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_654_879.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_654_879.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_654_879.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_654_879.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_654_879.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623002222289872 "Constant thermal conductance of material"; Real TC_655_656.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_655_656.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_655_656.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_655_656.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_655_656.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_655_656.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_655_656.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299982876712298 "Constant thermal conductance of material"; Real TC_655_668.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_655_668.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_655_668.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_655_668.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_655_668.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_655_668.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_655_668.G(quantity = "ThermalConductance", unit = "W/K") = 0.0003 "Constant thermal conductance of material"; Real TC_655_880.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_655_880.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_655_880.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_655_880.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_655_880.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_655_880.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_655_880.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622996223377432 "Constant thermal conductance of material"; Real TC_656_657.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_656_657.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_656_657.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_656_657.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_656_657.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_656_657.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_656_657.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299998383237407 "Constant thermal conductance of material"; Real TC_656_669.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_656_669.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_656_669.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_656_669.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_656_669.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_656_669.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_656_669.G(quantity = "ThermalConductance", unit = "W/K") = 0.00030000572639295 "Constant thermal conductance of material"; Real TC_656_881.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_656_881.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_656_881.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_656_881.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_656_881.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_656_881.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_656_881.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623000661146123 "Constant thermal conductance of material"; Real TC_657_658.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_657_658.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_657_658.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_657_658.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_657_658.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_657_658.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_657_658.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999999 "Constant thermal conductance of material"; Real TC_657_670.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_657_670.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_657_670.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_657_670.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_657_670.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_657_670.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_657_670.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299995151280071 "Constant thermal conductance of material"; Real TC_657_882.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_657_882.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_657_882.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_657_882.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_657_882.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_657_882.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_657_882.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623003252554934 "Constant thermal conductance of material"; Real TC_658_659.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_658_659.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_658_659.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_658_659.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_658_659.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_658_659.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_658_659.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300004688122641 "Constant thermal conductance of material"; Real TC_658_671.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_658_671.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_658_671.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_658_671.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_658_671.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_658_671.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_658_671.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000005 "Constant thermal conductance of material"; Real TC_658_883.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_658_883.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_658_883.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_658_883.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_658_883.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_658_883.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_658_883.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623005620414734 "Constant thermal conductance of material"; Real TC_659_660.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_659_660.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_659_660.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_659_660.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_659_660.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_659_660.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_659_660.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000332432442 "Constant thermal conductance of material"; Real TC_659_672.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_659_672.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_659_672.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_659_672.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_659_672.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_659_672.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_659_672.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300010640561827 "Constant thermal conductance of material"; Real TC_659_884.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_659_884.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_659_884.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_659_884.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_659_884.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_659_884.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_659_884.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623002139701008 "Constant thermal conductance of material"; Real TC_660_661.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_660_661.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_660_661.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_660_661.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_660_661.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_660_661.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_660_661.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428573511932974 "Constant thermal conductance of material"; Real TC_660_673.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_660_673.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_660_673.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_660_673.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_660_673.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_660_673.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_660_673.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300010366454148 "Constant thermal conductance of material"; Real TC_660_885.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_660_885.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_660_885.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_660_885.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_660_885.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_660_885.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_660_885.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623004624794868 "Constant thermal conductance of material"; Real TC_661_662.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_661_662.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_661_662.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_661_662.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_661_662.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_661_662.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_661_662.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999982488398565 "Constant thermal conductance of material"; Real TC_661_674.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_661_674.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_661_674.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_661_674.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_661_674.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_661_674.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_661_674.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120001494321579 "Constant thermal conductance of material"; Real TC_661_886.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_661_886.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_661_886.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_661_886.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_661_886.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_661_886.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_661_886.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249203362636479 "Constant thermal conductance of material"; Real TC_662_675.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_662_675.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_662_675.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_662_675.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_662_675.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_662_675.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_662_675.G(quantity = "ThermalConductance", unit = "W/K") = 6.00008398421093e-05 "Constant thermal conductance of material"; Real TC_663_664.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_663_664.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_663_664.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_663_664.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_663_664.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_663_664.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_663_664.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999999 "Constant thermal conductance of material"; Real TC_663_676.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_663_676.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_663_676.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_663_676.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_663_676.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_663_676.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_663_676.G(quantity = "ThermalConductance", unit = "W/K") = 5.99874055415244e-05 "Constant thermal conductance of material"; Real TC_664_665.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_664_665.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_664_665.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_664_665.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_664_665.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_664_665.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_664_665.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428584578200206 "Constant thermal conductance of material"; Real TC_664_677.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_664_677.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_664_677.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_664_677.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_664_677.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_664_677.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_664_677.G(quantity = "ThermalConductance", unit = "W/K") = 0.000120015797788313 "Constant thermal conductance of material"; Real TC_664_887.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_664_887.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_664_887.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_664_887.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_664_887.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_664_887.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_664_887.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249201630328522 "Constant thermal conductance of material"; Real TC_665_666.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_665_666.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_665_666.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_665_666.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_665_666.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_665_666.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_665_666.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999695814714 "Constant thermal conductance of material"; Real TC_665_678.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_665_678.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_665_678.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_665_678.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_665_678.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_665_678.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_665_678.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999985 "Constant thermal conductance of material"; Real TC_665_888.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_665_888.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_665_888.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_665_888.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_665_888.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_665_888.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_665_888.G(quantity = "ThermalConductance", unit = "W/K") = 0.00062300291131151 "Constant thermal conductance of material"; Real TC_666_667.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_666_667.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_666_667.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_666_667.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_666_667.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_666_667.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_666_667.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299997695162146 "Constant thermal conductance of material"; Real TC_666_679.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_666_679.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_666_679.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_666_679.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_666_679.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_666_679.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_666_679.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300010877841837 "Constant thermal conductance of material"; Real TC_666_889.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_666_889.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_666_889.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_666_889.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_666_889.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_666_889.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_666_889.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623007498787592 "Constant thermal conductance of material"; Real TC_667_668.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_667_668.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_667_668.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_667_668.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_667_668.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_667_668.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_667_668.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999997 "Constant thermal conductance of material"; Real TC_667_680.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_667_680.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_667_680.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_667_680.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_667_680.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_667_680.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_667_680.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299985141894907 "Constant thermal conductance of material"; Real TC_667_890.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_667_890.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_667_890.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_667_890.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_667_890.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_667_890.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_667_890.G(quantity = "ThermalConductance", unit = "W/K") = 0.00062300123209211 "Constant thermal conductance of material"; Real TC_668_669.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_668_669.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_668_669.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_668_669.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_668_669.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_668_669.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_668_669.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299998313858397 "Constant thermal conductance of material"; Real TC_668_681.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_668_681.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_668_681.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_668_681.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_668_681.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_668_681.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_668_681.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299995998879687 "Constant thermal conductance of material"; Real TC_668_891.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_668_891.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_668_891.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_668_891.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_668_891.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_668_891.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_668_891.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623004712569867 "Constant thermal conductance of material"; Real TC_669_670.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_669_670.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_669_670.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_669_670.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_669_670.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_669_670.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_669_670.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299997065469376 "Constant thermal conductance of material"; Real TC_669_682.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_669_682.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_669_682.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_669_682.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_669_682.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_669_682.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_669_682.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003325684264 "Constant thermal conductance of material"; Real TC_669_892.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_669_892.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_669_892.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_669_892.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_669_892.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_669_892.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_669_892.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623001839888095 "Constant thermal conductance of material"; Real TC_670_671.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_670_671.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_670_671.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_670_671.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_670_671.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_670_671.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_670_671.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000001 "Constant thermal conductance of material"; Real TC_670_683.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_670_683.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_670_683.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_670_683.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_670_683.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_670_683.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_670_683.G(quantity = "ThermalConductance", unit = "W/K") = 0.0002999979333292 "Constant thermal conductance of material"; Real TC_670_893.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_670_893.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_670_893.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_670_893.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_670_893.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_670_893.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_670_893.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623000745190407 "Constant thermal conductance of material"; Real TC_671_672.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_671_672.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_671_672.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_671_672.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_671_672.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_671_672.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_671_672.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029999765131409 "Constant thermal conductance of material"; Real TC_671_684.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_671_684.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_671_684.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_671_684.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_671_684.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_671_684.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_671_684.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999999 "Constant thermal conductance of material"; Real TC_671_894.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_671_894.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_671_894.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_671_894.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_671_894.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_671_894.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_671_894.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623008734866385 "Constant thermal conductance of material"; Real TC_672_673.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_672_673.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_672_673.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_672_673.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_672_673.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_672_673.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_672_673.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999292070481 "Constant thermal conductance of material"; Real TC_672_685.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_672_685.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_672_685.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_672_685.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_672_685.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_672_685.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_672_685.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003179144809 "Constant thermal conductance of material"; Real TC_672_895.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_672_895.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_672_895.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_672_895.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_672_895.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_672_895.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_672_895.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623005964561752 "Constant thermal conductance of material"; Real TC_673_674.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_673_674.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_673_674.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_673_674.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_673_674.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_673_674.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_673_674.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428582607043183 "Constant thermal conductance of material"; Real TC_673_686.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_673_686.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_673_686.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_673_686.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_673_686.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_673_686.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_673_686.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299990824846316 "Constant thermal conductance of material"; Real TC_673_896.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_673_896.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_673_896.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_673_896.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_673_896.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_673_896.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_673_896.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623010001682409 "Constant thermal conductance of material"; Real TC_674_675.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_674_675.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_674_675.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_674_675.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_674_675.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_674_675.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_674_675.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999982023441431 "Constant thermal conductance of material"; Real TC_674_687.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_674_687.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_674_687.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_674_687.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_674_687.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_674_687.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_674_687.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119998811539946 "Constant thermal conductance of material"; Real TC_674_897.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_674_897.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_674_897.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_674_897.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_674_897.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_674_897.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_674_897.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249201149270965 "Constant thermal conductance of material"; Real TC_675_688.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_675_688.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_675_688.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_675_688.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_675_688.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_675_688.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_675_688.G(quantity = "ThermalConductance", unit = "W/K") = 6.00013670072786e-05 "Constant thermal conductance of material"; Real TC_676_677.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_676_677.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_676_677.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_676_677.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_676_677.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_676_677.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_676_677.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100001168101485 "Constant thermal conductance of material"; Real TC_676_689.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_676_689.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_676_689.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_676_689.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_676_689.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_676_689.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_676_689.G(quantity = "ThermalConductance", unit = "W/K") = 5.99983999359965e-05 "Constant thermal conductance of material"; Real TC_677_678.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_677_678.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_677_678.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_677_678.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_677_678.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_677_678.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_677_678.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428556973735563 "Constant thermal conductance of material"; Real TC_677_690.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_677_690.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_677_690.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_677_690.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_677_690.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_677_690.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_677_690.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119999234039296 "Constant thermal conductance of material"; Real TC_677_898.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_677_898.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_677_898.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_677_898.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_677_898.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_677_898.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_677_898.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249201342349515 "Constant thermal conductance of material"; Real TC_678_679.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_678_679.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_678_679.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_678_679.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_678_679.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_678_679.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_678_679.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300001132400236 "Constant thermal conductance of material"; Real TC_678_691.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_678_691.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_678_691.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_678_691.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_678_691.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_678_691.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_678_691.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999999 "Constant thermal conductance of material"; Real TC_678_899.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_678_899.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_678_899.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_678_899.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_678_899.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_678_899.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_678_899.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622997839254092 "Constant thermal conductance of material"; Real TC_679_680.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_679_680.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_679_680.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_679_680.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_679_680.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_679_680.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_679_680.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299997787218978 "Constant thermal conductance of material"; Real TC_679_692.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_679_692.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_679_692.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_679_692.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_679_692.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_679_692.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_679_692.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300008862891073 "Constant thermal conductance of material"; Real TC_679_900.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_679_900.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_679_900.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_679_900.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_679_900.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_679_900.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_679_900.G(quantity = "ThermalConductance", unit = "W/K") = 0.00062299864992975 "Constant thermal conductance of material"; Real TC_680_681.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_680_681.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_680_681.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_680_681.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_680_681.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_680_681.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_680_681.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299996794666326 "Constant thermal conductance of material"; Real TC_680_693.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_680_693.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_680_693.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_680_693.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_680_693.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_680_693.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_680_693.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029999206475163 "Constant thermal conductance of material"; Real TC_680_901.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_680_901.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_680_901.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_680_901.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_680_901.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_680_901.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_680_901.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622997680693806 "Constant thermal conductance of material"; Real TC_681_682.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_681_682.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_681_682.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_681_682.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_681_682.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_681_682.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_681_682.G(quantity = "ThermalConductance", unit = "W/K") = 0.00030000115156959 "Constant thermal conductance of material"; Real TC_681_694.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_681_694.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_681_694.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_681_694.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_681_694.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_681_694.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_681_694.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299996087177683 "Constant thermal conductance of material"; Real TC_681_902.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_681_902.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_681_902.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_681_902.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_681_902.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_681_902.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_681_902.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623003723907808 "Constant thermal conductance of material"; Real TC_682_683.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_682_683.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_682_683.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_682_683.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_682_683.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_682_683.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_682_683.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299991478120073 "Constant thermal conductance of material"; Real TC_682_695.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_682_695.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_682_695.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_682_695.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_682_695.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_682_695.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_682_695.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299992247761542 "Constant thermal conductance of material"; Real TC_682_903.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_682_903.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_682_903.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_682_903.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_682_903.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_682_903.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_682_903.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623002871977 "Constant thermal conductance of material"; Real TC_683_684.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_683_684.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_683_684.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_683_684.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_683_684.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_683_684.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_683_684.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299999999999999 "Constant thermal conductance of material"; Real TC_683_696.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_683_696.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_683_696.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_683_696.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_683_696.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_683_696.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_683_696.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000001 "Constant thermal conductance of material"; Real TC_683_904.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_683_904.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_683_904.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_683_904.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_683_904.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_683_904.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_683_904.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623003900677885 "Constant thermal conductance of material"; Real TC_684_685.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_684_685.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_684_685.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_684_685.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_684_685.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_684_685.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_684_685.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300004220655889 "Constant thermal conductance of material"; Real TC_684_697.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_684_697.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_684_697.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_684_697.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_684_697.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_684_697.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_684_697.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300001231329961 "Constant thermal conductance of material"; Real TC_684_905.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_684_905.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_684_905.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_684_905.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_684_905.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_684_905.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_684_905.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623009730909275 "Constant thermal conductance of material"; Real TC_685_686.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_685_686.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_685_686.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_685_686.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_685_686.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_685_686.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_685_686.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299998887244484 "Constant thermal conductance of material"; Real TC_685_698.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_685_698.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_685_698.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_685_698.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_685_698.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_685_698.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_685_698.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299995961282159 "Constant thermal conductance of material"; Real TC_685_906.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_685_906.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_685_906.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_685_906.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_685_906.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_685_906.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_685_906.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623000916777019 "Constant thermal conductance of material"; Real TC_686_687.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_686_687.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_686_687.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_686_687.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_686_687.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_686_687.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_686_687.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428585856545539 "Constant thermal conductance of material"; Real TC_686_699.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_686_699.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_686_699.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_686_699.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_686_699.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_686_699.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_686_699.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000000000002 "Constant thermal conductance of material"; Real TC_686_907.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_686_907.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_686_907.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_686_907.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_686_907.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_686_907.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_686_907.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623002889233301 "Constant thermal conductance of material"; Real TC_687_688.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_687_688.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_687_688.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_687_688.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_687_688.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_687_688.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_687_688.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999995 "Constant thermal conductance of material"; Real TC_687_700.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_687_700.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_687_700.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_687_700.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_687_700.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_687_700.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_687_700.G(quantity = "ThermalConductance", unit = "W/K") = 0.000119998675730555 "Constant thermal conductance of material"; Real TC_687_908.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_687_908.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_687_908.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_687_908.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_687_908.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_687_908.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_687_908.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249202727346227 "Constant thermal conductance of material"; Real TC_688_701.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_688_701.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_688_701.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_688_701.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_688_701.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_688_701.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_688_701.G(quantity = "ThermalConductance", unit = "W/K") = 5.99982495678626e-05 "Constant thermal conductance of material"; Real TC_689_690.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_689_690.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_689_690.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_689_690.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_689_690.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_689_690.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_689_690.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999996 "Constant thermal conductance of material"; Real TC_689_702.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_689_702.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_689_702.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_689_702.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_689_702.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_689_702.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_689_702.G(quantity = "ThermalConductance", unit = "W/K") = 2.9999918875287e-05 "Constant thermal conductance of material"; Real TC_690_691.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_690_691.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_690_691.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_690_691.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_690_691.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_690_691.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_690_691.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428570171914814 "Constant thermal conductance of material"; Real TC_690_703.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_690_703.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_690_703.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_690_703.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_690_703.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_690_703.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_690_703.G(quantity = "ThermalConductance", unit = "W/K") = 6.0000297904983e-05 "Constant thermal conductance of material"; Real TC_690_909.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_690_909.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_690_909.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_690_909.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_690_909.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_690_909.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_690_909.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249199717038267 "Constant thermal conductance of material"; Real TC_691_692.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_691_692.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_691_692.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_691_692.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_691_692.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_691_692.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_691_692.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299992626999927 "Constant thermal conductance of material"; Real TC_691_704.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_691_704.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_691_704.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_691_704.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_691_704.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_691_704.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_691_704.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149998091904769 "Constant thermal conductance of material"; Real TC_691_910.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_691_910.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_691_910.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_691_910.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_691_910.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_691_910.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_691_910.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623001799213677 "Constant thermal conductance of material"; Real TC_692_693.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_692_693.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_692_693.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_692_693.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_692_693.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_692_693.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_692_693.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299995300089297 "Constant thermal conductance of material"; Real TC_692_705.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_692_705.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_692_705.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_692_705.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_692_705.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_692_705.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_692_705.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149999577084761 "Constant thermal conductance of material"; Real TC_692_911.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_692_911.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_692_911.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_692_911.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_692_911.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_692_911.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_692_911.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623004195103625 "Constant thermal conductance of material"; Real TC_693_694.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_693_694.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_693_694.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_693_694.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_693_694.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_693_694.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_693_694.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003134403209 "Constant thermal conductance of material"; Real TC_693_706.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_693_706.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_693_706.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_693_706.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_693_706.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_693_706.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_693_706.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149999101663463 "Constant thermal conductance of material"; Real TC_693_912.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_693_912.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_693_912.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_693_912.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_693_912.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_693_912.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_693_912.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622998642765829 "Constant thermal conductance of material"; Real TC_694_695.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_694_695.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_694_695.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_694_695.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_694_695.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_694_695.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_694_695.G(quantity = "ThermalConductance", unit = "W/K") = 0.0003 "Constant thermal conductance of material"; Real TC_694_707.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_694_707.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_694_707.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_694_707.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_694_707.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_694_707.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_694_707.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149999576511642 "Constant thermal conductance of material"; Real TC_694_913.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_694_913.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_694_913.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_694_913.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_694_913.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_694_913.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_694_913.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623002520971036 "Constant thermal conductance of material"; Real TC_695_696.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_695_696.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_695_696.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_695_696.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_695_696.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_695_696.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_695_696.G(quantity = "ThermalConductance", unit = "W/K") = 0.0003 "Constant thermal conductance of material"; Real TC_695_708.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_695_708.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_695_708.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_695_708.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_695_708.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_695_708.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_695_708.G(quantity = "ThermalConductance", unit = "W/K") = 0.00015000025063536 "Constant thermal conductance of material"; Real TC_695_914.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_695_914.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_695_914.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_695_914.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_695_914.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_695_914.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_695_914.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623007189261303 "Constant thermal conductance of material"; Real TC_696_697.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_696_697.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_696_697.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_696_697.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_696_697.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_696_697.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_696_697.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300002328126092 "Constant thermal conductance of material"; Real TC_696_709.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_696_709.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_696_709.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_696_709.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_696_709.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_696_709.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_696_709.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150000659256622 "Constant thermal conductance of material"; Real TC_696_915.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_696_915.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_696_915.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_696_915.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_696_915.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_696_915.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_696_915.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623008815741919 "Constant thermal conductance of material"; Real TC_697_698.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_697_698.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_697_698.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_697_698.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_697_698.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_697_698.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_697_698.G(quantity = "ThermalConductance", unit = "W/K") = 0.00029999844108064 "Constant thermal conductance of material"; Real TC_697_710.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_697_710.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_697_710.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_697_710.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_697_710.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_697_710.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_697_710.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149997809611425 "Constant thermal conductance of material"; Real TC_697_916.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_697_916.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_697_916.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_697_916.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_697_916.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_697_916.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_697_916.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623010117518002 "Constant thermal conductance of material"; Real TC_698_699.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_698_699.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_698_699.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_698_699.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_698_699.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_698_699.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_698_699.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300000650478427 "Constant thermal conductance of material"; Real TC_698_711.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_698_711.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_698_711.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_698_711.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_698_711.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_698_711.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_698_711.G(quantity = "ThermalConductance", unit = "W/K") = 0.00015 "Constant thermal conductance of material"; Real TC_698_917.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_698_917.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_698_917.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_698_917.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_698_917.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_698_917.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_698_917.G(quantity = "ThermalConductance", unit = "W/K") = 0.000622996515679443 "Constant thermal conductance of material"; Real TC_699_700.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_699_700.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_699_700.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_699_700.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_699_700.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_699_700.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_699_700.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428560330058103 "Constant thermal conductance of material"; Real TC_699_712.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_699_712.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_699_712.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_699_712.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_699_712.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_699_712.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_699_712.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150000793235289 "Constant thermal conductance of material"; Real TC_699_918.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_699_918.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_699_918.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_699_918.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_699_918.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_699_918.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_699_918.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623006510071614 "Constant thermal conductance of material"; Real TC_700_701.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_700_701.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_700_701.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_700_701.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_700_701.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_700_701.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_700_701.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_700_713.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_700_713.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_700_713.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_700_713.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_700_713.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_700_713.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_700_713.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000001e-05 "Constant thermal conductance of material"; Real TC_700_919.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_700_919.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_700_919.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_700_919.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_700_919.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_700_919.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_700_919.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249200999210183 "Constant thermal conductance of material"; Real TC_701_714.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_701_714.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_701_714.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_701_714.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_701_714.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_701_714.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_701_714.G(quantity = "ThermalConductance", unit = "W/K") = 3.0000183700837e-05 "Constant thermal conductance of material"; Real TC_702_703.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_702_703.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_702_703.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_702_703.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_702_703.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_702_703.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_702_703.G(quantity = "ThermalConductance", unit = "W/K") = 0.00300001360673806 "Constant thermal conductance of material"; Real TC_702_715.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_702_715.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_702_715.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_702_715.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_702_715.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_702_715.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_702_715.G(quantity = "ThermalConductance", unit = "W/K") = 3.00001544466288e-05 "Constant thermal conductance of material"; Real TC_703_704.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_703_704.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_703_704.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_703_704.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_703_704.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_703_704.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_703_704.G(quantity = "ThermalConductance", unit = "W/K") = 0.00128572064834197 "Constant thermal conductance of material"; Real TC_703_716.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_703_716.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_703_716.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_703_716.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_703_716.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_703_716.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_703_716.G(quantity = "ThermalConductance", unit = "W/K") = 6.00009125915816e-05 "Constant thermal conductance of material"; Real TC_703_832.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_703_832.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_703_832.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_703_832.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_703_832.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_703_832.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_703_832.G(quantity = "ThermalConductance", unit = "W/K") = 0.000747609728524884 "Constant thermal conductance of material"; Real TC_704_705.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_704_705.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_704_705.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_704_705.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_704_705.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_704_705.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_704_705.G(quantity = "ThermalConductance", unit = "W/K") = 0.000899995828938823 "Constant thermal conductance of material"; Real TC_704_717.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_704_717.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_704_717.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_704_717.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_704_717.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_704_717.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_704_717.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149998330569498 "Constant thermal conductance of material"; Real TC_704_833.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_704_833.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_704_833.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_704_833.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_704_833.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_704_833.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_704_833.G(quantity = "ThermalConductance", unit = "W/K") = 0.0018690564112716 "Constant thermal conductance of material"; Real TC_705_706.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_705_706.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_705_706.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_705_706.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_705_706.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_705_706.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_705_706.G(quantity = "ThermalConductance", unit = "W/K") = 0.000899999999999995 "Constant thermal conductance of material"; Real TC_705_718.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_705_718.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_705_718.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_705_718.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_705_718.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_705_718.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_705_718.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149998480196967 "Constant thermal conductance of material"; Real TC_705_834.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_705_834.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_705_834.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_705_834.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_705_834.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_705_834.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_705_834.G(quantity = "ThermalConductance", unit = "W/K") = 0.00186897112180562 "Constant thermal conductance of material"; Real TC_706_707.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_706_707.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_706_707.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_706_707.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_706_707.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_706_707.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_706_707.G(quantity = "ThermalConductance", unit = "W/K") = 0.000899942922374373 "Constant thermal conductance of material"; Real TC_706_719.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_706_719.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_706_719.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_706_719.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_706_719.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_706_719.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_706_719.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150001891574925 "Constant thermal conductance of material"; Real TC_706_835.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_706_835.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_706_835.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_706_835.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_706_835.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_706_835.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_706_835.G(quantity = "ThermalConductance", unit = "W/K") = 0.00186897313553329 "Constant thermal conductance of material"; Real TC_707_708.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_707_708.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_707_708.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_707_708.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_707_708.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_707_708.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_707_708.G(quantity = "ThermalConductance", unit = "W/K") = 0.000900010281719084 "Constant thermal conductance of material"; Real TC_707_720.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_707_720.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_707_720.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_707_720.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_707_720.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_707_720.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_707_720.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149998337442226 "Constant thermal conductance of material"; Real TC_707_836.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_707_836.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_707_836.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_707_836.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_707_836.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_707_836.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_707_836.G(quantity = "ThermalConductance", unit = "W/K") = 0.00186899285687573 "Constant thermal conductance of material"; Real TC_708_709.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_708_709.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_708_709.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_708_709.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_708_709.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_708_709.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_708_709.G(quantity = "ThermalConductance", unit = "W/K") = 0.00090001370927205 "Constant thermal conductance of material"; Real TC_708_721.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_708_721.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_708_721.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_708_721.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_708_721.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_708_721.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_708_721.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150001999057414 "Constant thermal conductance of material"; Real TC_708_837.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_708_837.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_708_837.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_708_837.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_708_837.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_708_837.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_708_837.G(quantity = "ThermalConductance", unit = "W/K") = 0.00186902038802351 "Constant thermal conductance of material"; Real TC_709_710.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_709_710.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_709_710.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_709_710.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_709_710.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_709_710.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_709_710.G(quantity = "ThermalConductance", unit = "W/K") = 0.00089999645754365 "Constant thermal conductance of material"; Real TC_709_722.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_709_722.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_709_722.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_709_722.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_709_722.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_709_722.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_709_722.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150003080904554 "Constant thermal conductance of material"; Real TC_709_838.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_709_838.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_709_838.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_709_838.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_709_838.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_709_838.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_709_838.G(quantity = "ThermalConductance", unit = "W/K") = 0.00186894650277696 "Constant thermal conductance of material"; Real TC_710_711.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_710_711.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_710_711.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_710_711.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_710_711.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_710_711.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_710_711.G(quantity = "ThermalConductance", unit = "W/K") = 0.000900008892841265 "Constant thermal conductance of material"; Real TC_710_723.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_710_723.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_710_723.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_710_723.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_710_723.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_710_723.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_710_723.G(quantity = "ThermalConductance", unit = "W/K") = 0.000150004638672487 "Constant thermal conductance of material"; Real TC_710_839.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_710_839.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_710_839.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_710_839.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_710_839.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_710_839.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_710_839.G(quantity = "ThermalConductance", unit = "W/K") = 0.00186904416523466 "Constant thermal conductance of material"; Real TC_711_712.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_711_712.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_711_712.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_711_712.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_711_712.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_711_712.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_711_712.G(quantity = "ThermalConductance", unit = "W/K") = 0.000899979437380189 "Constant thermal conductance of material"; Real TC_711_724.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_711_724.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_711_724.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_711_724.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_711_724.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_711_724.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_711_724.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149998377202947 "Constant thermal conductance of material"; Real TC_711_840.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_711_840.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_711_840.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_711_840.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_711_840.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_711_840.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_711_840.G(quantity = "ThermalConductance", unit = "W/K") = 0.00186907767312389 "Constant thermal conductance of material"; Real TC_712_713.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_712_713.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_712_713.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_712_713.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_712_713.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_712_713.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_712_713.G(quantity = "ThermalConductance", unit = "W/K") = 0.00128571535395683 "Constant thermal conductance of material"; Real TC_712_725.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_712_725.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_712_725.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_712_725.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_712_725.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_712_725.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_712_725.G(quantity = "ThermalConductance", unit = "W/K") = 0.000149998676482266 "Constant thermal conductance of material"; Real TC_712_841.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_712_841.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_712_841.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_712_841.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_712_841.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_712_841.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_712_841.G(quantity = "ThermalConductance", unit = "W/K") = 0.00186901091309187 "Constant thermal conductance of material"; Real TC_713_714.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_713_714.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_713_714.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_713_714.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_713_714.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_713_714.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_713_714.G(quantity = "ThermalConductance", unit = "W/K") = 0.0029999545254733 "Constant thermal conductance of material"; Real TC_713_726.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_713_726.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_713_726.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_713_726.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_713_726.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_713_726.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_713_726.G(quantity = "ThermalConductance", unit = "W/K") = 5.99992155616062e-05 "Constant thermal conductance of material"; Real TC_713_842.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_713_842.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_713_842.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_713_842.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_713_842.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_713_842.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_713_842.G(quantity = "ThermalConductance", unit = "W/K") = 0.000747625264238857 "Constant thermal conductance of material"; Real TC_714_727.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_714_727.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_714_727.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_714_727.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_714_727.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_714_727.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_714_727.G(quantity = "ThermalConductance", unit = "W/K") = 3.00005462093074e-05 "Constant thermal conductance of material"; Real TC_715_716.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_715_716.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_715_716.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_715_716.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_715_716.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_715_716.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_715_716.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_715_728.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_715_728.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_715_728.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_715_728.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_715_728.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_715_728.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_715_728.G(quantity = "ThermalConductance", unit = "W/K") = 9.99999999999994e-05 "Constant thermal conductance of material"; Real TC_716_717.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_716_717.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_716_717.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_716_717.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_716_717.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_716_717.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_716_717.G(quantity = "ThermalConductance", unit = "W/K") = 0.00042856587237794 "Constant thermal conductance of material"; Real TC_716_729.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_716_729.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_716_729.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_716_729.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_716_729.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_716_729.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_716_729.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199996711391738 "Constant thermal conductance of material"; Real TC_716_821.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_716_821.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_716_821.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_716_821.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_716_821.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_716_821.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_716_821.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249202741574632 "Constant thermal conductance of material"; Real TC_717_718.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_717_718.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_717_718.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_717_718.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_717_718.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_717_718.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_717_718.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003117401333 "Constant thermal conductance of material"; Real TC_717_730.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_717_730.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_717_730.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_717_730.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_717_730.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_717_730.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_717_730.G(quantity = "ThermalConductance", unit = "W/K") = 0.000500000000000001 "Constant thermal conductance of material"; Real TC_717_822.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_717_822.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_717_822.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_717_822.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_717_822.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_717_822.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_717_822.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623005953277313 "Constant thermal conductance of material"; Real TC_718_719.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_718_719.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_718_719.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_718_719.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_718_719.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_718_719.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_718_719.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003731482521 "Constant thermal conductance of material"; Real TC_718_731.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_718_731.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_718_731.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_718_731.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_718_731.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_718_731.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_718_731.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499999999999999 "Constant thermal conductance of material"; Real TC_718_823.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_718_823.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_718_823.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_718_823.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_718_823.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_718_823.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_718_823.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623003393564664 "Constant thermal conductance of material"; Real TC_719_720.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_719_720.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_719_720.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_719_720.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_719_720.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_719_720.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_719_720.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299972542559022 "Constant thermal conductance of material"; Real TC_719_732.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_719_732.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_719_732.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_719_732.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_719_732.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_719_732.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_719_732.G(quantity = "ThermalConductance", unit = "W/K") = 0.000500004371737591 "Constant thermal conductance of material"; Real TC_719_824.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_719_824.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_719_824.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_719_824.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_719_824.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_719_824.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_719_824.G(quantity = "ThermalConductance", unit = "W/K") = 0.00062299922027632 "Constant thermal conductance of material"; Real TC_720_721.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_720_721.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_720_721.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_720_721.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_720_721.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_720_721.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_720_721.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299967450271234 "Constant thermal conductance of material"; Real TC_720_733.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_720_733.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_720_733.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_720_733.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_720_733.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_720_733.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_720_733.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499999999999999 "Constant thermal conductance of material"; Real TC_720_825.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_720_825.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_720_825.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_720_825.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_720_825.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_720_825.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_720_825.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623005295829973 "Constant thermal conductance of material"; Real TC_721_722.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_721_722.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_721_722.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_721_722.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_721_722.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_721_722.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_721_722.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300012588116811 "Constant thermal conductance of material"; Real TC_721_734.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_721_734.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_721_734.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_721_734.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_721_734.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_721_734.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_721_734.G(quantity = "ThermalConductance", unit = "W/K") = 0.0005 "Constant thermal conductance of material"; Real TC_721_826.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_721_826.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_721_826.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_721_826.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_721_826.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_721_826.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_721_826.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623000008825112 "Constant thermal conductance of material"; Real TC_722_723.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_722_723.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_722_723.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_722_723.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_722_723.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_722_723.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_722_723.G(quantity = "ThermalConductance", unit = "W/K") = 0.000299993065668128 "Constant thermal conductance of material"; Real TC_722_735.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_722_735.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_722_735.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_722_735.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_722_735.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_722_735.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_722_735.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499995512515594 "Constant thermal conductance of material"; Real TC_722_827.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_722_827.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_722_827.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_722_827.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_722_827.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_722_827.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_722_827.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623011419307716 "Constant thermal conductance of material"; Real TC_723_724.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_723_724.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_723_724.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_723_724.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_723_724.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_723_724.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_723_724.G(quantity = "ThermalConductance", unit = "W/K") = 0.000300003465243607 "Constant thermal conductance of material"; Real TC_723_736.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_723_736.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_723_736.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_723_736.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_723_736.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_723_736.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_723_736.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499999999999999 "Constant thermal conductance of material"; Real TC_723_828.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_723_828.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_723_828.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_723_828.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_723_828.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_723_828.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_723_828.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623005181347151 "Constant thermal conductance of material"; Real TC_724_725.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_724_725.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_724_725.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_724_725.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_724_725.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_724_725.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_724_725.G(quantity = "ThermalConductance", unit = "W/K") = 0.0003 "Constant thermal conductance of material"; Real TC_724_737.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_724_737.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_724_737.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_724_737.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_724_737.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_724_737.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_724_737.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499995157525689 "Constant thermal conductance of material"; Real TC_724_829.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_724_829.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_724_829.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_724_829.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_724_829.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_724_829.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_724_829.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623009370915183 "Constant thermal conductance of material"; Real TC_725_726.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_725_726.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_725_726.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_725_726.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_725_726.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_725_726.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_725_726.G(quantity = "ThermalConductance", unit = "W/K") = 0.000428567453637362 "Constant thermal conductance of material"; Real TC_725_738.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_725_738.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_725_738.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_725_738.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_725_738.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_725_738.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_725_738.G(quantity = "ThermalConductance", unit = "W/K") = 0.000499994277539341 "Constant thermal conductance of material"; Real TC_725_830.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_725_830.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_725_830.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_725_830.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_725_830.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_725_830.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_725_830.G(quantity = "ThermalConductance", unit = "W/K") = 0.000623008019997917 "Constant thermal conductance of material"; Real TC_726_727.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_726_727.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_726_727.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_726_727.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_726_727.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_726_727.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_726_727.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000001 "Constant thermal conductance of material"; Real TC_726_739.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_726_739.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_726_739.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_726_739.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_726_739.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_726_739.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_726_739.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200006873088423 "Constant thermal conductance of material"; Real TC_726_831.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_726_831.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_726_831.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_726_831.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_726_831.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_726_831.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_726_831.G(quantity = "ThermalConductance", unit = "W/K") = 0.000249196221707359 "Constant thermal conductance of material"; Real TC_727_740.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_727_740.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_727_740.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_727_740.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_727_740.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_727_740.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_727_740.G(quantity = "ThermalConductance", unit = "W/K") = 9.99999999999998e-05 "Constant thermal conductance of material"; Real TC_728_729.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_728_729.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_728_729.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_728_729.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_728_729.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_728_729.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_728_729.G(quantity = "ThermalConductance", unit = "W/K") = 0.000199991992953798 "Constant thermal conductance of material"; Real TC_729_730.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_729_730.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_729_730.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_729_730.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_729_730.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_729_730.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_729_730.G(quantity = "ThermalConductance", unit = "W/K") = 8.5713347633848e-05 "Constant thermal conductance of material"; Real TC_730_731.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_730_731.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_730_731.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_730_731.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_730_731.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_730_731.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_730_731.G(quantity = "ThermalConductance", unit = "W/K") = 5.9999574395642e-05 "Constant thermal conductance of material"; Real TC_731_732.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_731_732.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_731_732.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_731_732.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_731_732.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_731_732.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_731_732.G(quantity = "ThermalConductance", unit = "W/K") = 5.99972547584187e-05 "Constant thermal conductance of material"; Real TC_732_733.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_732_733.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_732_733.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_732_733.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_732_733.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_732_733.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_732_733.G(quantity = "ThermalConductance", unit = "W/K") = 6.00000000000015e-05 "Constant thermal conductance of material"; Real TC_733_734.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_733_734.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_733_734.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_733_734.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_733_734.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_733_734.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_733_734.G(quantity = "ThermalConductance", unit = "W/K") = 5.99671618451964e-05 "Constant thermal conductance of material"; Real TC_734_735.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_734_735.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_734_735.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_734_735.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_734_735.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_734_735.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_734_735.G(quantity = "ThermalConductance", unit = "W/K") = 6.00033052388028e-05 "Constant thermal conductance of material"; Real TC_735_736.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_735_736.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_735_736.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_735_736.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_735_736.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_735_736.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_735_736.G(quantity = "ThermalConductance", unit = "W/K") = 5.99983085250338e-05 "Constant thermal conductance of material"; Real TC_736_737.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_736_737.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_736_737.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_736_737.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_736_737.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_736_737.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_736_737.G(quantity = "ThermalConductance", unit = "W/K") = 5.9999141151716e-05 "Constant thermal conductance of material"; Real TC_737_738.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_737_738.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_737_738.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_737_738.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_737_738.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_737_738.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_737_738.G(quantity = "ThermalConductance", unit = "W/K") = 5.99995516901281e-05 "Constant thermal conductance of material"; Real TC_738_739.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_738_739.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_738_739.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_738_739.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_738_739.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_738_739.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_738_739.G(quantity = "ThermalConductance", unit = "W/K") = 8.57126129923659e-05 "Constant thermal conductance of material"; Real TC_739_740.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_739_740.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_739_740.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_739_740.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_739_740.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_739_740.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_739_740.G(quantity = "ThermalConductance", unit = "W/K") = 0.000200008534607832 "Constant thermal conductance of material"; Real TC_741_742.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_741_742.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_741_742.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_741_742.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_741_742.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_741_742.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_741_742.G(quantity = "ThermalConductance", unit = "W/K") = 0.139991577765294 "Constant thermal conductance of material"; Real TC_741_749.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_741_749.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_741_749.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_741_749.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_741_749.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_741_749.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_741_749.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714277046295722 "Constant thermal conductance of material"; Real TC_741_813.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_741_813.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_741_813.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_741_813.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_741_813.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_741_813.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_741_813.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714338062576368 "Constant thermal conductance of material"; Real TC_741_1304.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_741_1304.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_741_1304.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_741_1304.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_741_1304.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_741_1304.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_741_1304.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181952917657602 "Constant thermal conductance of material"; Real TC_741_1465.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_741_1465.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_741_1465.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_741_1465.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_741_1465.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_741_1465.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_741_1465.G(quantity = "ThermalConductance", unit = "W/K") = 7.27807443315285e-05 "Constant thermal conductance of material"; Real TC_742_743.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_742_743.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_742_743.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_742_743.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_742_743.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_742_743.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_742_743.G(quantity = "ThermalConductance", unit = "W/K") = 0.140012558869708 "Constant thermal conductance of material"; Real TC_742_750.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_742_750.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_742_750.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_742_750.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_742_750.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_742_750.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_742_750.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714301846310207 "Constant thermal conductance of material"; Real TC_742_814.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_742_814.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_742_814.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_742_814.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_742_814.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_742_814.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_742_814.G(quantity = "ThermalConductance", unit = "W/K") = 0.071429598992985 "Constant thermal conductance of material"; Real TC_742_1305.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_742_1305.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_742_1305.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_742_1305.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_742_1305.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_742_1305.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_742_1305.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181952513485767 "Constant thermal conductance of material"; Real TC_743_744.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_743_744.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_743_744.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_743_744.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_743_744.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_743_744.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_743_744.G(quantity = "ThermalConductance", unit = "W/K") = 0.139938429964102 "Constant thermal conductance of material"; Real TC_743_751.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_743_751.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_743_751.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_743_751.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_743_751.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_743_751.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_743_751.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714271501765895 "Constant thermal conductance of material"; Real TC_743_815.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_743_815.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_743_815.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_743_815.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_743_815.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_743_815.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_743_815.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714326954800394 "Constant thermal conductance of material"; Real TC_743_1306.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_743_1306.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_743_1306.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_743_1306.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_743_1306.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_743_1306.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_743_1306.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181951985536556 "Constant thermal conductance of material"; Real TC_744_745.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_744_745.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_744_745.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_744_745.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_744_745.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_744_745.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_744_745.G(quantity = "ThermalConductance", unit = "W/K") = 0.139771428571896 "Constant thermal conductance of material"; Real TC_744_752.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_744_752.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_744_752.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_744_752.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_744_752.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_744_752.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_744_752.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714304030086738 "Constant thermal conductance of material"; Real TC_744_816.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_744_816.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_744_816.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_744_816.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_744_816.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_744_816.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_744_816.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714265578635023 "Constant thermal conductance of material"; Real TC_744_1307.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_744_1307.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_744_1307.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_744_1307.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_744_1307.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_744_1307.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_744_1307.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181954530634022 "Constant thermal conductance of material"; Real TC_745_746.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_745_746.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_745_746.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_745_746.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_745_746.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_745_746.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_745_746.G(quantity = "ThermalConductance", unit = "W/K") = 0.139954504094636 "Constant thermal conductance of material"; Real TC_745_753.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_745_753.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_745_753.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_745_753.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_745_753.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_745_753.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_745_753.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714285714285726 "Constant thermal conductance of material"; Real TC_745_817.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_745_817.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_745_817.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_745_817.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_745_817.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_745_817.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_745_817.G(quantity = "ThermalConductance", unit = "W/K") = 0.071423778851312 "Constant thermal conductance of material"; Real TC_745_1308.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_745_1308.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_745_1308.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_745_1308.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_745_1308.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_745_1308.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_745_1308.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181950699882263 "Constant thermal conductance of material"; Real TC_746_747.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_746_747.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_746_747.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_746_747.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_746_747.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_746_747.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_746_747.G(quantity = "ThermalConductance", unit = "W/K") = 0.140011700468004 "Constant thermal conductance of material"; Real TC_746_754.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_746_754.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_746_754.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_746_754.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_746_754.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_746_754.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_746_754.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714280886726154 "Constant thermal conductance of material"; Real TC_746_818.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_746_818.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_746_818.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_746_818.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_746_818.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_746_818.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_746_818.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714294596779189 "Constant thermal conductance of material"; Real TC_746_1309.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_746_1309.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_746_1309.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_746_1309.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_746_1309.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_746_1309.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_746_1309.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181950890336442 "Constant thermal conductance of material"; Real TC_747_748.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_747_748.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_747_748.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_747_748.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_747_748.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_747_748.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_747_748.G(quantity = "ThermalConductance", unit = "W/K") = 0.140004905567813 "Constant thermal conductance of material"; Real TC_747_755.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_747_755.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_747_755.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_747_755.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_747_755.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_747_755.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_747_755.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714276477434373 "Constant thermal conductance of material"; Real TC_747_819.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_747_819.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_747_819.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_747_819.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_747_819.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_747_819.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_747_819.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714302649516934 "Constant thermal conductance of material"; Real TC_747_1310.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_747_1310.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_747_1310.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_747_1310.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_747_1310.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_747_1310.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_747_1310.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181955671841562 "Constant thermal conductance of material"; Real TC_748_756.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_748_756.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_748_756.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_748_756.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_748_756.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_748_756.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_748_756.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714294851295172 "Constant thermal conductance of material"; Real TC_748_820.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_748_820.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_748_820.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_748_820.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_748_820.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_748_820.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_748_820.G(quantity = "ThermalConductance", unit = "W/K") = 0.0714269228549994 "Constant thermal conductance of material"; Real TC_748_1311.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_748_1311.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_748_1311.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_748_1311.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_748_1311.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_748_1311.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_748_1311.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181956043261687 "Constant thermal conductance of material"; Real TC_748_1414.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_748_1414.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_748_1414.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_748_1414.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_748_1414.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_748_1414.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_748_1414.G(quantity = "ThermalConductance", unit = "W/K") = 0.000181886161220816 "Constant thermal conductance of material"; Real TC_749_750.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_749_750.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_749_750.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_749_750.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_749_750.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_749_750.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_749_750.G(quantity = "ThermalConductance", unit = "W/K") = 0.139989565943245 "Constant thermal conductance of material"; Real TC_749_757.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_749_757.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_749_757.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_749_757.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_749_757.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_749_757.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_749_757.G(quantity = "ThermalConductance", unit = "W/K") = 0.0476162293680547 "Constant thermal conductance of material"; Real TC_749_1315.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_749_1315.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_749_1315.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_749_1315.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_749_1315.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_749_1315.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_749_1315.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181953080607192 "Constant thermal conductance of material"; Real TC_749_1416.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_749_1416.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_749_1416.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_749_1416.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_749_1416.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_749_1416.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_749_1416.G(quantity = "ThermalConductance", unit = "W/K") = 7.27814528593508e-05 "Constant thermal conductance of material"; Real TC_750_751.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_750_751.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_750_751.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_750_751.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_750_751.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_750_751.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_750_751.G(quantity = "ThermalConductance", unit = "W/K") = 0.14000179307871 "Constant thermal conductance of material"; Real TC_750_758.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_750_758.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_750_758.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_750_758.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_750_758.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_750_758.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_750_758.G(quantity = "ThermalConductance", unit = "W/K") = 0.0476204640095184 "Constant thermal conductance of material"; Real TC_750_1316.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_750_1316.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_750_1316.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_750_1316.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_750_1316.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_750_1316.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_750_1316.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181951088616028 "Constant thermal conductance of material"; Real TC_751_752.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_751_752.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_751_752.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_751_752.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_751_752.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_751_752.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_751_752.G(quantity = "ThermalConductance", unit = "W/K") = 0.139996186844613 "Constant thermal conductance of material"; Real TC_751_759.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_751_759.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_751_759.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_751_759.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_751_759.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_751_759.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_751_759.G(quantity = "ThermalConductance", unit = "W/K") = 0.0476198783770319 "Constant thermal conductance of material"; Real TC_751_1317.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_751_1317.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_751_1317.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_751_1317.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_751_1317.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_751_1317.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_751_1317.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181953937166159 "Constant thermal conductance of material"; Real TC_752_753.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_752_753.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_752_753.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_752_753.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_752_753.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_752_753.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_752_753.G(quantity = "ThermalConductance", unit = "W/K") = 0.14002064896757 "Constant thermal conductance of material"; Real TC_752_760.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_752_760.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_752_760.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_752_760.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_752_760.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_752_760.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_752_760.G(quantity = "ThermalConductance", unit = "W/K") = 0.0476187613952841 "Constant thermal conductance of material"; Real TC_752_1318.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_752_1318.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_752_1318.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_752_1318.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_752_1318.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_752_1318.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_752_1318.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181951657111284 "Constant thermal conductance of material"; Real TC_753_754.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_753_754.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_753_754.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_753_754.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_753_754.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_753_754.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_753_754.G(quantity = "ThermalConductance", unit = "W/K") = 0.139960758665792 "Constant thermal conductance of material"; Real TC_753_761.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_753_761.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_753_761.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_753_761.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_753_761.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_753_761.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_753_761.G(quantity = "ThermalConductance", unit = "W/K") = 0.0476181994818651 "Constant thermal conductance of material"; Real TC_753_1319.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_753_1319.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_753_1319.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_753_1319.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_753_1319.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_753_1319.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_753_1319.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181953775602991 "Constant thermal conductance of material"; Real TC_754_755.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_754_755.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_754_755.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_754_755.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_754_755.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_754_755.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_754_755.G(quantity = "ThermalConductance", unit = "W/K") = 0.139975490196096 "Constant thermal conductance of material"; Real TC_754_762.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_754_762.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_754_762.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_754_762.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_754_762.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_754_762.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_754_762.G(quantity = "ThermalConductance", unit = "W/K") = 0.0476192550010163 "Constant thermal conductance of material"; Real TC_754_1320.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_754_1320.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_754_1320.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_754_1320.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_754_1320.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_754_1320.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_754_1320.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181950909248605 "Constant thermal conductance of material"; Real TC_755_756.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_755_756.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_755_756.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_755_756.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_755_756.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_755_756.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_755_756.G(quantity = "ThermalConductance", unit = "W/K") = 0.140021396095205 "Constant thermal conductance of material"; Real TC_755_763.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_755_763.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_755_763.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_755_763.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_755_763.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_755_763.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_755_763.G(quantity = "ThermalConductance", unit = "W/K") = 0.0476187116347986 "Constant thermal conductance of material"; Real TC_755_1321.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_755_1321.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_755_1321.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_755_1321.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_755_1321.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_755_1321.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_755_1321.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181949127055732 "Constant thermal conductance of material"; Real TC_756_764.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_756_764.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_756_764.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_756_764.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_756_764.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_756_764.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_756_764.G(quantity = "ThermalConductance", unit = "W/K") = 0.0476187039976907 "Constant thermal conductance of material"; Real TC_756_1322.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_756_1322.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_756_1322.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_756_1322.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_756_1322.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_756_1322.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_756_1322.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181948967301601 "Constant thermal conductance of material"; Real TC_756_1417.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_756_1417.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_756_1417.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_756_1417.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_756_1417.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_756_1417.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_756_1417.G(quantity = "ThermalConductance", unit = "W/K") = 0.00018187986909803 "Constant thermal conductance of material"; Real TC_757_758.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_757_758.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_757_758.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_757_758.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_757_758.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_757_758.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_757_758.G(quantity = "ThermalConductance", unit = "W/K") = 0.280032508127035 "Constant thermal conductance of material"; Real TC_757_765.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_757_765.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_757_765.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_757_765.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_757_765.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_757_765.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_757_765.G(quantity = "ThermalConductance", unit = "W/K") = 0.052632189912357 "Constant thermal conductance of material"; Real TC_757_1326.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_757_1326.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_757_1326.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_757_1326.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_757_1326.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_757_1326.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_757_1326.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363906981271343 "Constant thermal conductance of material"; Real TC_757_1419.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_757_1419.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_757_1419.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_757_1419.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_757_1419.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_757_1419.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_757_1419.G(quantity = "ThermalConductance", unit = "W/K") = 0.000145567661918338 "Constant thermal conductance of material"; Real TC_758_759.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_758_759.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_758_759.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_758_759.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_758_759.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_758_759.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_758_759.G(quantity = "ThermalConductance", unit = "W/K") = 0.279993378031623 "Constant thermal conductance of material"; Real TC_758_766.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_758_766.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_758_766.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_758_766.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_758_766.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_758_766.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_758_766.G(quantity = "ThermalConductance", unit = "W/K") = 0.0526299771747399 "Constant thermal conductance of material"; Real TC_758_1327.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_758_1327.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_758_1327.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_758_1327.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_758_1327.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_758_1327.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_758_1327.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363901362356343 "Constant thermal conductance of material"; Real TC_759_760.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_759_760.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_759_760.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_759_760.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_759_760.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_759_760.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_759_760.G(quantity = "ThermalConductance", unit = "W/K") = 0.279996008515166 "Constant thermal conductance of material"; Real TC_759_767.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_759_767.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_759_767.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_759_767.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_759_767.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_759_767.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_759_767.G(quantity = "ThermalConductance", unit = "W/K") = 0.0526308612393583 "Constant thermal conductance of material"; Real TC_759_1328.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_759_1328.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_759_1328.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_759_1328.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_759_1328.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_759_1328.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_759_1328.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363902491773902 "Constant thermal conductance of material"; Real TC_760_761.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_760_761.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_760_761.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_760_761.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_760_761.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_760_761.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_760_761.G(quantity = "ThermalConductance", unit = "W/K") = 0.279998687577918 "Constant thermal conductance of material"; Real TC_760_768.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_760_768.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_760_768.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_760_768.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_760_768.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_760_768.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_760_768.G(quantity = "ThermalConductance", unit = "W/K") = 0.052631648812605 "Constant thermal conductance of material"; Real TC_760_1329.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_760_1329.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_760_1329.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_760_1329.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_760_1329.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_760_1329.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_760_1329.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363909363909363 "Constant thermal conductance of material"; Real TC_761_762.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_761_762.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_761_762.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_761_762.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_761_762.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_761_762.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_761_762.G(quantity = "ThermalConductance", unit = "W/K") = 0.280000000000015 "Constant thermal conductance of material"; Real TC_761_769.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_761_769.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_761_769.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_761_769.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_761_769.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_761_769.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_761_769.G(quantity = "ThermalConductance", unit = "W/K") = 0.0526316646051691 "Constant thermal conductance of material"; Real TC_761_1330.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_761_1330.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_761_1330.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_761_1330.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_761_1330.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_761_1330.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_761_1330.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363910132623288 "Constant thermal conductance of material"; Real TC_762_763.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_762_763.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_762_763.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_762_763.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_762_763.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_762_763.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_762_763.G(quantity = "ThermalConductance", unit = "W/K") = 0.279973509933703 "Constant thermal conductance of material"; Real TC_762_770.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_762_770.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_762_770.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_762_770.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_762_770.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_762_770.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_762_770.G(quantity = "ThermalConductance", unit = "W/K") = 0.0526312329247446 "Constant thermal conductance of material"; Real TC_762_1331.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_762_1331.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_762_1331.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_762_1331.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_762_1331.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_762_1331.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_762_1331.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363900012570259 "Constant thermal conductance of material"; Real TC_763_764.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_763_764.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_763_764.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_763_764.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_763_764.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_763_764.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_763_764.G(quantity = "ThermalConductance", unit = "W/K") = 0.280033872788864 "Constant thermal conductance of material"; Real TC_763_771.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_763_771.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_763_771.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_763_771.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_763_771.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_763_771.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_763_771.G(quantity = "ThermalConductance", unit = "W/K") = 0.0526315789473683 "Constant thermal conductance of material"; Real TC_763_1332.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_763_1332.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_763_1332.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_763_1332.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_763_1332.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_763_1332.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_763_1332.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363905130450339 "Constant thermal conductance of material"; Real TC_764_772.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_764_772.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_764_772.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_764_772.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_764_772.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_764_772.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_764_772.G(quantity = "ThermalConductance", unit = "W/K") = 0.0526317940752698 "Constant thermal conductance of material"; Real TC_764_1333.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_764_1333.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_764_1333.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_764_1333.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_764_1333.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_764_1333.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_764_1333.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363902615068567 "Constant thermal conductance of material"; Real TC_764_1420.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_764_1420.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_764_1420.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_764_1420.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_764_1420.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_764_1420.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_764_1420.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363766790036179 "Constant thermal conductance of material"; Real TC_765_766.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_765_766.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_765_766.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_765_766.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_765_766.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_765_766.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_765_766.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_765_773.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_765_773.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_765_773.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_765_773.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_765_773.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_765_773.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_765_773.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999992 "Constant thermal conductance of material"; Real TC_765_1337.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_765_1337.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_765_1337.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_765_1337.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_765_1337.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_765_1337.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_765_1337.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129964962834408 "Constant thermal conductance of material"; Real TC_765_1422.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_765_1422.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_765_1422.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_765_1422.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_765_1422.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_765_1422.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_765_1422.G(quantity = "ThermalConductance", unit = "W/K") = 5.19869706840391e-05 "Constant thermal conductance of material"; Real TC_766_767.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_766_767.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_766_767.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_766_767.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_766_767.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_766_767.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_766_767.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999996 "Constant thermal conductance of material"; Real TC_766_774.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_766_774.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_766_774.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_766_774.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_766_774.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_766_774.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_766_774.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999996 "Constant thermal conductance of material"; Real TC_766_1338.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_766_1338.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_766_1338.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_766_1338.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_766_1338.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_766_1338.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_766_1338.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129969669325474 "Constant thermal conductance of material"; Real TC_767_768.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_767_768.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_767_768.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_767_768.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_767_768.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_767_768.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_767_768.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999993 "Constant thermal conductance of material"; Real TC_767_775.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_767_775.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_767_775.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_767_775.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_767_775.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_767_775.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_767_775.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000001 "Constant thermal conductance of material"; Real TC_767_1339.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_767_1339.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_767_1339.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_767_1339.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_767_1339.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_767_1339.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_767_1339.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129970093641222 "Constant thermal conductance of material"; Real TC_768_769.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_768_769.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_768_769.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_768_769.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_768_769.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_768_769.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_768_769.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999984074911623 "Constant thermal conductance of material"; Real TC_768_776.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_768_776.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_768_776.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_768_776.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_768_776.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_768_776.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_768_776.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000002 "Constant thermal conductance of material"; Real TC_768_1340.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_768_1340.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_768_1340.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_768_1340.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_768_1340.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_768_1340.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_768_1340.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129968646577252 "Constant thermal conductance of material"; Real TC_769_770.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_769_770.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_769_770.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_769_770.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_769_770.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_769_770.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_769_770.G(quantity = "ThermalConductance", unit = "W/K") = 0.100004412867922 "Constant thermal conductance of material"; Real TC_769_777.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_769_777.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_769_777.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_769_777.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_769_777.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_769_777.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_769_777.G(quantity = "ThermalConductance", unit = "W/K") = 0.10000353769413 "Constant thermal conductance of material"; Real TC_769_1488.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_769_1488.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_769_1488.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_769_1488.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_769_1488.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_769_1488.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_769_1488.G(quantity = "ThermalConductance", unit = "W/K") = 0.0495049157508728 "Constant thermal conductance of material"; Real TC_770_771.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_770_771.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_770_771.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_770_771.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_770_771.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_770_771.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_770_771.G(quantity = "ThermalConductance", unit = "W/K") = 0.100003112356058 "Constant thermal conductance of material"; Real TC_770_778.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_770_778.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_770_778.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_770_778.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_770_778.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_770_778.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_770_778.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999992 "Constant thermal conductance of material"; Real TC_770_1489.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_770_1489.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_770_1489.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_770_1489.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_770_1489.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_770_1489.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_770_1489.G(quantity = "ThermalConductance", unit = "W/K") = 0.049505118809263 "Constant thermal conductance of material"; Real TC_771_772.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_771_772.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_771_772.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_771_772.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_771_772.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_771_772.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_771_772.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_771_779.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_771_779.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_771_779.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_771_779.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_771_779.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_771_779.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_771_779.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_771_1490.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_771_1490.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_771_1490.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_771_1490.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_771_1490.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_771_1490.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_771_1490.G(quantity = "ThermalConductance", unit = "W/K") = 0.0495051216389245 "Constant thermal conductance of material"; Real TC_772_780.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_772_780.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_772_780.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_772_780.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_772_780.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_772_780.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_772_780.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999999 "Constant thermal conductance of material"; Real TC_772_1341.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_772_1341.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_772_1341.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_772_1341.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_772_1341.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_772_1341.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_772_1341.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129965917294876 "Constant thermal conductance of material"; Real TC_772_1423.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_772_1423.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_772_1423.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_772_1423.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_772_1423.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_772_1423.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_772_1423.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129920523423104 "Constant thermal conductance of material"; Real TC_773_774.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_773_774.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_773_774.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_773_774.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_773_774.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_773_774.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_773_774.G(quantity = "ThermalConductance", unit = "W/K") = 0.10000714081691 "Constant thermal conductance of material"; Real TC_773_781.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_773_781.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_773_781.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_773_781.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_773_781.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_773_781.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_773_781.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999977 "Constant thermal conductance of material"; Real TC_773_1345.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_773_1345.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_773_1345.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_773_1345.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_773_1345.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_773_1345.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_773_1345.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129966693249519 "Constant thermal conductance of material"; Real TC_773_1425.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_773_1425.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_773_1425.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_773_1425.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_773_1425.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_773_1425.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_773_1425.G(quantity = "ThermalConductance", unit = "W/K") = 5.19862717764354e-05 "Constant thermal conductance of material"; Real TC_774_775.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_774_775.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_774_775.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_774_775.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_774_775.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_774_775.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_774_775.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_774_782.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_774_782.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_774_782.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_774_782.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_774_782.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_774_782.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_774_782.G(quantity = "ThermalConductance", unit = "W/K") = 0.100004317789289 "Constant thermal conductance of material"; Real TC_774_1346.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_774_1346.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_774_1346.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_774_1346.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_774_1346.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_774_1346.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_774_1346.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129962790767319 "Constant thermal conductance of material"; Real TC_775_776.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_775_776.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_775_776.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_775_776.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_775_776.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_775_776.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_775_776.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999998 "Constant thermal conductance of material"; Real TC_775_783.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_775_783.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_775_783.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_775_783.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_775_783.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_775_783.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_775_783.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999971921943003 "Constant thermal conductance of material"; Real TC_775_1347.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_775_1347.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_775_1347.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_775_1347.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_775_1347.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_775_1347.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_775_1347.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129968739586474 "Constant thermal conductance of material"; Real TC_776_777.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_776_777.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_776_777.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_776_777.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_776_777.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_776_777.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_776_777.G(quantity = "ThermalConductance", unit = "W/K") = 0.100001450094981 "Constant thermal conductance of material"; Real TC_776_784.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_776_784.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_776_784.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_776_784.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_776_784.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_776_784.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_776_784.G(quantity = "ThermalConductance", unit = "W/K") = 0.100015692428412 "Constant thermal conductance of material"; Real TC_776_1348.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_776_1348.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_776_1348.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_776_1348.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_776_1348.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_776_1348.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_776_1348.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012996737904857 "Constant thermal conductance of material"; Real TC_777_778.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_777_778.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_777_778.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_777_778.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_777_778.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_777_778.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_777_778.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_777_785.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_777_785.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_777_785.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_777_785.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_777_785.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_777_785.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_777_785.G(quantity = "ThermalConductance", unit = "W/K") = 0.100010945709272 "Constant thermal conductance of material"; Real TC_777_1491.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_777_1491.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_777_1491.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_777_1491.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_777_1491.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_777_1491.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_777_1491.G(quantity = "ThermalConductance", unit = "W/K") = 0.0495045118567398 "Constant thermal conductance of material"; Real TC_778_779.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_778_779.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_778_779.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_778_779.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_778_779.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_778_779.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_778_779.G(quantity = "ThermalConductance", unit = "W/K") = 0.100006945409085 "Constant thermal conductance of material"; Real TC_778_786.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_778_786.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_778_786.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_778_786.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_778_786.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_778_786.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_778_786.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999944001119985 "Constant thermal conductance of material"; Real TC_778_1492.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_778_1492.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_778_1492.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_778_1492.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_778_1492.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_778_1492.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_778_1492.G(quantity = "ThermalConductance", unit = "W/K") = 0.0495046061824643 "Constant thermal conductance of material"; Real TC_779_780.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_779_780.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_779_780.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_779_780.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_779_780.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_779_780.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_779_780.G(quantity = "ThermalConductance", unit = "W/K") = 0.099997508222865 "Constant thermal conductance of material"; Real TC_779_787.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_779_787.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_779_787.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_779_787.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_779_787.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_779_787.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_779_787.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999981893898214 "Constant thermal conductance of material"; Real TC_779_1493.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_779_1493.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_779_1493.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_779_1493.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_779_1493.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_779_1493.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_779_1493.G(quantity = "ThermalConductance", unit = "W/K") = 0.0495048289673439 "Constant thermal conductance of material"; Real TC_780_788.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_780_788.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_780_788.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_780_788.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_780_788.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_780_788.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_780_788.G(quantity = "ThermalConductance", unit = "W/K") = 0.100115720523925 "Constant thermal conductance of material"; Real TC_780_1349.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_780_1349.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_780_1349.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_780_1349.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_780_1349.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_780_1349.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_780_1349.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012996674467299 "Constant thermal conductance of material"; Real TC_780_1426.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_780_1426.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_780_1426.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_780_1426.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_780_1426.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_780_1426.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_780_1426.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129919740396808 "Constant thermal conductance of material"; Real TC_781_782.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_781_782.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_781_782.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_781_782.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_781_782.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_781_782.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_781_782.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_781_789.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_781_789.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_781_789.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_781_789.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_781_789.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_781_789.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_781_789.G(quantity = "ThermalConductance", unit = "W/K") = 0.100006595218474 "Constant thermal conductance of material"; Real TC_781_1353.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_781_1353.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_781_1353.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_781_1353.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_781_1353.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_781_1353.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_781_1353.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129964397096569 "Constant thermal conductance of material"; Real TC_781_1428.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_781_1428.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_781_1428.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_781_1428.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_781_1428.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_781_1428.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_781_1428.G(quantity = "ThermalConductance", unit = "W/K") = 5.19867713231264e-05 "Constant thermal conductance of material"; Real TC_782_783.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_782_783.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_782_783.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_782_783.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_782_783.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_782_783.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_782_783.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999958604131325 "Constant thermal conductance of material"; Real TC_782_790.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_782_790.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_782_790.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_782_790.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_782_790.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_782_790.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_782_790.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000001 "Constant thermal conductance of material"; Real TC_782_1354.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_782_1354.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_782_1354.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_782_1354.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_782_1354.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_782_1354.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_782_1354.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129963588215823 "Constant thermal conductance of material"; Real TC_783_784.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_783_784.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_783_784.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_783_784.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_783_784.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_783_784.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_783_784.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_783_791.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_783_791.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_783_791.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_783_791.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_783_791.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_783_791.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_783_791.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999661246612775 "Constant thermal conductance of material"; Real TC_783_1355.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_783_1355.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_783_1355.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_783_1355.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_783_1355.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_783_1355.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_783_1355.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129963413512232 "Constant thermal conductance of material"; Real TC_784_785.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_784_785.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_784_785.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_784_785.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_784_785.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_784_785.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_784_785.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_784_792.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_784_792.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_784_792.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_784_792.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_784_792.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_784_792.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_784_792.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000004 "Constant thermal conductance of material"; Real TC_784_1356.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_784_1356.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_784_1356.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_784_1356.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_784_1356.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_784_1356.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_784_1356.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012997022529795 "Constant thermal conductance of material"; Real TC_785_786.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_785_786.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_785_786.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_785_786.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_785_786.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_785_786.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_785_786.G(quantity = "ThermalConductance", unit = "W/K") = 0.100004448200701 "Constant thermal conductance of material"; Real TC_785_793.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_785_793.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_785_793.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_785_793.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_785_793.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_785_793.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_785_793.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000001 "Constant thermal conductance of material"; Real TC_785_1494.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_785_1494.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_785_1494.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_785_1494.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_785_1494.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_785_1494.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_785_1494.G(quantity = "ThermalConductance", unit = "W/K") = 0.0495047469848729 "Constant thermal conductance of material"; Real TC_786_787.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_786_787.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_786_787.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_786_787.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_786_787.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_786_787.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_786_787.G(quantity = "ThermalConductance", unit = "W/K") = 0.10001433948736 "Constant thermal conductance of material"; Real TC_786_794.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_786_794.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_786_794.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_786_794.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_786_794.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_786_794.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_786_794.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_786_1495.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_786_1495.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_786_1495.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_786_1495.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_786_1495.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_786_1495.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_786_1495.G(quantity = "ThermalConductance", unit = "W/K") = 0.0495049924870342 "Constant thermal conductance of material"; Real TC_787_788.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_787_788.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_787_788.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_787_788.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_787_788.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_787_788.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_787_788.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999997 "Constant thermal conductance of material"; Real TC_787_795.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_787_795.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_787_795.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_787_795.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_787_795.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_787_795.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_787_795.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999996 "Constant thermal conductance of material"; Real TC_787_1496.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_787_1496.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_787_1496.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_787_1496.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_787_1496.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_787_1496.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_787_1496.G(quantity = "ThermalConductance", unit = "W/K") = 0.04950549140026 "Constant thermal conductance of material"; Real TC_788_796.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_788_796.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_788_796.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_788_796.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_788_796.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_788_796.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_788_796.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000001 "Constant thermal conductance of material"; Real TC_788_1357.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_788_1357.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_788_1357.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_788_1357.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_788_1357.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_788_1357.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_788_1357.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129968503937008 "Constant thermal conductance of material"; Real TC_788_1429.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_788_1429.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_788_1429.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_788_1429.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_788_1429.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_788_1429.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_788_1429.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129915287628054 "Constant thermal conductance of material"; Real TC_789_790.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_789_790.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_789_790.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_789_790.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_789_790.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_789_790.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_789_790.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999967 "Constant thermal conductance of material"; Real TC_789_797.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_789_797.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_789_797.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_789_797.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_789_797.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_789_797.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_789_797.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999452887538057 "Constant thermal conductance of material"; Real TC_789_1361.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_789_1361.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_789_1361.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_789_1361.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_789_1361.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_789_1361.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_789_1361.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129964747356051 "Constant thermal conductance of material"; Real TC_789_1431.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_789_1431.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_789_1431.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_789_1431.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_789_1431.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_789_1431.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_789_1431.G(quantity = "ThermalConductance", unit = "W/K") = 5.19863427734492e-05 "Constant thermal conductance of material"; Real TC_790_791.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_790_791.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_790_791.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_790_791.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_790_791.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_790_791.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_790_791.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999995 "Constant thermal conductance of material"; Real TC_790_798.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_790_798.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_790_798.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_790_798.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_790_798.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_790_798.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_790_798.G(quantity = "ThermalConductance", unit = "W/K") = 0.100290322580419 "Constant thermal conductance of material"; Real TC_790_1362.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_790_1362.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_790_1362.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_790_1362.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_790_1362.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_790_1362.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_790_1362.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129964838029878 "Constant thermal conductance of material"; Real TC_791_792.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_791_792.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_791_792.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_791_792.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_791_792.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_791_792.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_791_792.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_791_799.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_791_799.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_791_799.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_791_799.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_791_799.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_791_799.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_791_799.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999937539038013 "Constant thermal conductance of material"; Real TC_791_1363.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_791_1363.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_791_1363.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_791_1363.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_791_1363.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_791_1363.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_791_1363.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129964533442139 "Constant thermal conductance of material"; Real TC_792_793.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_792_793.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_792_793.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_792_793.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_792_793.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_792_793.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_792_793.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000001 "Constant thermal conductance of material"; Real TC_792_800.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_792_800.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_792_800.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_792_800.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_792_800.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_792_800.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_792_800.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999982 "Constant thermal conductance of material"; Real TC_792_1364.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_792_1364.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_792_1364.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_792_1364.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_792_1364.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_792_1364.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_792_1364.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129968952192333 "Constant thermal conductance of material"; Real TC_793_794.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_793_794.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_793_794.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_793_794.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_793_794.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_793_794.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_793_794.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999986 "Constant thermal conductance of material"; Real TC_793_801.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_793_801.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_793_801.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_793_801.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_793_801.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_793_801.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_793_801.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999999 "Constant thermal conductance of material"; Real TC_793_1365.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_793_1365.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_793_1365.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_793_1365.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_793_1365.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_793_1365.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_793_1365.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129964583315381 "Constant thermal conductance of material"; Real TC_794_795.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_794_795.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_794_795.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_794_795.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_794_795.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_794_795.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_794_795.G(quantity = "ThermalConductance", unit = "W/K") = 0.099889175257855 "Constant thermal conductance of material"; Real TC_794_802.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_794_802.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_794_802.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_794_802.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_794_802.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_794_802.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_794_802.G(quantity = "ThermalConductance", unit = "W/K") = 0.100003290231303 "Constant thermal conductance of material"; Real TC_794_1366.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_794_1366.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_794_1366.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_794_1366.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_794_1366.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_794_1366.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_794_1366.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129965003537894 "Constant thermal conductance of material"; Real TC_795_796.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_795_796.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_795_796.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_795_796.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_795_796.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_795_796.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_795_796.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000003 "Constant thermal conductance of material"; Real TC_795_803.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_795_803.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_795_803.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_795_803.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_795_803.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_795_803.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_795_803.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000001 "Constant thermal conductance of material"; Real TC_795_1367.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_795_1367.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_795_1367.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_795_1367.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_795_1367.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_795_1367.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_795_1367.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129972017825681 "Constant thermal conductance of material"; Real TC_796_804.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_796_804.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_796_804.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_796_804.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_796_804.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_796_804.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_796_804.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999998 "Constant thermal conductance of material"; Real TC_796_1368.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_796_1368.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_796_1368.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_796_1368.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_796_1368.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_796_1368.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_796_1368.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129967099250594 "Constant thermal conductance of material"; Real TC_796_1432.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_796_1432.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_796_1432.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_796_1432.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_796_1432.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_796_1432.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_796_1432.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129916005576476 "Constant thermal conductance of material"; Real TC_797_798.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_797_798.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_797_798.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_797_798.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_797_798.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_797_798.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_797_798.G(quantity = "ThermalConductance", unit = "W/K") = 0.10000323485012 "Constant thermal conductance of material"; Real TC_797_805.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_797_805.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_797_805.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_797_805.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_797_805.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_797_805.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_797_805.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999828693790731 "Constant thermal conductance of material"; Real TC_797_1372.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_797_1372.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_797_1372.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_797_1372.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_797_1372.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_797_1372.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_797_1372.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129966094039095 "Constant thermal conductance of material"; Real TC_797_1434.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_797_1434.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_797_1434.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_797_1434.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_797_1434.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_797_1434.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_797_1434.G(quantity = "ThermalConductance", unit = "W/K") = 5.19859723027696e-05 "Constant thermal conductance of material"; Real TC_798_799.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_798_799.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_798_799.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_798_799.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_798_799.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_798_799.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_798_799.G(quantity = "ThermalConductance", unit = "W/K") = 0.100007088176919 "Constant thermal conductance of material"; Real TC_798_806.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_798_806.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_798_806.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_798_806.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_798_806.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_798_806.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_798_806.G(quantity = "ThermalConductance", unit = "W/K") = 0.099989733059577 "Constant thermal conductance of material"; Real TC_798_1373.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_798_1373.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_798_1373.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_798_1373.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_798_1373.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_798_1373.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_798_1373.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129965046977884 "Constant thermal conductance of material"; Real TC_799_800.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_799_800.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_799_800.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_799_800.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_799_800.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_799_800.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_799_800.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999991 "Constant thermal conductance of material"; Real TC_799_807.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_799_807.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_799_807.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_799_807.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_799_807.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_799_807.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_799_807.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_799_1374.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_799_1374.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_799_1374.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_799_1374.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_799_1374.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_799_1374.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_799_1374.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129967547038476 "Constant thermal conductance of material"; Real TC_800_801.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_800_801.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_800_801.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_800_801.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_800_801.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_800_801.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_800_801.G(quantity = "ThermalConductance", unit = "W/K") = 0.1 "Constant thermal conductance of material"; Real TC_800_808.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_800_808.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_800_808.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_800_808.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_800_808.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_800_808.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_800_808.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999926362297507 "Constant thermal conductance of material"; Real TC_800_1375.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_800_1375.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_800_1375.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_800_1375.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_800_1375.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_800_1375.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_800_1375.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012996344662913 "Constant thermal conductance of material"; Real TC_801_802.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_801_802.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_801_802.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_801_802.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_801_802.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_801_802.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_801_802.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999911684182624 "Constant thermal conductance of material"; Real TC_801_809.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_801_809.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_801_809.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_801_809.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_801_809.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_801_809.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_801_809.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000001 "Constant thermal conductance of material"; Real TC_801_1376.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_801_1376.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_801_1376.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_801_1376.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_801_1376.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_801_1376.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_801_1376.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129969749351772 "Constant thermal conductance of material"; Real TC_802_803.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_802_803.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_802_803.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_802_803.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_802_803.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_802_803.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_802_803.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000002 "Constant thermal conductance of material"; Real TC_802_810.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_802_810.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_802_810.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_802_810.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_802_810.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_802_810.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_802_810.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999933506217158 "Constant thermal conductance of material"; Real TC_802_1377.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_802_1377.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_802_1377.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_802_1377.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_802_1377.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_802_1377.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_802_1377.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129963824924935 "Constant thermal conductance of material"; Real TC_803_804.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_803_804.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_803_804.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_803_804.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_803_804.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_803_804.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_803_804.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999976985040276 "Constant thermal conductance of material"; Real TC_803_811.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_803_811.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_803_811.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_803_811.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_803_811.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_803_811.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_803_811.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999992 "Constant thermal conductance of material"; Real TC_803_1378.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_803_1378.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_803_1378.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_803_1378.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_803_1378.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_803_1378.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_803_1378.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129966063348416 "Constant thermal conductance of material"; Real TC_804_812.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_804_812.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_804_812.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_804_812.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_804_812.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_804_812.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_804_812.G(quantity = "ThermalConductance", unit = "W/K") = 0.099992295246167 "Constant thermal conductance of material"; Real TC_804_1379.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_804_1379.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_804_1379.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_804_1379.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_804_1379.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_804_1379.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_804_1379.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129966230808497 "Constant thermal conductance of material"; Real TC_804_1435.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_804_1435.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_804_1435.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_804_1435.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_804_1435.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_804_1435.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_804_1435.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129912812445101 "Constant thermal conductance of material"; Real TC_805_806.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_805_806.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_805_806.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_805_806.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_805_806.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_805_806.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_805_806.G(quantity = "ThermalConductance", unit = "W/K") = 0.100004842615013 "Constant thermal conductance of material"; Real TC_805_1383.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_805_1383.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_805_1383.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_805_1383.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_805_1383.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_805_1383.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_805_1383.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129966455917434 "Constant thermal conductance of material"; Real TC_805_1437.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_805_1437.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_805_1437.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_805_1437.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_805_1437.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_805_1437.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_805_1437.G(quantity = "ThermalConductance", unit = "W/K") = 5.19868809886272e-05 "Constant thermal conductance of material"; Real TC_805_1441.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_805_1441.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_805_1441.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_805_1441.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_805_1441.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_805_1441.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_805_1441.G(quantity = "ThermalConductance", unit = "W/K") = 1.7331970084052e-05 "Constant thermal conductance of material"; Real TC_806_807.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_806_807.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_806_807.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_806_807.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_806_807.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_806_807.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_806_807.G(quantity = "ThermalConductance", unit = "W/K") = 0.100000000000003 "Constant thermal conductance of material"; Real TC_806_1384.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_806_1384.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_806_1384.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_806_1384.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_806_1384.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_806_1384.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_806_1384.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129965927323643 "Constant thermal conductance of material"; Real TC_806_1442.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_806_1442.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_806_1442.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_806_1442.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_806_1442.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_806_1442.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_806_1442.G(quantity = "ThermalConductance", unit = "W/K") = 1.73316131544996e-05 "Constant thermal conductance of material"; Real TC_807_808.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_807_808.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_807_808.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_807_808.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_807_808.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_807_808.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_807_808.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999981 "Constant thermal conductance of material"; Real TC_807_1385.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_807_1385.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_807_1385.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_807_1385.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_807_1385.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_807_1385.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_807_1385.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129967720943183 "Constant thermal conductance of material"; Real TC_807_1443.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_807_1443.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_807_1443.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_807_1443.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_807_1443.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_807_1443.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_807_1443.G(quantity = "ThermalConductance", unit = "W/K") = 1.73321564815238e-05 "Constant thermal conductance of material"; Real TC_808_809.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_808_809.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_808_809.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_808_809.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_808_809.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_808_809.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_808_809.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999999999999999 "Constant thermal conductance of material"; Real TC_808_1386.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_808_1386.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_808_1386.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_808_1386.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_808_1386.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_808_1386.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_808_1386.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129968823070928 "Constant thermal conductance of material"; Real TC_808_1444.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_808_1444.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_808_1444.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_808_1444.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_808_1444.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_808_1444.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_808_1444.G(quantity = "ThermalConductance", unit = "W/K") = 1.73320180085229e-05 "Constant thermal conductance of material"; Real TC_809_810.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_809_810.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_809_810.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_809_810.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_809_810.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_809_810.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_809_810.G(quantity = "ThermalConductance", unit = "W/K") = 0.100002207749201 "Constant thermal conductance of material"; Real TC_809_1387.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_809_1387.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_809_1387.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_809_1387.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_809_1387.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_809_1387.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_809_1387.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129963862373341 "Constant thermal conductance of material"; Real TC_809_1445.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_809_1445.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_809_1445.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_809_1445.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_809_1445.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_809_1445.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_809_1445.G(quantity = "ThermalConductance", unit = "W/K") = 1.73321667338112e-05 "Constant thermal conductance of material"; Real TC_810_811.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_810_811.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_810_811.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_810_811.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_810_811.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_810_811.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_810_811.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999616991643459 "Constant thermal conductance of material"; Real TC_810_1388.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_810_1388.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_810_1388.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_810_1388.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_810_1388.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_810_1388.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_810_1388.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129962159494206 "Constant thermal conductance of material"; Real TC_810_1446.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_810_1446.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_810_1446.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_810_1446.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_810_1446.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_810_1446.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_810_1446.G(quantity = "ThermalConductance", unit = "W/K") = 1.7331613783621e-05 "Constant thermal conductance of material"; Real TC_811_812.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_811_812.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_811_812.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_811_812.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_811_812.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_811_812.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_811_812.G(quantity = "ThermalConductance", unit = "W/K") = 0.0999735849056655 "Constant thermal conductance of material"; Real TC_811_1389.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_811_1389.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_811_1389.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_811_1389.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_811_1389.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_811_1389.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_811_1389.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129967465481669 "Constant thermal conductance of material"; Real TC_811_1447.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_811_1447.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_811_1447.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_811_1447.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_811_1447.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_811_1447.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_811_1447.G(quantity = "ThermalConductance", unit = "W/K") = 1.73314931994875e-05 "Constant thermal conductance of material"; Real TC_812_1390.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_812_1390.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_812_1390.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_812_1390.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_812_1390.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_812_1390.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_812_1390.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129965307892454 "Constant thermal conductance of material"; Real TC_812_1438.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_812_1438.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_812_1438.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_812_1438.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_812_1438.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_812_1438.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_812_1438.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129915638467663 "Constant thermal conductance of material"; Real TC_812_1448.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_812_1448.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_812_1448.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_812_1448.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_812_1448.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_812_1448.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_812_1448.G(quantity = "ThermalConductance", unit = "W/K") = 1.73321772729389e-05 "Constant thermal conductance of material"; Real TC_813_814.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_813_814.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_813_814.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_813_814.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_813_814.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_813_814.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_813_814.G(quantity = "ThermalConductance", unit = "W/K") = 0.140019461563437 "Constant thermal conductance of material"; Real TC_813_1293.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_813_1293.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_813_1293.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_813_1293.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_813_1293.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_813_1293.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_813_1293.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181953724487133 "Constant thermal conductance of material"; Real TC_813_1462.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_813_1462.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_813_1462.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_813_1462.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_813_1462.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_813_1462.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_813_1462.G(quantity = "ThermalConductance", unit = "W/K") = 7.27810448133299e-05 "Constant thermal conductance of material"; Real TC_813_1468.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_813_1468.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_813_1468.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_813_1468.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_813_1468.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_813_1468.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_813_1468.G(quantity = "ThermalConductance", unit = "W/K") = 2.59953548295238e-05 "Constant thermal conductance of material"; Real TC_814_815.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_814_815.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_814_815.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_814_815.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_814_815.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_814_815.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_814_815.G(quantity = "ThermalConductance", unit = "W/K") = 0.139986257443876 "Constant thermal conductance of material"; Real TC_814_1294.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_814_1294.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_814_1294.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_814_1294.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_814_1294.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_814_1294.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_814_1294.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181951835733722 "Constant thermal conductance of material"; Real TC_814_1469.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_814_1469.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_814_1469.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_814_1469.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_814_1469.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_814_1469.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_814_1469.G(quantity = "ThermalConductance", unit = "W/K") = 2.59956878544032e-05 "Constant thermal conductance of material"; Real TC_815_816.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_815_816.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_815_816.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_815_816.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_815_816.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_815_816.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_815_816.G(quantity = "ThermalConductance", unit = "W/K") = 0.140043844856677 "Constant thermal conductance of material"; Real TC_815_1295.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_815_1295.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_815_1295.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_815_1295.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_815_1295.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_815_1295.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_815_1295.G(quantity = "ThermalConductance", unit = "W/K") = 0.0018195407148454 "Constant thermal conductance of material"; Real TC_815_1470.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_815_1470.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_815_1470.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_815_1470.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_815_1470.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_815_1470.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_815_1470.G(quantity = "ThermalConductance", unit = "W/K") = 2.59953770832978e-05 "Constant thermal conductance of material"; Real TC_816_817.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_816_817.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_816_817.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_816_817.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_816_817.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_816_817.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_816_817.G(quantity = "ThermalConductance", unit = "W/K") = 0.139974984365209 "Constant thermal conductance of material"; Real TC_816_1296.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_816_1296.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_816_1296.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_816_1296.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_816_1296.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_816_1296.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_816_1296.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181953350346471 "Constant thermal conductance of material"; Real TC_816_1471.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_816_1471.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_816_1471.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_816_1471.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_816_1471.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_816_1471.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_816_1471.G(quantity = "ThermalConductance", unit = "W/K") = 2.59955905377627e-05 "Constant thermal conductance of material"; Real TC_817_818.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_817_818.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_817_818.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_817_818.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_817_818.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_817_818.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_817_818.G(quantity = "ThermalConductance", unit = "W/K") = 0.140008779631272 "Constant thermal conductance of material"; Real TC_817_1297.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_817_1297.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_817_1297.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_817_1297.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_817_1297.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_817_1297.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_817_1297.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181952808119991 "Constant thermal conductance of material"; Real TC_817_1472.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_817_1472.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_817_1472.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_817_1472.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_817_1472.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_817_1472.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_817_1472.G(quantity = "ThermalConductance", unit = "W/K") = 2.59953030818652e-05 "Constant thermal conductance of material"; Real TC_818_819.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_818_819.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_818_819.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_818_819.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_818_819.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_818_819.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_818_819.G(quantity = "ThermalConductance", unit = "W/K") = 0.140014916467798 "Constant thermal conductance of material"; Real TC_818_1298.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_818_1298.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_818_1298.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_818_1298.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_818_1298.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_818_1298.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_818_1298.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181952277657266 "Constant thermal conductance of material"; Real TC_818_1473.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_818_1473.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_818_1473.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_818_1473.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_818_1473.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_818_1473.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_818_1473.G(quantity = "ThermalConductance", unit = "W/K") = 2.59957568909207e-05 "Constant thermal conductance of material"; Real TC_819_820.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_819_820.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_819_820.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_819_820.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_819_820.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_819_820.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_819_820.G(quantity = "ThermalConductance", unit = "W/K") = 0.139982367202981 "Constant thermal conductance of material"; Real TC_819_1299.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_819_1299.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_819_1299.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_819_1299.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_819_1299.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_819_1299.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_819_1299.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181955269131256 "Constant thermal conductance of material"; Real TC_819_1474.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_819_1474.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_819_1474.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_819_1474.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_819_1474.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_819_1474.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_819_1474.G(quantity = "ThermalConductance", unit = "W/K") = 2.59956052370103e-05 "Constant thermal conductance of material"; Real TC_820_1300.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_820_1300.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_820_1300.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_820_1300.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_820_1300.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_820_1300.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_820_1300.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181949095397556 "Constant thermal conductance of material"; Real TC_820_1463.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_820_1463.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_820_1463.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_820_1463.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_820_1463.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_820_1463.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_820_1463.G(quantity = "ThermalConductance", unit = "W/K") = 0.000181878832978369 "Constant thermal conductance of material"; Real TC_820_1475.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_820_1475.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_820_1475.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_820_1475.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_820_1475.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_820_1475.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_820_1475.G(quantity = "ThermalConductance", unit = "W/K") = 2.59953698554663e-05 "Constant thermal conductance of material"; Real TC_821_822.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_821_822.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_821_822.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_821_822.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_821_822.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_821_822.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_821_822.G(quantity = "ThermalConductance", unit = "W/K") = 7.42879448662035e-05 "Constant thermal conductance of material"; Real TC_821_832.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_821_832.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_821_832.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_821_832.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_821_832.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_821_832.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_821_832.G(quantity = "ThermalConductance", unit = "W/K") = 1.04000265287573e-05 "Constant thermal conductance of material"; Real TC_821_1017.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_821_1017.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_821_1017.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_821_1017.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_821_1017.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_821_1017.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_821_1017.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173331986123741 "Constant thermal conductance of material"; Real TC_822_823.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_822_823.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_822_823.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_822_823.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_822_823.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_822_823.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_822_823.G(quantity = "ThermalConductance", unit = "W/K") = 5.20003112315693e-05 "Constant thermal conductance of material"; Real TC_822_833.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_822_833.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_822_833.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_822_833.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_822_833.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_822_833.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_822_833.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998087615429e-05 "Constant thermal conductance of material"; Real TC_822_1018.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_822_1018.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_822_1018.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_822_1018.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_822_1018.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_822_1018.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_822_1018.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433331804070897 "Constant thermal conductance of material"; Real TC_823_824.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_823_824.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_823_824.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_823_824.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_823_824.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_823_824.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_823_824.G(quantity = "ThermalConductance", unit = "W/K") = 5.19981674654643e-05 "Constant thermal conductance of material"; Real TC_823_834.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_823_834.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_823_834.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_823_834.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_823_834.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_823_834.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_823_834.G(quantity = "ThermalConductance", unit = "W/K") = 2.5999849846676e-05 "Constant thermal conductance of material"; Real TC_823_1019.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_823_1019.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_823_1019.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_823_1019.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_823_1019.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_823_1019.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_823_1019.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433331207076184 "Constant thermal conductance of material"; Real TC_824_825.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_824_825.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_824_825.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_824_825.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_824_825.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_824_825.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_824_825.G(quantity = "ThermalConductance", unit = "W/K") = 5.20005560962033e-05 "Constant thermal conductance of material"; Real TC_824_835.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_824_835.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_824_835.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_824_835.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_824_835.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_824_835.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_824_835.G(quantity = "ThermalConductance", unit = "W/K") = 2.59996842378182e-05 "Constant thermal conductance of material"; Real TC_824_1020.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_824_1020.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_824_1020.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_824_1020.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_824_1020.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_824_1020.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_824_1020.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433330028749875 "Constant thermal conductance of material"; Real TC_825_826.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_825_826.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_825_826.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_825_826.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_825_826.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_825_826.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_825_826.G(quantity = "ThermalConductance", unit = "W/K") = 5.20005707762578e-05 "Constant thermal conductance of material"; Real TC_825_836.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_825_836.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_825_836.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_825_836.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_825_836.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_825_836.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_825_836.G(quantity = "ThermalConductance", unit = "W/K") = 2.6000175213176e-05 "Constant thermal conductance of material"; Real TC_825_1021.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_825_1021.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_825_1021.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_825_1021.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_825_1021.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_825_1021.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_825_1021.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433332621797198 "Constant thermal conductance of material"; Real TC_826_827.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_826_827.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_826_827.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_826_827.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_826_827.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_826_827.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_826_827.G(quantity = "ThermalConductance", unit = "W/K") = 5.19964408853279e-05 "Constant thermal conductance of material"; Real TC_826_837.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_826_837.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_826_837.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_826_837.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_826_837.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_826_837.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_826_837.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000787273501e-05 "Constant thermal conductance of material"; Real TC_826_1022.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_826_1022.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_826_1022.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_826_1022.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_826_1022.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_826_1022.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_826_1022.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433335959264644 "Constant thermal conductance of material"; Real TC_827_828.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_827_828.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_827_828.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_827_828.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_827_828.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_827_828.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_827_828.G(quantity = "ThermalConductance", unit = "W/K") = 5.20022912423628e-05 "Constant thermal conductance of material"; Real TC_827_838.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_827_838.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_827_838.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_827_838.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_827_838.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_827_838.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_827_838.G(quantity = "ThermalConductance", unit = "W/K") = 2.5999853967236e-05 "Constant thermal conductance of material"; Real TC_827_1023.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_827_1023.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_827_1023.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_827_1023.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_827_1023.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_827_1023.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_827_1023.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433331890144462 "Constant thermal conductance of material"; Real TC_828_829.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_828_829.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_828_829.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_828_829.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_828_829.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_828_829.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_828_829.G(quantity = "ThermalConductance", unit = "W/K") = 5.19984614891506e-05 "Constant thermal conductance of material"; Real TC_828_839.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_828_839.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_828_839.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_828_839.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_828_839.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_828_839.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_828_839.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001385091093e-05 "Constant thermal conductance of material"; Real TC_828_1024.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_828_1024.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_828_1024.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_828_1024.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_828_1024.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_828_1024.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_828_1024.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433333091167988 "Constant thermal conductance of material"; Real TC_829_830.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_829_830.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_829_830.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_829_830.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_829_830.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_829_830.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_829_830.G(quantity = "ThermalConductance", unit = "W/K") = 5.19996170364089e-05 "Constant thermal conductance of material"; Real TC_829_840.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_829_840.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_829_840.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_829_840.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_829_840.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_829_840.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_829_840.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997667281773e-05 "Constant thermal conductance of material"; Real TC_829_1025.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_829_1025.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_829_1025.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_829_1025.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_829_1025.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_829_1025.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_829_1025.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433335530218151 "Constant thermal conductance of material"; Real TC_830_831.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_830_831.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_830_831.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_830_831.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_830_831.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_830_831.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_830_831.G(quantity = "ThermalConductance", unit = "W/K") = 7.42880844429823e-05 "Constant thermal conductance of material"; Real TC_830_841.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_830_841.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_830_841.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_830_841.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_830_841.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_830_841.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_830_841.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001653849334e-05 "Constant thermal conductance of material"; Real TC_830_1026.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_830_1026.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_830_1026.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_830_1026.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_830_1026.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_830_1026.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_830_1026.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433327792158446 "Constant thermal conductance of material"; Real TC_831_842.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_831_842.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_831_842.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_831_842.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_831_842.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_831_842.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_831_842.G(quantity = "ThermalConductance", unit = "W/K") = 1.04000212685768e-05 "Constant thermal conductance of material"; Real TC_831_1027.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_831_1027.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_831_1027.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_831_1027.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_831_1027.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_831_1027.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_831_1027.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173332887879194 "Constant thermal conductance of material"; Real TC_832_833.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_832_833.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_832_833.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_832_833.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_832_833.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_832_833.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_832_833.G(quantity = "ThermalConductance", unit = "W/K") = 0.000222850888315702 "Constant thermal conductance of material"; Real TC_832_909.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_832_909.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_832_909.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_832_909.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_832_909.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_832_909.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_832_909.G(quantity = "ThermalConductance", unit = "W/K") = 1.03998380261532e-05 "Constant thermal conductance of material"; Real TC_832_1006.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_832_1006.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_832_1006.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_832_1006.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_832_1006.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_832_1006.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_832_1006.G(quantity = "ThermalConductance", unit = "W/K") = 0.000519986749471748 "Constant thermal conductance of material"; Real TC_833_834.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_833_834.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_833_834.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_833_834.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_833_834.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_833_834.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_833_834.G(quantity = "ThermalConductance", unit = "W/K") = 0.000155997689864279 "Constant thermal conductance of material"; Real TC_833_910.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_833_910.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_833_910.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_833_910.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_833_910.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_833_910.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_833_910.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002276900841e-05 "Constant thermal conductance of material"; Real TC_833_1007.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_833_1007.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_833_1007.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_833_1007.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_833_1007.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_833_1007.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_833_1007.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130001534462636 "Constant thermal conductance of material"; Real TC_834_835.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_834_835.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_834_835.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_834_835.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_834_835.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_834_835.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_834_835.G(quantity = "ThermalConductance", unit = "W/K") = 0.000155999033063845 "Constant thermal conductance of material"; Real TC_834_911.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_834_911.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_834_911.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_834_911.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_834_911.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_834_911.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_834_911.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997412961065e-05 "Constant thermal conductance of material"; Real TC_834_1008.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_834_1008.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_834_1008.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_834_1008.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_834_1008.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_834_1008.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_834_1008.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129997956230802 "Constant thermal conductance of material"; Real TC_835_836.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_835_836.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_835_836.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_835_836.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_835_836.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_835_836.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_835_836.G(quantity = "ThermalConductance", unit = "W/K") = 0.000156000521784495 "Constant thermal conductance of material"; Real TC_835_912.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_835_912.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_835_912.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_835_912.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_835_912.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_835_912.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_835_912.G(quantity = "ThermalConductance", unit = "W/K") = 2.60005633614537e-05 "Constant thermal conductance of material"; Real TC_835_1009.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_835_1009.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_835_1009.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_835_1009.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_835_1009.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_835_1009.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_835_1009.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130000933748939 "Constant thermal conductance of material"; Real TC_836_837.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_836_837.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_836_837.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_836_837.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_836_837.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_836_837.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_836_837.G(quantity = "ThermalConductance", unit = "W/K") = 0.000155995529893834 "Constant thermal conductance of material"; Real TC_836_913.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_836_913.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_836_913.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_836_913.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_836_913.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_836_913.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_836_913.G(quantity = "ThermalConductance", unit = "W/K") = 2.59996471633973e-05 "Constant thermal conductance of material"; Real TC_836_1010.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_836_1010.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_836_1010.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_836_1010.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_836_1010.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_836_1010.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_836_1010.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130001519677701 "Constant thermal conductance of material"; Real TC_837_838.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_837_838.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_837_838.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_837_838.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_837_838.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_837_838.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_837_838.G(quantity = "ThermalConductance", unit = "W/K") = 0.000156000148472592 "Constant thermal conductance of material"; Real TC_837_914.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_837_914.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_837_914.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_837_914.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_837_914.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_837_914.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_837_914.G(quantity = "ThermalConductance", unit = "W/K") = 2.5999990431858e-05 "Constant thermal conductance of material"; Real TC_837_1011.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_837_1011.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_837_1011.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_837_1011.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_837_1011.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_837_1011.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_837_1011.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130001979128221 "Constant thermal conductance of material"; Real TC_838_839.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_838_839.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_838_839.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_838_839.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_838_839.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_838_839.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_838_839.G(quantity = "ThermalConductance", unit = "W/K") = 0.000155999072479129 "Constant thermal conductance of material"; Real TC_838_915.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_838_915.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_838_915.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_838_915.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_838_915.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_838_915.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_838_915.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997873499821e-05 "Constant thermal conductance of material"; Real TC_838_1012.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_838_1012.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_838_1012.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_838_1012.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_838_1012.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_838_1012.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_838_1012.G(quantity = "ThermalConductance", unit = "W/K") = 0.0013000270278128 "Constant thermal conductance of material"; Real TC_839_840.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_839_840.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_839_840.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_839_840.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_839_840.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_839_840.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_839_840.G(quantity = "ThermalConductance", unit = "W/K") = 0.000156001186591517 "Constant thermal conductance of material"; Real TC_839_916.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_839_916.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_839_916.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_839_916.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_839_916.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_839_916.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_839_916.G(quantity = "ThermalConductance", unit = "W/K") = 2.59995406965115e-05 "Constant thermal conductance of material"; Real TC_839_1013.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_839_1013.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_839_1013.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_839_1013.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_839_1013.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_839_1013.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_839_1013.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129998749908398 "Constant thermal conductance of material"; Real TC_840_841.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_840_841.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_840_841.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_840_841.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_840_841.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_840_841.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_840_841.G(quantity = "ThermalConductance", unit = "W/K") = 0.000156001287545521 "Constant thermal conductance of material"; Real TC_840_917.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_840_917.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_840_917.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_840_917.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_840_917.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_840_917.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_840_917.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999686161283e-05 "Constant thermal conductance of material"; Real TC_840_1014.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_840_1014.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_840_1014.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_840_1014.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_840_1014.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_840_1014.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_840_1014.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012999666079135 "Constant thermal conductance of material"; Real TC_841_842.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_841_842.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_841_842.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_841_842.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_841_842.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_841_842.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_841_842.G(quantity = "ThermalConductance", unit = "W/K") = 0.000222856925459318 "Constant thermal conductance of material"; Real TC_841_918.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_841_918.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_841_918.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_841_918.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_841_918.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_841_918.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_841_918.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001887148518e-05 "Constant thermal conductance of material"; Real TC_841_1015.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_841_1015.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_841_1015.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_841_1015.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_841_1015.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_841_1015.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_841_1015.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130001993565864 "Constant thermal conductance of material"; Real TC_842_919.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_842_919.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_842_919.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_842_919.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_842_919.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_842_919.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_842_919.G(quantity = "ThermalConductance", unit = "W/K") = 1.03999695095391e-05 "Constant thermal conductance of material"; Real TC_842_1016.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_842_1016.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_842_1016.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_842_1016.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_842_1016.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_842_1016.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_842_1016.G(quantity = "ThermalConductance", unit = "W/K") = 0.00052001312879815 "Constant thermal conductance of material"; Real TC_843_844.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_843_844.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_843_844.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_843_844.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_843_844.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_843_844.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_843_844.G(quantity = "ThermalConductance", unit = "W/K") = 0.000208000196638841 "Constant thermal conductance of material"; Real TC_843_854.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_843_854.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_843_854.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_843_854.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_843_854.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_843_854.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_843_854.G(quantity = "ThermalConductance", unit = "W/K") = 1.09469614065805e-05 "Constant thermal conductance of material"; Real TC_843_964.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_843_964.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_843_964.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_843_964.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_843_964.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_843_964.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_843_964.G(quantity = "ThermalConductance", unit = "W/K") = 9.90405787983615e-06 "Constant thermal conductance of material"; Real TC_843_1038.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_843_1038.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_843_1038.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_843_1038.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_843_1038.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_843_1038.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_843_1038.G(quantity = "ThermalConductance", unit = "W/K") = 0.000485340129188534 "Constant thermal conductance of material"; Real TC_844_845.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_844_845.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_844_845.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_844_845.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_844_845.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_844_845.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_844_845.G(quantity = "ThermalConductance", unit = "W/K") = 0.000145600906353418 "Constant thermal conductance of material"; Real TC_844_855.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_844_855.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_844_855.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_844_855.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_844_855.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_844_855.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_844_855.G(quantity = "ThermalConductance", unit = "W/K") = 2.73686149877944e-05 "Constant thermal conductance of material"; Real TC_844_965.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_844_965.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_844_965.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_844_965.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_844_965.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_844_965.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_844_965.G(quantity = "ThermalConductance", unit = "W/K") = 2.47623562389217e-05 "Constant thermal conductance of material"; Real TC_844_1039.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_844_1039.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_844_1039.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_844_1039.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_844_1039.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_844_1039.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_844_1039.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012133587986485 "Constant thermal conductance of material"; Real TC_845_846.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_845_846.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_845_846.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_845_846.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_845_846.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_845_846.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_845_846.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001455987375832 "Constant thermal conductance of material"; Real TC_845_856.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_845_856.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_845_856.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_845_856.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_845_856.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_845_856.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_845_856.G(quantity = "ThermalConductance", unit = "W/K") = 2.73683520517412e-05 "Constant thermal conductance of material"; Real TC_845_966.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_845_966.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_845_966.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_845_966.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_845_966.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_845_966.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_845_966.G(quantity = "ThermalConductance", unit = "W/K") = 2.47625313540854e-05 "Constant thermal conductance of material"; Real TC_845_1040.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_845_1040.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_845_1040.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_845_1040.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_845_1040.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_845_1040.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_845_1040.G(quantity = "ThermalConductance", unit = "W/K") = 0.00121330080610946 "Constant thermal conductance of material"; Real TC_846_847.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_846_847.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_846_847.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_846_847.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_846_847.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_846_847.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_846_847.G(quantity = "ThermalConductance", unit = "W/K") = 0.000145600463326854 "Constant thermal conductance of material"; Real TC_846_857.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_846_857.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_846_857.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_846_857.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_846_857.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_846_857.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_846_857.G(quantity = "ThermalConductance", unit = "W/K") = 2.73698813132615e-05 "Constant thermal conductance of material"; Real TC_846_967.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_846_967.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_846_967.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_846_967.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_846_967.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_846_967.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_846_967.G(quantity = "ThermalConductance", unit = "W/K") = 2.47616254871544e-05 "Constant thermal conductance of material"; Real TC_846_1041.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_846_1041.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_846_1041.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_846_1041.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_846_1041.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_846_1041.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_846_1041.G(quantity = "ThermalConductance", unit = "W/K") = 0.00121329936255564 "Constant thermal conductance of material"; Real TC_847_848.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_847_848.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_847_848.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_847_848.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_847_848.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_847_848.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_847_848.G(quantity = "ThermalConductance", unit = "W/K") = 0.000145621584699454 "Constant thermal conductance of material"; Real TC_847_858.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_847_858.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_847_858.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_847_858.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_847_858.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_847_858.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_847_858.G(quantity = "ThermalConductance", unit = "W/K") = 2.73686868686868e-05 "Constant thermal conductance of material"; Real TC_847_968.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_847_968.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_847_968.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_847_968.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_847_968.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_847_968.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_847_968.G(quantity = "ThermalConductance", unit = "W/K") = 2.4761198182324e-05 "Constant thermal conductance of material"; Real TC_847_1042.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_847_1042.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_847_1042.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_847_1042.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_847_1042.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_847_1042.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_847_1042.G(quantity = "ThermalConductance", unit = "W/K") = 0.00121331906814074 "Constant thermal conductance of material"; Real TC_848_849.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_848_849.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_848_849.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_848_849.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_848_849.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_848_849.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_848_849.G(quantity = "ThermalConductance", unit = "W/K") = 0.000145603031490922 "Constant thermal conductance of material"; Real TC_848_859.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_848_859.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_848_859.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_848_859.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_848_859.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_848_859.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_848_859.G(quantity = "ThermalConductance", unit = "W/K") = 2.73688680187827e-05 "Constant thermal conductance of material"; Real TC_848_969.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_848_969.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_848_969.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_848_969.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_848_969.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_848_969.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_848_969.G(quantity = "ThermalConductance", unit = "W/K") = 2.47612749413455e-05 "Constant thermal conductance of material"; Real TC_848_1043.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_848_1043.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_848_1043.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_848_1043.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_848_1043.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_848_1043.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_848_1043.G(quantity = "ThermalConductance", unit = "W/K") = 0.00121329418494145 "Constant thermal conductance of material"; Real TC_849_850.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_849_850.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_849_850.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_849_850.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_849_850.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_849_850.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_849_850.G(quantity = "ThermalConductance", unit = "W/K") = 0.00014559790934487 "Constant thermal conductance of material"; Real TC_849_860.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_849_860.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_849_860.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_849_860.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_849_860.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_849_860.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_849_860.G(quantity = "ThermalConductance", unit = "W/K") = 2.73691841307499e-05 "Constant thermal conductance of material"; Real TC_849_970.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_849_970.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_849_970.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_849_970.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_849_970.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_849_970.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_849_970.G(quantity = "ThermalConductance", unit = "W/K") = 2.47627455307879e-05 "Constant thermal conductance of material"; Real TC_849_1044.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_849_1044.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_849_1044.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_849_1044.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_849_1044.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_849_1044.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_849_1044.G(quantity = "ThermalConductance", unit = "W/K") = 0.00121329738877545 "Constant thermal conductance of material"; Real TC_850_851.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_850_851.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_850_851.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_850_851.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_850_851.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_850_851.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_850_851.G(quantity = "ThermalConductance", unit = "W/K") = 0.000145600624895385 "Constant thermal conductance of material"; Real TC_850_861.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_850_861.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_850_861.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_850_861.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_850_861.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_850_861.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_850_861.G(quantity = "ThermalConductance", unit = "W/K") = 2.73688491256608e-05 "Constant thermal conductance of material"; Real TC_850_971.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_850_971.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_850_971.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_850_971.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_850_971.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_850_971.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_850_971.G(quantity = "ThermalConductance", unit = "W/K") = 2.47620866354754e-05 "Constant thermal conductance of material"; Real TC_850_1045.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_850_1045.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_850_1045.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_850_1045.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_850_1045.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_850_1045.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_850_1045.G(quantity = "ThermalConductance", unit = "W/K") = 0.00121331572928067 "Constant thermal conductance of material"; Real TC_851_852.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_851_852.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_851_852.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_851_852.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_851_852.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_851_852.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_851_852.G(quantity = "ThermalConductance", unit = "W/K") = 0.00014560351505115 "Constant thermal conductance of material"; Real TC_851_862.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_851_862.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_851_862.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_851_862.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_851_862.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_851_862.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_851_862.G(quantity = "ThermalConductance", unit = "W/K") = 2.73682737209095e-05 "Constant thermal conductance of material"; Real TC_851_972.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_851_972.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_851_972.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_851_972.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_851_972.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_851_972.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_851_972.G(quantity = "ThermalConductance", unit = "W/K") = 2.47627222960058e-05 "Constant thermal conductance of material"; Real TC_851_1046.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_851_1046.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_851_1046.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_851_1046.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_851_1046.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_851_1046.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_851_1046.G(quantity = "ThermalConductance", unit = "W/K") = 0.00121332736252652 "Constant thermal conductance of material"; Real TC_852_853.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_852_853.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_852_853.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_852_853.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_852_853.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_852_853.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_852_853.G(quantity = "ThermalConductance", unit = "W/K") = 0.0002079925216172 "Constant thermal conductance of material"; Real TC_852_863.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_852_863.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_852_863.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_852_863.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_852_863.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_852_863.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_852_863.G(quantity = "ThermalConductance", unit = "W/K") = 2.73673606447278e-05 "Constant thermal conductance of material"; Real TC_852_973.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_852_973.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_852_973.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_852_973.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_852_973.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_852_973.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_852_973.G(quantity = "ThermalConductance", unit = "W/K") = 2.4761904761905e-05 "Constant thermal conductance of material"; Real TC_852_1047.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_852_1047.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_852_1047.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_852_1047.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_852_1047.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_852_1047.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_852_1047.G(quantity = "ThermalConductance", unit = "W/K") = 0.00121335777988862 "Constant thermal conductance of material"; Real TC_853_864.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_853_864.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_853_864.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_853_864.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_853_864.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_853_864.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_853_864.G(quantity = "ThermalConductance", unit = "W/K") = 1.09476893333831e-05 "Constant thermal conductance of material"; Real TC_853_974.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_853_974.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_853_974.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_853_974.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_853_974.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_853_974.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_853_974.G(quantity = "ThermalConductance", unit = "W/K") = 9.9054537797424e-06 "Constant thermal conductance of material"; Real TC_853_1048.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_853_1048.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_853_1048.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_853_1048.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_853_1048.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_853_1048.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_853_1048.G(quantity = "ThermalConductance", unit = "W/K") = 0.000485325399363244 "Constant thermal conductance of material"; Real TC_854_855.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_854_855.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_854_855.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_854_855.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_854_855.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_854_855.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_854_855.G(quantity = "ThermalConductance", unit = "W/K") = 7.42863472243422e-05 "Constant thermal conductance of material"; Real TC_854_865.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_854_865.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_854_865.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_854_865.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_854_865.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_854_865.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_854_865.G(quantity = "ThermalConductance", unit = "W/K") = 2.08010827419707e-05 "Constant thermal conductance of material"; Real TC_854_1049.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_854_1049.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_854_1049.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_854_1049.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_854_1049.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_854_1049.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_854_1049.G(quantity = "ThermalConductance", unit = "W/K") = 0.00017333254157512 "Constant thermal conductance of material"; Real TC_855_856.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_855_856.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_855_856.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_855_856.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_855_856.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_855_856.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_855_856.G(quantity = "ThermalConductance", unit = "W/K") = 5.19999763141219e-05 "Constant thermal conductance of material"; Real TC_855_866.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_855_866.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_855_866.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_855_866.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_855_866.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_855_866.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_855_866.G(quantity = "ThermalConductance", unit = "W/K") = 5.20010067958723e-05 "Constant thermal conductance of material"; Real TC_855_1050.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_855_1050.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_855_1050.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_855_1050.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_855_1050.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_855_1050.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_855_1050.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433336798256759 "Constant thermal conductance of material"; Real TC_856_857.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_856_857.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_856_857.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_856_857.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_856_857.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_856_857.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_856_857.G(quantity = "ThermalConductance", unit = "W/K") = 5.20006955160954e-05 "Constant thermal conductance of material"; Real TC_856_867.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_856_867.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_856_867.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_856_867.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_856_867.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_856_867.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_856_867.G(quantity = "ThermalConductance", unit = "W/K") = 5.20023358023174e-05 "Constant thermal conductance of material"; Real TC_856_1051.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_856_1051.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_856_1051.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_856_1051.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_856_1051.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_856_1051.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_856_1051.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433336419999916 "Constant thermal conductance of material"; Real TC_857_858.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_857_858.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_857_858.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_857_858.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_857_858.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_857_858.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_857_858.G(quantity = "ThermalConductance", unit = "W/K") = 5.19969861362265e-05 "Constant thermal conductance of material"; Real TC_857_868.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_857_868.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_857_868.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_857_868.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_857_868.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_857_868.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_857_868.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001153635392e-05 "Constant thermal conductance of material"; Real TC_857_1052.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_857_1052.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_857_1052.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_857_1052.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_857_1052.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_857_1052.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_857_1052.G(quantity = "ThermalConductance", unit = "W/K") = 0.00043333799929902 "Constant thermal conductance of material"; Real TC_858_859.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_858_859.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_858_859.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_858_859.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_858_859.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_858_859.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_858_859.G(quantity = "ThermalConductance", unit = "W/K") = 5.20039904229837e-05 "Constant thermal conductance of material"; Real TC_858_869.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_858_869.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_858_869.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_858_869.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_858_869.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_858_869.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_858_869.G(quantity = "ThermalConductance", unit = "W/K") = 5.20004665811269e-05 "Constant thermal conductance of material"; Real TC_858_1053.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_858_1053.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_858_1053.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_858_1053.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_858_1053.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_858_1053.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_858_1053.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433329556417768 "Constant thermal conductance of material"; Real TC_859_860.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_859_860.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_859_860.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_859_860.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_859_860.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_859_860.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_859_860.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000000000001e-05 "Constant thermal conductance of material"; Real TC_859_870.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_859_870.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_859_870.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_859_870.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_859_870.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_859_870.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_859_870.G(quantity = "ThermalConductance", unit = "W/K") = 5.19999282536952e-05 "Constant thermal conductance of material"; Real TC_859_1054.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_859_1054.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_859_1054.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_859_1054.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_859_1054.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_859_1054.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_859_1054.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433336458570517 "Constant thermal conductance of material"; Real TC_860_861.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_860_861.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_860_861.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_860_861.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_860_861.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_860_861.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_860_861.G(quantity = "ThermalConductance", unit = "W/K") = 5.20012010208699e-05 "Constant thermal conductance of material"; Real TC_860_871.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_860_871.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_860_871.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_860_871.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_860_871.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_860_871.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_860_871.G(quantity = "ThermalConductance", unit = "W/K") = 5.2001258799944e-05 "Constant thermal conductance of material"; Real TC_860_1055.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_860_1055.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_860_1055.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_860_1055.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_860_1055.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_860_1055.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_860_1055.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433329979327126 "Constant thermal conductance of material"; Real TC_861_862.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_861_862.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_861_862.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_861_862.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_861_862.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_861_862.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_861_862.G(quantity = "ThermalConductance", unit = "W/K") = 5.19987550333608e-05 "Constant thermal conductance of material"; Real TC_861_872.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_861_872.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_861_872.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_861_872.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_861_872.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_861_872.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_861_872.G(quantity = "ThermalConductance", unit = "W/K") = 5.19989120056843e-05 "Constant thermal conductance of material"; Real TC_861_1056.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_861_1056.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_861_1056.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_861_1056.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_861_1056.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_861_1056.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_861_1056.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433332304854762 "Constant thermal conductance of material"; Real TC_862_863.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_862_863.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_862_863.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_862_863.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_862_863.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_862_863.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_862_863.G(quantity = "ThermalConductance", unit = "W/K") = 5.20004429608771e-05 "Constant thermal conductance of material"; Real TC_862_873.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_862_873.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_862_873.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_862_873.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_862_873.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_862_873.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_862_873.G(quantity = "ThermalConductance", unit = "W/K") = 5.19986991053497e-05 "Constant thermal conductance of material"; Real TC_862_1057.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_862_1057.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_862_1057.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_862_1057.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_862_1057.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_862_1057.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_862_1057.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433330859161655 "Constant thermal conductance of material"; Real TC_863_864.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_863_864.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_863_864.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_863_864.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_863_864.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_863_864.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_863_864.G(quantity = "ThermalConductance", unit = "W/K") = 7.42855307060017e-05 "Constant thermal conductance of material"; Real TC_863_874.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_863_874.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_863_874.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_863_874.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_863_874.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_863_874.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_863_874.G(quantity = "ThermalConductance", unit = "W/K") = 5.19994867627565e-05 "Constant thermal conductance of material"; Real TC_863_1058.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_863_1058.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_863_1058.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_863_1058.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_863_1058.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_863_1058.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_863_1058.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433329510311093 "Constant thermal conductance of material"; Real TC_864_875.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_864_875.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_864_875.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_864_875.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_864_875.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_864_875.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_864_875.G(quantity = "ThermalConductance", unit = "W/K") = 2.07994226392052e-05 "Constant thermal conductance of material"; Real TC_864_1059.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_864_1059.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_864_1059.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_864_1059.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_864_1059.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_864_1059.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_864_1059.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173333958636214 "Constant thermal conductance of material"; Real TC_865_866.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_865_866.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_865_866.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_865_866.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_865_866.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_865_866.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_865_866.G(quantity = "ThermalConductance", unit = "W/K") = 7.42857904274598e-05 "Constant thermal conductance of material"; Real TC_865_876.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_865_876.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_865_876.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_865_876.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_865_876.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_865_876.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_865_876.G(quantity = "ThermalConductance", unit = "W/K") = 2.07994599546751e-05 "Constant thermal conductance of material"; Real TC_865_1060.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_865_1060.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_865_1060.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_865_1060.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_865_1060.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_865_1060.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_865_1060.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173333084933957 "Constant thermal conductance of material"; Real TC_866_867.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_866_867.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_866_867.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_866_867.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_866_867.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_866_867.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_866_867.G(quantity = "ThermalConductance", unit = "W/K") = 5.20002703067981e-05 "Constant thermal conductance of material"; Real TC_866_877.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_866_877.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_866_877.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_866_877.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_866_877.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_866_877.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_866_877.G(quantity = "ThermalConductance", unit = "W/K") = 5.19996052599118e-05 "Constant thermal conductance of material"; Real TC_866_1061.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_866_1061.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_866_1061.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_866_1061.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_866_1061.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_866_1061.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_866_1061.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433335912713766 "Constant thermal conductance of material"; Real TC_867_868.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_867_868.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_867_868.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_867_868.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_867_868.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_867_868.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_867_868.G(quantity = "ThermalConductance", unit = "W/K") = 5.19991691764467e-05 "Constant thermal conductance of material"; Real TC_867_878.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_867_878.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_867_878.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_867_878.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_867_878.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_867_878.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_867_878.G(quantity = "ThermalConductance", unit = "W/K") = 5.19996659269337e-05 "Constant thermal conductance of material"; Real TC_867_1062.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_867_1062.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_867_1062.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_867_1062.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_867_1062.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_867_1062.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_867_1062.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433332809199595 "Constant thermal conductance of material"; Real TC_868_869.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_868_869.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_868_869.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_868_869.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_868_869.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_868_869.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_868_869.G(quantity = "ThermalConductance", unit = "W/K") = 5.19988895058304e-05 "Constant thermal conductance of material"; Real TC_868_879.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_868_879.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_868_879.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_868_879.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_868_879.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_868_879.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_868_879.G(quantity = "ThermalConductance", unit = "W/K") = 5.20007052885619e-05 "Constant thermal conductance of material"; Real TC_868_1063.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_868_1063.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_868_1063.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_868_1063.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_868_1063.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_868_1063.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_868_1063.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433335427421434 "Constant thermal conductance of material"; Real TC_869_870.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_869_870.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_869_870.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_869_870.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_869_870.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_869_870.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_869_870.G(quantity = "ThermalConductance", unit = "W/K") = 5.20005884083554e-05 "Constant thermal conductance of material"; Real TC_869_880.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_869_880.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_869_880.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_869_880.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_869_880.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_869_880.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_869_880.G(quantity = "ThermalConductance", unit = "W/K") = 5.20009579389186e-05 "Constant thermal conductance of material"; Real TC_869_1064.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_869_1064.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_869_1064.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_869_1064.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_869_1064.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_869_1064.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_869_1064.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433335389387237 "Constant thermal conductance of material"; Real TC_870_871.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_870_871.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_870_871.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_870_871.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_870_871.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_870_871.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_870_871.G(quantity = "ThermalConductance", unit = "W/K") = 5.20007364482598e-05 "Constant thermal conductance of material"; Real TC_870_881.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_870_881.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_870_881.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_870_881.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_870_881.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_870_881.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_870_881.G(quantity = "ThermalConductance", unit = "W/K") = 5.1998885991341e-05 "Constant thermal conductance of material"; Real TC_870_1065.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_870_1065.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_870_1065.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_870_1065.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_870_1065.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_870_1065.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_870_1065.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433333106617605 "Constant thermal conductance of material"; Real TC_871_872.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_871_872.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_871_872.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_871_872.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_871_872.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_871_872.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_871_872.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000765476989e-05 "Constant thermal conductance of material"; Real TC_871_882.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_871_882.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_871_882.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_871_882.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_871_882.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_871_882.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_871_882.G(quantity = "ThermalConductance", unit = "W/K") = 5.20021615779518e-05 "Constant thermal conductance of material"; Real TC_871_1647.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_871_1647.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_871_1647.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_871_1647.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_871_1647.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_871_1647.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_871_1647.G(quantity = "ThermalConductance", unit = "W/K") = 0.00064831101233371 "Constant thermal conductance of material"; Real TC_872_873.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_872_873.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_872_873.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_872_873.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_872_873.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_872_873.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_872_873.G(quantity = "ThermalConductance", unit = "W/K") = 5.19999999999999e-05 "Constant thermal conductance of material"; Real TC_872_883.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_872_883.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_872_883.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_872_883.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_872_883.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_872_883.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_872_883.G(quantity = "ThermalConductance", unit = "W/K") = 5.2002332218369e-05 "Constant thermal conductance of material"; Real TC_872_1648.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_872_1648.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_872_1648.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_872_1648.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_872_1648.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_872_1648.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_872_1648.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648314806281919 "Constant thermal conductance of material"; Real TC_873_874.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_873_874.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_873_874.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_873_874.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_873_874.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_873_874.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_873_874.G(quantity = "ThermalConductance", unit = "W/K") = 5.20005107428268e-05 "Constant thermal conductance of material"; Real TC_873_884.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_873_884.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_873_884.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_873_884.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_873_884.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_873_884.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_873_884.G(quantity = "ThermalConductance", unit = "W/K") = 5.20007578628269e-05 "Constant thermal conductance of material"; Real TC_873_1649.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_873_1649.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_873_1649.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_873_1649.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_873_1649.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_873_1649.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_873_1649.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648308404233999 "Constant thermal conductance of material"; Real TC_874_875.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_874_875.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_874_875.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_874_875.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_874_875.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_874_875.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_874_875.G(quantity = "ThermalConductance", unit = "W/K") = 7.42860659773511e-05 "Constant thermal conductance of material"; Real TC_874_885.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_874_885.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_874_885.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_874_885.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_874_885.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_874_885.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_874_885.G(quantity = "ThermalConductance", unit = "W/K") = 5.19964907883176e-05 "Constant thermal conductance of material"; Real TC_874_975.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_874_975.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_874_975.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_874_975.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_874_975.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_874_975.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_874_975.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433335611219849 "Constant thermal conductance of material"; Real TC_875_886.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_875_886.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_875_886.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_875_886.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_875_886.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_875_886.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_875_886.G(quantity = "ThermalConductance", unit = "W/K") = 2.08033106134355e-05 "Constant thermal conductance of material"; Real TC_875_976.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_875_976.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_875_976.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_875_976.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_875_976.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_875_976.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_875_976.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173334370027685 "Constant thermal conductance of material"; Real TC_876_877.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_876_877.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_876_877.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_876_877.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_876_877.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_876_877.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_876_877.G(quantity = "ThermalConductance", unit = "W/K") = 7.42852543380667e-05 "Constant thermal conductance of material"; Real TC_876_887.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_876_887.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_876_887.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_876_887.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_876_887.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_876_887.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_876_887.G(quantity = "ThermalConductance", unit = "W/K") = 2.08004337523596e-05 "Constant thermal conductance of material"; Real TC_876_977.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_876_977.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_876_977.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_876_977.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_876_977.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_876_977.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_876_977.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173333044923891 "Constant thermal conductance of material"; Real TC_877_878.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_877_878.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_877_878.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_877_878.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_877_878.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_877_878.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_877_878.G(quantity = "ThermalConductance", unit = "W/K") = 5.20019741280557e-05 "Constant thermal conductance of material"; Real TC_877_888.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_877_888.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_877_888.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_877_888.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_877_888.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_877_888.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_877_888.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000588902136e-05 "Constant thermal conductance of material"; Real TC_877_978.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_877_978.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_877_978.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_877_978.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_877_978.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_877_978.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_877_978.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433328489020983 "Constant thermal conductance of material"; Real TC_878_879.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_878_879.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_878_879.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_878_879.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_878_879.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_878_879.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_878_879.G(quantity = "ThermalConductance", unit = "W/K") = 5.1999128445364e-05 "Constant thermal conductance of material"; Real TC_878_889.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_878_889.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_878_889.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_878_889.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_878_889.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_878_889.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_878_889.G(quantity = "ThermalConductance", unit = "W/K") = 5.19996285217119e-05 "Constant thermal conductance of material"; Real TC_878_979.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_878_979.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_878_979.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_878_979.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_878_979.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_878_979.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_878_979.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433333227639724 "Constant thermal conductance of material"; Real TC_879_880.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_879_880.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_879_880.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_879_880.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_879_880.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_879_880.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_879_880.G(quantity = "ThermalConductance", unit = "W/K") = 5.20008328128284e-05 "Constant thermal conductance of material"; Real TC_879_890.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_879_890.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_879_890.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_879_890.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_879_890.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_879_890.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_879_890.G(quantity = "ThermalConductance", unit = "W/K") = 5.19995795890483e-05 "Constant thermal conductance of material"; Real TC_879_980.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_879_980.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_879_980.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_879_980.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_879_980.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_879_980.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_879_980.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433328760734177 "Constant thermal conductance of material"; Real TC_880_881.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_880_881.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_880_881.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_880_881.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_880_881.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_880_881.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_880_881.G(quantity = "ThermalConductance", unit = "W/K") = 5.20051282051262e-05 "Constant thermal conductance of material"; Real TC_880_891.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_880_891.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_880_891.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_880_891.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_880_891.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_880_891.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_880_891.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000624125574e-05 "Constant thermal conductance of material"; Real TC_880_981.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_880_981.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_880_981.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_880_981.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_880_981.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_880_981.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_880_981.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433335674603573 "Constant thermal conductance of material"; Real TC_881_882.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_881_882.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_881_882.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_881_882.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_881_882.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_881_882.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_881_882.G(quantity = "ThermalConductance", unit = "W/K") = 5.19986162216561e-05 "Constant thermal conductance of material"; Real TC_881_892.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_881_892.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_881_892.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_881_892.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_881_892.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_881_892.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_881_892.G(quantity = "ThermalConductance", unit = "W/K") = 5.19994845582233e-05 "Constant thermal conductance of material"; Real TC_881_982.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_881_982.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_881_982.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_881_982.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_881_982.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_881_982.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_881_982.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433338928339391 "Constant thermal conductance of material"; Real TC_882_883.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_882_883.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_882_883.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_882_883.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_882_883.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_882_883.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_882_883.G(quantity = "ThermalConductance", unit = "W/K") = 5.20039814200409e-05 "Constant thermal conductance of material"; Real TC_882_893.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_882_893.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_882_893.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_882_893.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_882_893.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_882_893.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_882_893.G(quantity = "ThermalConductance", unit = "W/K") = 5.1999764387112e-05 "Constant thermal conductance of material"; Real TC_882_1650.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_882_1650.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_882_1650.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_882_1650.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_882_1650.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_882_1650.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_882_1650.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648316011329255 "Constant thermal conductance of material"; Real TC_883_884.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_883_884.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_883_884.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_883_884.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_883_884.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_883_884.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_883_884.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000831205842e-05 "Constant thermal conductance of material"; Real TC_883_894.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_883_894.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_883_894.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_883_894.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_883_894.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_883_894.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_883_894.G(quantity = "ThermalConductance", unit = "W/K") = 5.20005836859771e-05 "Constant thermal conductance of material"; Real TC_883_1651.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_883_1651.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_883_1651.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_883_1651.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_883_1651.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_883_1651.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_883_1651.G(quantity = "ThermalConductance", unit = "W/K") = 0.0006483125670843 "Constant thermal conductance of material"; Real TC_884_885.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_884_885.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_884_885.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_884_885.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_884_885.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_884_885.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_884_885.G(quantity = "ThermalConductance", unit = "W/K") = 5.19997655379926e-05 "Constant thermal conductance of material"; Real TC_884_895.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_884_895.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_884_895.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_884_895.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_884_895.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_884_895.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_884_895.G(quantity = "ThermalConductance", unit = "W/K") = 5.20022380305334e-05 "Constant thermal conductance of material"; Real TC_884_1652.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_884_1652.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_884_1652.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_884_1652.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_884_1652.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_884_1652.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_884_1652.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648318621932787 "Constant thermal conductance of material"; Real TC_885_886.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_885_886.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_885_886.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_885_886.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_885_886.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_885_886.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_885_886.G(quantity = "ThermalConductance", unit = "W/K") = 7.42862796334717e-05 "Constant thermal conductance of material"; Real TC_885_896.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_885_896.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_885_896.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_885_896.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_885_896.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_885_896.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_885_896.G(quantity = "ThermalConductance", unit = "W/K") = 5.19990042320133e-05 "Constant thermal conductance of material"; Real TC_885_983.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_885_983.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_885_983.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_885_983.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_885_983.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_885_983.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_885_983.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433331521889589 "Constant thermal conductance of material"; Real TC_886_897.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_886_897.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_886_897.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_886_897.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_886_897.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_886_897.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_886_897.G(quantity = "ThermalConductance", unit = "W/K") = 2.07997954860857e-05 "Constant thermal conductance of material"; Real TC_886_984.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_886_984.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_886_984.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_886_984.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_886_984.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_886_984.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_886_984.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173332998832033 "Constant thermal conductance of material"; Real TC_887_888.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_887_888.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_887_888.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_887_888.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_887_888.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_887_888.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_887_888.G(quantity = "ThermalConductance", unit = "W/K") = 7.4285194356804e-05 "Constant thermal conductance of material"; Real TC_887_898.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_887_898.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_887_898.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_887_898.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_887_898.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_887_898.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_887_898.G(quantity = "ThermalConductance", unit = "W/K") = 2.08017641597013e-05 "Constant thermal conductance of material"; Real TC_887_985.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_887_985.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_887_985.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_887_985.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_887_985.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_887_985.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_887_985.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173332177971163 "Constant thermal conductance of material"; Real TC_888_889.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_888_889.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_888_889.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_888_889.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_888_889.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_888_889.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_888_889.G(quantity = "ThermalConductance", unit = "W/K") = 5.20004981231432e-05 "Constant thermal conductance of material"; Real TC_888_899.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_888_899.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_888_899.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_888_899.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_888_899.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_888_899.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_888_899.G(quantity = "ThermalConductance", unit = "W/K") = 5.19979079497911e-05 "Constant thermal conductance of material"; Real TC_888_986.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_888_986.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_888_986.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_888_986.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_888_986.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_888_986.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_888_986.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433330540682575 "Constant thermal conductance of material"; Real TC_889_890.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_889_890.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_889_890.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_889_890.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_889_890.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_889_890.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_889_890.G(quantity = "ThermalConductance", unit = "W/K") = 5.20004338663689e-05 "Constant thermal conductance of material"; Real TC_889_900.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_889_900.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_889_900.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_889_900.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_889_900.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_889_900.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_889_900.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001059658792e-05 "Constant thermal conductance of material"; Real TC_889_1656.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_889_1656.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_889_1656.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_889_1656.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_889_1656.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_889_1656.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_889_1656.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648309674356099 "Constant thermal conductance of material"; Real TC_890_891.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_890_891.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_890_891.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_890_891.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_890_891.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_890_891.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_890_891.G(quantity = "ThermalConductance", unit = "W/K") = 5.20019114585104e-05 "Constant thermal conductance of material"; Real TC_890_901.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_890_901.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_890_901.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_890_901.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_890_901.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_890_901.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_890_901.G(quantity = "ThermalConductance", unit = "W/K") = 5.19989935840987e-05 "Constant thermal conductance of material"; Real TC_890_1657.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_890_1657.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_890_1657.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_890_1657.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_890_1657.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_890_1657.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_890_1657.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648309957861257 "Constant thermal conductance of material"; Real TC_891_892.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_891_892.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_891_892.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_891_892.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_891_892.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_891_892.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_891_892.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001396054981e-05 "Constant thermal conductance of material"; Real TC_891_902.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_891_902.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_891_902.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_891_902.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_891_902.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_891_902.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_891_902.G(quantity = "ThermalConductance", unit = "W/K") = 5.20007389617581e-05 "Constant thermal conductance of material"; Real TC_891_1658.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_891_1658.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_891_1658.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_891_1658.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_891_1658.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_891_1658.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_891_1658.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648310861481911 "Constant thermal conductance of material"; Real TC_892_893.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_892_893.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_892_893.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_892_893.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_892_893.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_892_893.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_892_893.G(quantity = "ThermalConductance", unit = "W/K") = 5.19983807004649e-05 "Constant thermal conductance of material"; Real TC_892_903.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_892_903.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_892_903.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_892_903.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_892_903.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_892_903.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_892_903.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000452399129e-05 "Constant thermal conductance of material"; Real TC_892_987.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_892_987.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_892_987.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_892_987.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_892_987.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_892_987.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_892_987.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433331762916012 "Constant thermal conductance of material"; Real TC_893_894.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_893_894.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_893_894.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_893_894.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_893_894.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_893_894.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_893_894.G(quantity = "ThermalConductance", unit = "W/K") = 5.20026642984012e-05 "Constant thermal conductance of material"; Real TC_893_904.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_893_904.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_893_904.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_893_904.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_893_904.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_893_904.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_893_904.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000658748205e-05 "Constant thermal conductance of material"; Real TC_893_1653.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_893_1653.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_893_1653.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_893_1653.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_893_1653.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_893_1653.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_893_1653.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648310385039462 "Constant thermal conductance of material"; Real TC_894_895.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_894_895.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_894_895.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_894_895.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_894_895.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_894_895.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_894_895.G(quantity = "ThermalConductance", unit = "W/K") = 5.20002831257077e-05 "Constant thermal conductance of material"; Real TC_894_905.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_894_905.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_894_905.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_894_905.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_894_905.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_894_905.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_894_905.G(quantity = "ThermalConductance", unit = "W/K") = 5.20008874418953e-05 "Constant thermal conductance of material"; Real TC_894_1654.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_894_1654.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_894_1654.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_894_1654.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_894_1654.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_894_1654.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_894_1654.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648309582474796 "Constant thermal conductance of material"; Real TC_895_896.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_895_896.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_895_896.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_895_896.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_895_896.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_895_896.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_895_896.G(quantity = "ThermalConductance", unit = "W/K") = 5.20003560144186e-05 "Constant thermal conductance of material"; Real TC_895_906.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_895_906.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_895_906.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_895_906.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_895_906.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_895_906.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_895_906.G(quantity = "ThermalConductance", unit = "W/K") = 5.20011661775805e-05 "Constant thermal conductance of material"; Real TC_895_1655.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_895_1655.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_895_1655.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_895_1655.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_895_1655.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_895_1655.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_895_1655.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648310236393221 "Constant thermal conductance of material"; Real TC_896_897.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_896_897.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_896_897.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_896_897.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_896_897.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_896_897.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_896_897.G(quantity = "ThermalConductance", unit = "W/K") = 7.42862597661987e-05 "Constant thermal conductance of material"; Real TC_896_907.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_896_907.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_896_907.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_896_907.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_896_907.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_896_907.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_896_907.G(quantity = "ThermalConductance", unit = "W/K") = 5.20005684330198e-05 "Constant thermal conductance of material"; Real TC_896_988.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_896_988.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_896_988.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_896_988.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_896_988.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_896_988.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_896_988.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433332685065862 "Constant thermal conductance of material"; Real TC_897_908.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_897_908.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_897_908.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_897_908.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_897_908.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_897_908.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_897_908.G(quantity = "ThermalConductance", unit = "W/K") = 2.08004293713192e-05 "Constant thermal conductance of material"; Real TC_897_989.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_897_989.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_897_989.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_897_989.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_897_989.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_897_989.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_897_989.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173333296138943 "Constant thermal conductance of material"; Real TC_898_899.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_898_899.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_898_899.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_898_899.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_898_899.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_898_899.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_898_899.G(quantity = "ThermalConductance", unit = "W/K") = 7.42861370384026e-05 "Constant thermal conductance of material"; Real TC_898_909.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_898_909.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_898_909.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_898_909.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_898_909.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_898_909.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_898_909.G(quantity = "ThermalConductance", unit = "W/K") = 2.07999715059125e-05 "Constant thermal conductance of material"; Real TC_898_990.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_898_990.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_898_990.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_898_990.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_898_990.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_898_990.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_898_990.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173331181988277 "Constant thermal conductance of material"; Real TC_899_900.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_899_900.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_899_900.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_899_900.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_899_900.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_899_900.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_899_900.G(quantity = "ThermalConductance", unit = "W/K") = 5.20006001971102e-05 "Constant thermal conductance of material"; Real TC_899_910.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_899_910.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_899_910.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_899_910.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_899_910.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_899_910.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_899_910.G(quantity = "ThermalConductance", unit = "W/K") = 5.20008546747657e-05 "Constant thermal conductance of material"; Real TC_899_991.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_899_991.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_899_991.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_899_991.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_899_991.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_899_991.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_899_991.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433336158872781 "Constant thermal conductance of material"; Real TC_900_901.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_900_901.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_900_901.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_900_901.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_900_901.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_900_901.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_900_901.G(quantity = "ThermalConductance", unit = "W/K") = 5.19997595178329e-05 "Constant thermal conductance of material"; Real TC_900_911.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_900_911.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_900_911.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_900_911.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_900_911.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_900_911.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_900_911.G(quantity = "ThermalConductance", unit = "W/K") = 5.1999645295735e-05 "Constant thermal conductance of material"; Real TC_900_1659.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_900_1659.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_900_1659.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_900_1659.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_900_1659.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_900_1659.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_900_1659.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648314650559183 "Constant thermal conductance of material"; Real TC_901_902.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_901_902.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_901_902.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_901_902.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_901_902.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_901_902.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_901_902.G(quantity = "ThermalConductance", unit = "W/K") = 5.1999904709722e-05 "Constant thermal conductance of material"; Real TC_901_912.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_901_912.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_901_912.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_901_912.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_901_912.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_901_912.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_901_912.G(quantity = "ThermalConductance", unit = "W/K") = 5.19991844224689e-05 "Constant thermal conductance of material"; Real TC_901_1660.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_901_1660.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_901_1660.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_901_1660.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_901_1660.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_901_1660.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_901_1660.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648309069619495 "Constant thermal conductance of material"; Real TC_902_903.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_902_903.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_902_903.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_902_903.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_902_903.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_902_903.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_902_903.G(quantity = "ThermalConductance", unit = "W/K") = 5.19989760201645e-05 "Constant thermal conductance of material"; Real TC_902_913.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_902_913.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_902_913.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_902_913.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_902_913.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_902_913.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_902_913.G(quantity = "ThermalConductance", unit = "W/K") = 5.20014468290326e-05 "Constant thermal conductance of material"; Real TC_902_1661.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_902_1661.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_902_1661.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_902_1661.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_902_1661.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_902_1661.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_902_1661.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648316145637921 "Constant thermal conductance of material"; Real TC_903_904.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_903_904.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_903_904.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_903_904.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_903_904.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_903_904.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_903_904.G(quantity = "ThermalConductance", unit = "W/K") = 5.20004261893345e-05 "Constant thermal conductance of material"; Real TC_903_914.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_903_914.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_903_914.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_903_914.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_903_914.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_903_914.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_903_914.G(quantity = "ThermalConductance", unit = "W/K") = 5.19987409505826e-05 "Constant thermal conductance of material"; Real TC_903_992.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_903_992.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_903_992.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_903_992.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_903_992.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_903_992.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_903_992.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433337365921165 "Constant thermal conductance of material"; Real TC_904_905.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_904_905.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_904_905.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_904_905.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_904_905.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_904_905.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_904_905.G(quantity = "ThermalConductance", unit = "W/K") = 5.19995924397581e-05 "Constant thermal conductance of material"; Real TC_904_915.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_904_915.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_904_915.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_904_915.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_904_915.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_904_915.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_904_915.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000499968752e-05 "Constant thermal conductance of material"; Real TC_904_993.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_904_993.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_904_993.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_904_993.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_904_993.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_904_993.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_904_993.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433328773057893 "Constant thermal conductance of material"; Real TC_905_906.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_905_906.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_905_906.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_905_906.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_905_906.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_905_906.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_905_906.G(quantity = "ThermalConductance", unit = "W/K") = 5.20002518019575e-05 "Constant thermal conductance of material"; Real TC_905_916.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_905_916.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_905_916.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_905_916.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_905_916.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_905_916.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_905_916.G(quantity = "ThermalConductance", unit = "W/K") = 5.20004628022677e-05 "Constant thermal conductance of material"; Real TC_905_994.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_905_994.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_905_994.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_905_994.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_905_994.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_905_994.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_905_994.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433334095272927 "Constant thermal conductance of material"; Real TC_906_907.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_906_907.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_906_907.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_906_907.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_906_907.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_906_907.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_906_907.G(quantity = "ThermalConductance", unit = "W/K") = 5.19999160911041e-05 "Constant thermal conductance of material"; Real TC_906_917.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_906_917.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_906_917.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_906_917.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_906_917.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_906_917.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_906_917.G(quantity = "ThermalConductance", unit = "W/K") = 5.20003457387696e-05 "Constant thermal conductance of material"; Real TC_906_995.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_906_995.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_906_995.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_906_995.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_906_995.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_906_995.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_906_995.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433333555966685 "Constant thermal conductance of material"; Real TC_907_908.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_907_908.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_907_908.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_907_908.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_907_908.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_907_908.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_907_908.G(quantity = "ThermalConductance", unit = "W/K") = 7.42864504176782e-05 "Constant thermal conductance of material"; Real TC_907_918.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_907_918.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_907_918.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_907_918.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_907_918.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_907_918.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_907_918.G(quantity = "ThermalConductance", unit = "W/K") = 5.19991024438007e-05 "Constant thermal conductance of material"; Real TC_907_996.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_907_996.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_907_996.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_907_996.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_907_996.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_907_996.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_907_996.G(quantity = "ThermalConductance", unit = "W/K") = 0.00043333471541994 "Constant thermal conductance of material"; Real TC_908_919.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_908_919.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_908_919.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_908_919.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_908_919.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_908_919.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_908_919.G(quantity = "ThermalConductance", unit = "W/K") = 2.0799282439705e-05 "Constant thermal conductance of material"; Real TC_908_997.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_908_997.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_908_997.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_908_997.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_908_997.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_908_997.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_908_997.G(quantity = "ThermalConductance", unit = "W/K") = 0.00017333207396213 "Constant thermal conductance of material"; Real TC_909_910.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_909_910.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_909_910.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_909_910.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_909_910.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_909_910.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_909_910.G(quantity = "ThermalConductance", unit = "W/K") = 7.42861743041045e-05 "Constant thermal conductance of material"; Real TC_909_998.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_909_998.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_909_998.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_909_998.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_909_998.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_909_998.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_909_998.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173333791590768 "Constant thermal conductance of material"; Real TC_910_911.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_910_911.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_910_911.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_910_911.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_910_911.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_910_911.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_910_911.G(quantity = "ThermalConductance", unit = "W/K") = 5.20006897428618e-05 "Constant thermal conductance of material"; Real TC_910_999.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_910_999.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_910_999.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_910_999.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_910_999.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_910_999.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_910_999.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433335141632666 "Constant thermal conductance of material"; Real TC_911_912.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_911_912.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_911_912.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_911_912.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_911_912.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_911_912.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_911_912.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001278036936e-05 "Constant thermal conductance of material"; Real TC_911_1662.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_911_1662.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_911_1662.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_911_1662.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_911_1662.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_911_1662.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_911_1662.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648313379232571 "Constant thermal conductance of material"; Real TC_912_913.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_912_913.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_912_913.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_912_913.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_912_913.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_912_913.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_912_913.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001873711822e-05 "Constant thermal conductance of material"; Real TC_912_1663.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_912_1663.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_912_1663.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_912_1663.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_912_1663.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_912_1663.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_912_1663.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648318465392962 "Constant thermal conductance of material"; Real TC_913_914.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_913_914.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_913_914.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_913_914.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_913_914.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_913_914.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_913_914.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001178417288e-05 "Constant thermal conductance of material"; Real TC_913_1664.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_913_1664.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_913_1664.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_913_1664.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_913_1664.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_913_1664.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_913_1664.G(quantity = "ThermalConductance", unit = "W/K") = 0.000648313666734701 "Constant thermal conductance of material"; Real TC_914_915.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_914_915.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_914_915.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_914_915.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_914_915.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_914_915.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_914_915.G(quantity = "ThermalConductance", unit = "W/K") = 5.20003275390121e-05 "Constant thermal conductance of material"; Real TC_914_1000.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_914_1000.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_914_1000.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_914_1000.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_914_1000.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_914_1000.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_914_1000.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433329155120624 "Constant thermal conductance of material"; Real TC_915_916.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_915_916.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_915_916.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_915_916.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_915_916.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_915_916.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_915_916.G(quantity = "ThermalConductance", unit = "W/K") = 5.19996497603051e-05 "Constant thermal conductance of material"; Real TC_915_1001.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_915_1001.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_915_1001.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_915_1001.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_915_1001.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_915_1001.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_915_1001.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433334855839125 "Constant thermal conductance of material"; Real TC_916_917.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_916_917.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_916_917.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_916_917.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_916_917.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_916_917.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_916_917.G(quantity = "ThermalConductance", unit = "W/K") = 5.19983476195391e-05 "Constant thermal conductance of material"; Real TC_916_1002.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_916_1002.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_916_1002.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_916_1002.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_916_1002.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_916_1002.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_916_1002.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433337823380828 "Constant thermal conductance of material"; Real TC_917_918.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_917_918.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_917_918.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_917_918.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_917_918.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_917_918.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_917_918.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000756053151e-05 "Constant thermal conductance of material"; Real TC_917_1003.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_917_1003.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_917_1003.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_917_1003.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_917_1003.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_917_1003.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_917_1003.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433333914453326 "Constant thermal conductance of material"; Real TC_918_919.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_918_919.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_918_919.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_918_919.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_918_919.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_918_919.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_918_919.G(quantity = "ThermalConductance", unit = "W/K") = 7.42860204683063e-05 "Constant thermal conductance of material"; Real TC_918_1004.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_918_1004.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_918_1004.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_918_1004.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_918_1004.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_918_1004.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_918_1004.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433337519780965 "Constant thermal conductance of material"; Real TC_919_1005.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_919_1005.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_919_1005.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_919_1005.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_919_1005.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_919_1005.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_919_1005.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173332995583927 "Constant thermal conductance of material"; Real TC_920_921.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_920_921.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_920_921.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_920_921.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_920_921.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_920_921.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_920_921.G(quantity = "ThermalConductance", unit = "W/K") = 7.42847095487259e-05 "Constant thermal conductance of material"; Real TC_920_931.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_920_931.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_920_931.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_920_931.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_920_931.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_920_931.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_920_931.G(quantity = "ThermalConductance", unit = "W/K") = 1.38666968989474e-05 "Constant thermal conductance of material"; Real TC_920_1066.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_920_1066.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_920_1066.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_920_1066.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_920_1066.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_920_1066.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_920_1066.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173340439391248 "Constant thermal conductance of material"; Real TC_921_922.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_921_922.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_921_922.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_921_922.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_921_922.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_921_922.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_921_922.G(quantity = "ThermalConductance", unit = "W/K") = 5.19998618402872e-05 "Constant thermal conductance of material"; Real TC_921_932.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_921_932.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_921_932.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_921_932.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_921_932.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_921_932.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_921_932.G(quantity = "ThermalConductance", unit = "W/K") = 3.46663172606569e-05 "Constant thermal conductance of material"; Real TC_921_1067.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_921_1067.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_921_1067.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_921_1067.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_921_1067.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_921_1067.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_921_1067.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433336472770214 "Constant thermal conductance of material"; Real TC_922_923.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_922_923.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_922_923.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_922_923.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_922_923.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_922_923.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_922_923.G(quantity = "ThermalConductance", unit = "W/K") = 5.19999999999999e-05 "Constant thermal conductance of material"; Real TC_922_933.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_922_933.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_922_933.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_922_933.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_922_933.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_922_933.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_922_933.G(quantity = "ThermalConductance", unit = "W/K") = 3.46667103302605e-05 "Constant thermal conductance of material"; Real TC_922_1068.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_922_1068.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_922_1068.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_922_1068.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_922_1068.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_922_1068.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_922_1068.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433329989634534 "Constant thermal conductance of material"; Real TC_923_924.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_923_924.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_923_924.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_923_924.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_923_924.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_923_924.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_923_924.G(quantity = "ThermalConductance", unit = "W/K") = 5.19998712667359e-05 "Constant thermal conductance of material"; Real TC_923_934.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_923_934.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_923_934.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_923_934.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_923_934.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_923_934.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_923_934.G(quantity = "ThermalConductance", unit = "W/K") = 3.46666731442998e-05 "Constant thermal conductance of material"; Real TC_923_1069.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_923_1069.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_923_1069.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_923_1069.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_923_1069.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_923_1069.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_923_1069.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433331779528399 "Constant thermal conductance of material"; Real TC_924_925.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_924_925.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_924_925.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_924_925.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_924_925.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_924_925.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_924_925.G(quantity = "ThermalConductance", unit = "W/K") = 5.19948685054537e-05 "Constant thermal conductance of material"; Real TC_924_935.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_924_935.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_924_935.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_924_935.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_924_935.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_924_935.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_924_935.G(quantity = "ThermalConductance", unit = "W/K") = 3.46666025864382e-05 "Constant thermal conductance of material"; Real TC_924_1070.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_924_1070.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_924_1070.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_924_1070.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_924_1070.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_924_1070.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_924_1070.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433331325744648 "Constant thermal conductance of material"; Real TC_925_926.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_925_926.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_925_926.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_925_926.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_925_926.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_925_926.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_925_926.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000641231166e-05 "Constant thermal conductance of material"; Real TC_925_936.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_925_936.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_925_936.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_925_936.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_925_936.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_925_936.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_925_936.G(quantity = "ThermalConductance", unit = "W/K") = 3.46663226211779e-05 "Constant thermal conductance of material"; Real TC_925_1071.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_925_1071.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_925_1071.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_925_1071.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_925_1071.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_925_1071.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_925_1071.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433335576340757 "Constant thermal conductance of material"; Real TC_926_927.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_926_927.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_926_927.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_926_927.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_926_927.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_926_927.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_926_927.G(quantity = "ThermalConductance", unit = "W/K") = 5.20002349072111e-05 "Constant thermal conductance of material"; Real TC_926_937.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_926_937.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_926_937.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_926_937.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_926_937.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_926_937.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_926_937.G(quantity = "ThermalConductance", unit = "W/K") = 3.46663827473869e-05 "Constant thermal conductance of material"; Real TC_926_1072.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_926_1072.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_926_1072.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_926_1072.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_926_1072.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_926_1072.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_926_1072.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433333784405532 "Constant thermal conductance of material"; Real TC_927_928.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_927_928.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_927_928.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_927_928.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_927_928.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_927_928.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_927_928.G(quantity = "ThermalConductance", unit = "W/K") = 5.19983796921415e-05 "Constant thermal conductance of material"; Real TC_927_938.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_927_938.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_927_938.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_927_938.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_927_938.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_927_938.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_927_938.G(quantity = "ThermalConductance", unit = "W/K") = 3.46665101292738e-05 "Constant thermal conductance of material"; Real TC_927_1073.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_927_1073.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_927_1073.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_927_1073.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_927_1073.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_927_1073.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_927_1073.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433334916316714 "Constant thermal conductance of material"; Real TC_928_929.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_928_929.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_928_929.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_928_929.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_928_929.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_928_929.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_928_929.G(quantity = "ThermalConductance", unit = "W/K") = 5.1999809485253e-05 "Constant thermal conductance of material"; Real TC_928_939.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_928_939.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_928_939.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_928_939.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_928_939.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_928_939.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_928_939.G(quantity = "ThermalConductance", unit = "W/K") = 3.46668446164626e-05 "Constant thermal conductance of material"; Real TC_928_1074.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_928_1074.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_928_1074.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_928_1074.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_928_1074.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_928_1074.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_928_1074.G(quantity = "ThermalConductance", unit = "W/K") = 0.00043333197428684 "Constant thermal conductance of material"; Real TC_929_930.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_929_930.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_929_930.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_929_930.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_929_930.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_929_930.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_929_930.G(quantity = "ThermalConductance", unit = "W/K") = 7.42833439132157e-05 "Constant thermal conductance of material"; Real TC_929_940.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_929_940.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_929_940.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_929_940.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_929_940.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_929_940.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_929_940.G(quantity = "ThermalConductance", unit = "W/K") = 3.46668046653057e-05 "Constant thermal conductance of material"; Real TC_929_1075.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_929_1075.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_929_1075.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_929_1075.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_929_1075.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_929_1075.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_929_1075.G(quantity = "ThermalConductance", unit = "W/K") = 0.000433328225223844 "Constant thermal conductance of material"; Real TC_930_941.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_930_941.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_930_941.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_930_941.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_930_941.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_930_941.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_930_941.G(quantity = "ThermalConductance", unit = "W/K") = 1.38667170202891e-05 "Constant thermal conductance of material"; Real TC_930_1076.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_930_1076.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_930_1076.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_930_1076.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_930_1076.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_930_1076.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_930_1076.G(quantity = "ThermalConductance", unit = "W/K") = 0.000173335030117927 "Constant thermal conductance of material"; Real TC_931_932.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_931_932.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_931_932.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_931_932.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_931_932.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_931_932.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_931_932.G(quantity = "ThermalConductance", unit = "W/K") = 0.000148574572438826 "Constant thermal conductance of material"; Real TC_931_942.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_931_942.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_931_942.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_931_942.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_931_942.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_931_942.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_931_942.G(quantity = "ThermalConductance", unit = "W/K") = 1.22351332877649e-05 "Constant thermal conductance of material"; Real TC_931_1077.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_931_1077.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_931_1077.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_931_1077.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_931_1077.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_931_1077.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_931_1077.G(quantity = "ThermalConductance", unit = "W/K") = 0.000346679375151926 "Constant thermal conductance of material"; Real TC_932_933.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_932_933.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_932_933.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_932_933.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_932_933.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_932_933.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_932_933.G(quantity = "ThermalConductance", unit = "W/K") = 0.000104002054844786 "Constant thermal conductance of material"; Real TC_932_943.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_932_943.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_932_943.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_932_943.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_932_943.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_932_943.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_932_943.G(quantity = "ThermalConductance", unit = "W/K") = 3.05881027489861e-05 "Constant thermal conductance of material"; Real TC_932_1078.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_932_1078.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_932_1078.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_932_1078.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_932_1078.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_932_1078.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_932_1078.G(quantity = "ThermalConductance", unit = "W/K") = 0.000866667461628565 "Constant thermal conductance of material"; Real TC_933_934.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_933_934.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_933_934.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_933_934.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_933_934.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_933_934.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_933_934.G(quantity = "ThermalConductance", unit = "W/K") = 0.000103999272859481 "Constant thermal conductance of material"; Real TC_933_944.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_933_944.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_933_944.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_933_944.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_933_944.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_933_944.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_933_944.G(quantity = "ThermalConductance", unit = "W/K") = 3.05880234016918e-05 "Constant thermal conductance of material"; Real TC_933_1079.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_933_1079.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_933_1079.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_933_1079.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_933_1079.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_933_1079.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_933_1079.G(quantity = "ThermalConductance", unit = "W/K") = 0.00086666910987608 "Constant thermal conductance of material"; Real TC_934_935.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_934_935.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_934_935.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_934_935.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_934_935.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_934_935.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_934_935.G(quantity = "ThermalConductance", unit = "W/K") = 0.000103999723680574 "Constant thermal conductance of material"; Real TC_934_945.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_934_945.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_934_945.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_934_945.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_934_945.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_934_945.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_934_945.G(quantity = "ThermalConductance", unit = "W/K") = 3.05883439122909e-05 "Constant thermal conductance of material"; Real TC_934_1080.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_934_1080.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_934_1080.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_934_1080.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_934_1080.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_934_1080.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_934_1080.G(quantity = "ThermalConductance", unit = "W/K") = 0.000866667480935921 "Constant thermal conductance of material"; Real TC_935_936.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_935_936.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_935_936.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_935_936.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_935_936.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_935_936.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_935_936.G(quantity = "ThermalConductance", unit = "W/K") = 0.000103980620155052 "Constant thermal conductance of material"; Real TC_935_946.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_935_946.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_935_946.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_935_946.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_935_946.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_935_946.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_935_946.G(quantity = "ThermalConductance", unit = "W/K") = 3.05883278416537e-05 "Constant thermal conductance of material"; Real TC_935_1081.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_935_1081.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_935_1081.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_935_1081.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_935_1081.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_935_1081.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_935_1081.G(quantity = "ThermalConductance", unit = "W/K") = 0.000866671840641573 "Constant thermal conductance of material"; Real TC_936_937.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_936_937.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_936_937.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_936_937.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_936_937.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_936_937.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_936_937.G(quantity = "ThermalConductance", unit = "W/K") = 0.000103994144709328 "Constant thermal conductance of material"; Real TC_936_947.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_936_947.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_936_947.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_936_947.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_936_947.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_936_947.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_936_947.G(quantity = "ThermalConductance", unit = "W/K") = 3.05883889954686e-05 "Constant thermal conductance of material"; Real TC_936_1082.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_936_1082.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_936_1082.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_936_1082.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_936_1082.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_936_1082.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_936_1082.G(quantity = "ThermalConductance", unit = "W/K") = 0.000866670772841205 "Constant thermal conductance of material"; Real TC_937_938.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_937_938.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_937_938.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_937_938.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_937_938.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_937_938.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_937_938.G(quantity = "ThermalConductance", unit = "W/K") = 0.000104003567535426 "Constant thermal conductance of material"; Real TC_937_948.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_937_948.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_937_948.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_937_948.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_937_948.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_937_948.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_937_948.G(quantity = "ThermalConductance", unit = "W/K") = 3.05874734148905e-05 "Constant thermal conductance of material"; Real TC_937_1083.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_937_1083.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_937_1083.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_937_1083.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_937_1083.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_937_1083.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_937_1083.G(quantity = "ThermalConductance", unit = "W/K") = 0.000866669465376462 "Constant thermal conductance of material"; Real TC_938_939.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_938_939.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_938_939.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_938_939.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_938_939.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_938_939.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_938_939.G(quantity = "ThermalConductance", unit = "W/K") = 0.000103997899094757 "Constant thermal conductance of material"; Real TC_938_949.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_938_949.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_938_949.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_938_949.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_938_949.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_938_949.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_938_949.G(quantity = "ThermalConductance", unit = "W/K") = 3.0587976467286e-05 "Constant thermal conductance of material"; Real TC_938_1084.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_938_1084.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_938_1084.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_938_1084.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_938_1084.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_938_1084.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_938_1084.G(quantity = "ThermalConductance", unit = "W/K") = 0.000866662830177821 "Constant thermal conductance of material"; Real TC_939_940.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_939_940.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_939_940.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_939_940.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_939_940.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_939_940.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_939_940.G(quantity = "ThermalConductance", unit = "W/K") = 0.000103999654404187 "Constant thermal conductance of material"; Real TC_939_950.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_939_950.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_939_950.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_939_950.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_939_950.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_939_950.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_939_950.G(quantity = "ThermalConductance", unit = "W/K") = 3.05879986022723e-05 "Constant thermal conductance of material"; Real TC_939_1085.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_939_1085.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_939_1085.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_939_1085.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_939_1085.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_939_1085.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_939_1085.G(quantity = "ThermalConductance", unit = "W/K") = 0.000866666259049109 "Constant thermal conductance of material"; Real TC_940_941.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_940_941.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_940_941.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_940_941.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_940_941.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_940_941.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_940_941.G(quantity = "ThermalConductance", unit = "W/K") = 0.000148577181057496 "Constant thermal conductance of material"; Real TC_940_951.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_940_951.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_940_951.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_940_951.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_940_951.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_940_951.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_940_951.G(quantity = "ThermalConductance", unit = "W/K") = 3.05880719294591e-05 "Constant thermal conductance of material"; Real TC_940_1086.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_940_1086.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_940_1086.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_940_1086.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_940_1086.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_940_1086.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_940_1086.G(quantity = "ThermalConductance", unit = "W/K") = 0.00086666660370391 "Constant thermal conductance of material"; Real TC_941_952.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_941_952.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_941_952.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_941_952.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_941_952.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_941_952.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_941_952.G(quantity = "ThermalConductance", unit = "W/K") = 1.22350920978253e-05 "Constant thermal conductance of material"; Real TC_941_1087.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_941_1087.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_941_1087.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_941_1087.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_941_1087.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_941_1087.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_941_1087.G(quantity = "ThermalConductance", unit = "W/K") = 0.000346663667475377 "Constant thermal conductance of material"; Real TC_942_943.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_942_943.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_942_943.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_942_943.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_942_943.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_942_943.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_942_943.G(quantity = "ThermalConductance", unit = "W/K") = 0.000104000404753726 "Constant thermal conductance of material"; Real TC_942_953.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_942_953.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_942_953.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_942_953.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_942_953.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_942_953.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_942_953.G(quantity = "ThermalConductance", unit = "W/K") = 1.48569672760791e-05 "Constant thermal conductance of material"; Real TC_942_1088.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_942_1088.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_942_1088.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_942_1088.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_942_1088.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_942_1088.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_942_1088.G(quantity = "ThermalConductance", unit = "W/K") = 0.000242666048190958 "Constant thermal conductance of material"; Real TC_943_944.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_943_944.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_943_944.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_943_944.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_943_944.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_943_944.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_943_944.G(quantity = "ThermalConductance", unit = "W/K") = 7.27989968127904e-05 "Constant thermal conductance of material"; Real TC_943_954.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_943_954.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_943_954.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_943_954.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_943_954.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_943_954.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_943_954.G(quantity = "ThermalConductance", unit = "W/K") = 3.71436548065888e-05 "Constant thermal conductance of material"; Real TC_943_1089.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_943_1089.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_943_1089.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_943_1089.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_943_1089.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_943_1089.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_943_1089.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606662365988945 "Constant thermal conductance of material"; Real TC_944_945.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_944_945.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_944_945.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_944_945.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_944_945.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_944_945.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_944_945.G(quantity = "ThermalConductance", unit = "W/K") = 7.2799657534247e-05 "Constant thermal conductance of material"; Real TC_944_955.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_944_955.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_944_955.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_944_955.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_944_955.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_944_955.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_944_955.G(quantity = "ThermalConductance", unit = "W/K") = 3.71444171444176e-05 "Constant thermal conductance of material"; Real TC_944_1090.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_944_1090.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_944_1090.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_944_1090.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_944_1090.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_944_1090.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_944_1090.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606664216460211 "Constant thermal conductance of material"; Real TC_945_946.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_945_946.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_945_946.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_945_946.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_945_946.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_945_946.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_945_946.G(quantity = "ThermalConductance", unit = "W/K") = 7.28008007361607e-05 "Constant thermal conductance of material"; Real TC_945_956.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_945_956.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_945_956.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_945_956.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_945_956.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_945_956.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_945_956.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430520189157e-05 "Constant thermal conductance of material"; Real TC_945_1091.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_945_1091.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_945_1091.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_945_1091.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_945_1091.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_945_1091.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_945_1091.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606670261749699 "Constant thermal conductance of material"; Real TC_946_947.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_946_947.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_946_947.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_946_947.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_946_947.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_946_947.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_946_947.G(quantity = "ThermalConductance", unit = "W/K") = 7.27986225123134e-05 "Constant thermal conductance of material"; Real TC_946_957.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_946_957.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_946_957.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_946_957.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_946_957.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_946_957.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_946_957.G(quantity = "ThermalConductance", unit = "W/K") = 3.71423756740561e-05 "Constant thermal conductance of material"; Real TC_946_1635.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_946_1635.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_946_1635.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_946_1635.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_946_1635.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_946_1635.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_946_1635.G(quantity = "ThermalConductance", unit = "W/K") = 0.000907645325202073 "Constant thermal conductance of material"; Real TC_947_948.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_947_948.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_947_948.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_947_948.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_947_948.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_947_948.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_947_948.G(quantity = "ThermalConductance", unit = "W/K") = 7.27996375873683e-05 "Constant thermal conductance of material"; Real TC_947_958.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_947_958.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_947_958.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_947_958.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_947_958.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_947_958.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_947_958.G(quantity = "ThermalConductance", unit = "W/K") = 3.71420935412026e-05 "Constant thermal conductance of material"; Real TC_947_1636.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_947_1636.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_947_1636.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_947_1636.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_947_1636.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_947_1636.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_947_1636.G(quantity = "ThermalConductance", unit = "W/K") = 0.000907638644979229 "Constant thermal conductance of material"; Real TC_948_949.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_948_949.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_948_949.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_948_949.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_948_949.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_948_949.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_948_949.G(quantity = "ThermalConductance", unit = "W/K") = 7.28000821439571e-05 "Constant thermal conductance of material"; Real TC_948_959.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_948_959.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_948_959.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_948_959.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_948_959.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_948_959.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_948_959.G(quantity = "ThermalConductance", unit = "W/K") = 3.71438530830901e-05 "Constant thermal conductance of material"; Real TC_948_1637.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_948_1637.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_948_1637.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_948_1637.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_948_1637.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_948_1637.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_948_1637.G(quantity = "ThermalConductance", unit = "W/K") = 0.000907645547671065 "Constant thermal conductance of material"; Real TC_949_950.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_949_950.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_949_950.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_949_950.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_949_950.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_949_950.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_949_950.G(quantity = "ThermalConductance", unit = "W/K") = 7.27993014521659e-05 "Constant thermal conductance of material"; Real TC_949_960.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_949_960.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_949_960.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_949_960.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_949_960.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_949_960.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_949_960.G(quantity = "ThermalConductance", unit = "W/K") = 3.71437198067633e-05 "Constant thermal conductance of material"; Real TC_949_1638.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_949_1638.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_949_1638.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_949_1638.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_949_1638.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_949_1638.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_949_1638.G(quantity = "ThermalConductance", unit = "W/K") = 0.000907637365063115 "Constant thermal conductance of material"; Real TC_950_951.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_950_951.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_950_951.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_950_951.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_950_951.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_950_951.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_950_951.G(quantity = "ThermalConductance", unit = "W/K") = 7.2798194183298e-05 "Constant thermal conductance of material"; Real TC_950_961.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_950_961.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_950_961.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_950_961.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_950_961.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_950_961.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_950_961.G(quantity = "ThermalConductance", unit = "W/K") = 3.71437025347666e-05 "Constant thermal conductance of material"; Real TC_950_1092.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_950_1092.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_950_1092.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_950_1092.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_950_1092.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_950_1092.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_950_1092.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606663146614623 "Constant thermal conductance of material"; Real TC_951_952.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_951_952.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_951_952.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_951_952.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_951_952.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_951_952.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_951_952.G(quantity = "ThermalConductance", unit = "W/K") = 0.000103999438591462 "Constant thermal conductance of material"; Real TC_951_962.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_951_962.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_951_962.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_951_962.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_951_962.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_951_962.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_951_962.G(quantity = "ThermalConductance", unit = "W/K") = 3.71431657979307e-05 "Constant thermal conductance of material"; Real TC_951_1093.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_951_1093.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_951_1093.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_951_1093.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_951_1093.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_951_1093.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_951_1093.G(quantity = "ThermalConductance", unit = "W/K") = 0.00060666484786237 "Constant thermal conductance of material"; Real TC_952_963.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_952_963.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_952_963.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_952_963.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_952_963.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_952_963.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_952_963.G(quantity = "ThermalConductance", unit = "W/K") = 1.48572510572048e-05 "Constant thermal conductance of material"; Real TC_952_1094.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_952_1094.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_952_1094.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_952_1094.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_952_1094.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_952_1094.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_952_1094.G(quantity = "ThermalConductance", unit = "W/K") = 0.000242667589774106 "Constant thermal conductance of material"; Real TC_953_954.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_953_954.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_953_954.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_953_954.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_953_954.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_953_954.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_953_954.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010400044754291 "Constant thermal conductance of material"; Real TC_953_964.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_953_964.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_953_964.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_953_964.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_953_964.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_953_964.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_953_964.G(quantity = "ThermalConductance", unit = "W/K") = 1.48576369925363e-05 "Constant thermal conductance of material"; Real TC_953_1095.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_953_1095.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_953_1095.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_953_1095.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_953_1095.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_953_1095.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_953_1095.G(quantity = "ThermalConductance", unit = "W/K") = 0.000242667157029276 "Constant thermal conductance of material"; Real TC_954_955.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_954_955.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_954_955.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_954_955.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_954_955.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_954_955.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_954_955.G(quantity = "ThermalConductance", unit = "W/K") = 7.27999877415301e-05 "Constant thermal conductance of material"; Real TC_954_965.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_954_965.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_954_965.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_954_965.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_954_965.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_954_965.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_954_965.G(quantity = "ThermalConductance", unit = "W/K") = 3.71571753986266e-05 "Constant thermal conductance of material"; Real TC_954_1096.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_954_1096.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_954_1096.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_954_1096.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_954_1096.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_954_1096.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_954_1096.G(quantity = "ThermalConductance", unit = "W/K") = 0.00060666437322019 "Constant thermal conductance of material"; Real TC_955_956.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_955_956.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_955_956.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_955_956.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_955_956.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_955_956.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_955_956.G(quantity = "ThermalConductance", unit = "W/K") = 7.27999359852053e-05 "Constant thermal conductance of material"; Real TC_955_966.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_955_966.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_955_966.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_955_966.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_955_966.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_955_966.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_955_966.G(quantity = "ThermalConductance", unit = "W/K") = 3.71538857436956e-05 "Constant thermal conductance of material"; Real TC_955_1097.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_955_1097.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_955_1097.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_955_1097.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_955_1097.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_955_1097.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_955_1097.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606666930121404 "Constant thermal conductance of material"; Real TC_956_957.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_956_957.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_956_957.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_956_957.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_956_957.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_956_957.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_956_957.G(quantity = "ThermalConductance", unit = "W/K") = 7.28006045942868e-05 "Constant thermal conductance of material"; Real TC_956_967.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_956_967.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_956_967.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_956_967.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_956_967.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_956_967.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_956_967.G(quantity = "ThermalConductance", unit = "W/K") = 3.71441213653585e-05 "Constant thermal conductance of material"; Real TC_956_1098.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_956_1098.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_956_1098.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_956_1098.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_956_1098.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_956_1098.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_956_1098.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606664222171571 "Constant thermal conductance of material"; Real TC_957_958.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_957_958.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_957_958.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_957_958.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_957_958.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_957_958.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_957_958.G(quantity = "ThermalConductance", unit = "W/K") = 7.27988443481407e-05 "Constant thermal conductance of material"; Real TC_957_968.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_957_968.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_957_968.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_957_968.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_957_968.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_957_968.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_957_968.G(quantity = "ThermalConductance", unit = "W/K") = 3.71431809167656e-05 "Constant thermal conductance of material"; Real TC_957_1639.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_957_1639.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_957_1639.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_957_1639.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_957_1639.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_957_1639.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_957_1639.G(quantity = "ThermalConductance", unit = "W/K") = 0.000907641591969639 "Constant thermal conductance of material"; Real TC_958_959.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_958_959.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_958_959.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_958_959.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_958_959.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_958_959.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_958_959.G(quantity = "ThermalConductance", unit = "W/K") = 7.27999508025349e-05 "Constant thermal conductance of material"; Real TC_958_969.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_958_969.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_958_969.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_958_969.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_958_969.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_958_969.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_958_969.G(quantity = "ThermalConductance", unit = "W/K") = 3.71412797728585e-05 "Constant thermal conductance of material"; Real TC_958_1640.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_958_1640.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_958_1640.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_958_1640.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_958_1640.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_958_1640.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_958_1640.G(quantity = "ThermalConductance", unit = "W/K") = 0.000907636014008658 "Constant thermal conductance of material"; Real TC_959_960.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_959_960.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_959_960.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_959_960.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_959_960.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_959_960.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_959_960.G(quantity = "ThermalConductance", unit = "W/K") = 7.27999999999996e-05 "Constant thermal conductance of material"; Real TC_959_970.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_959_970.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_959_970.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_959_970.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_959_970.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_959_970.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_959_970.G(quantity = "ThermalConductance", unit = "W/K") = 3.71425869894087e-05 "Constant thermal conductance of material"; Real TC_959_1641.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_959_1641.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_959_1641.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_959_1641.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_959_1641.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_959_1641.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_959_1641.G(quantity = "ThermalConductance", unit = "W/K") = 0.000907638024602485 "Constant thermal conductance of material"; Real TC_960_961.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_960_961.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_960_961.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_960_961.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_960_961.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_960_961.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_960_961.G(quantity = "ThermalConductance", unit = "W/K") = 7.27987657854777e-05 "Constant thermal conductance of material"; Real TC_960_971.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_960_971.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_960_971.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_960_971.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_960_971.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_960_971.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_960_971.G(quantity = "ThermalConductance", unit = "W/K") = 3.71444753372462e-05 "Constant thermal conductance of material"; Real TC_960_1642.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_960_1642.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_960_1642.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_960_1642.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_960_1642.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_960_1642.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_960_1642.G(quantity = "ThermalConductance", unit = "W/K") = 0.00090763503254924 "Constant thermal conductance of material"; Real TC_961_962.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_961_962.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_961_962.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_961_962.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_961_962.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_961_962.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_961_962.G(quantity = "ThermalConductance", unit = "W/K") = 7.27986464907611e-05 "Constant thermal conductance of material"; Real TC_961_972.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_961_972.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_961_972.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_961_972.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_961_972.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_961_972.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_961_972.G(quantity = "ThermalConductance", unit = "W/K") = 3.71373119844775e-05 "Constant thermal conductance of material"; Real TC_961_1028.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_961_1028.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_961_1028.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_961_1028.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_961_1028.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_961_1028.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_961_1028.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606669431135431 "Constant thermal conductance of material"; Real TC_962_963.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_962_963.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_962_963.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_962_963.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_962_963.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_962_963.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_962_963.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010400006067593 "Constant thermal conductance of material"; Real TC_962_973.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_962_973.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_962_973.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_962_973.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_962_973.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_962_973.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_962_973.G(quantity = "ThermalConductance", unit = "W/K") = 3.71414484496571e-05 "Constant thermal conductance of material"; Real TC_962_1029.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_962_1029.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_962_1029.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_962_1029.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_962_1029.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_962_1029.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_962_1029.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606662270196789 "Constant thermal conductance of material"; Real TC_963_974.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_963_974.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_963_974.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_963_974.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_963_974.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_963_974.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_963_974.G(quantity = "ThermalConductance", unit = "W/K") = 1.48568281938323e-05 "Constant thermal conductance of material"; Real TC_963_1030.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_963_1030.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_963_1030.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_963_1030.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_963_1030.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_963_1030.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_963_1030.G(quantity = "ThermalConductance", unit = "W/K") = 0.000242666205751429 "Constant thermal conductance of material"; Real TC_964_965.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_964_965.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_964_965.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_964_965.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_964_965.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_964_965.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_964_965.G(quantity = "ThermalConductance", unit = "W/K") = 0.000103999978581822 "Constant thermal conductance of material"; Real TC_964_1031.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_964_1031.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_964_1031.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_964_1031.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_964_1031.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_964_1031.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_964_1031.G(quantity = "ThermalConductance", unit = "W/K") = 0.000242665868054256 "Constant thermal conductance of material"; Real TC_965_966.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_965_966.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_965_966.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_965_966.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_965_966.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_965_966.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_965_966.G(quantity = "ThermalConductance", unit = "W/K") = 7.28014826846589e-05 "Constant thermal conductance of material"; Real TC_965_1032.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_965_1032.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_965_1032.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_965_1032.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_965_1032.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_965_1032.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_965_1032.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606670935779254 "Constant thermal conductance of material"; Real TC_966_967.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_966_967.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_966_967.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_966_967.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_966_967.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_966_967.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_966_967.G(quantity = "ThermalConductance", unit = "W/K") = 7.27999098650794e-05 "Constant thermal conductance of material"; Real TC_966_1033.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_966_1033.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_966_1033.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_966_1033.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_966_1033.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_966_1033.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_966_1033.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606664170878743 "Constant thermal conductance of material"; Real TC_967_968.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_967_968.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_967_968.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_967_968.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_967_968.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_967_968.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_967_968.G(quantity = "ThermalConductance", unit = "W/K") = 7.28006182962921e-05 "Constant thermal conductance of material"; Real TC_967_1034.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_967_1034.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_967_1034.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_967_1034.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_967_1034.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_967_1034.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_967_1034.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606663143524023 "Constant thermal conductance of material"; Real TC_968_969.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_968_969.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_968_969.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_968_969.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_968_969.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_968_969.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_968_969.G(quantity = "ThermalConductance", unit = "W/K") = 7.28001519756845e-05 "Constant thermal conductance of material"; Real TC_968_1643.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_968_1643.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_968_1643.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_968_1643.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_968_1643.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_968_1643.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_968_1643.G(quantity = "ThermalConductance", unit = "W/K") = 0.000907634810464495 "Constant thermal conductance of material"; Real TC_969_970.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_969_970.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_969_970.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_969_970.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_969_970.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_969_970.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_969_970.G(quantity = "ThermalConductance", unit = "W/K") = 7.27994006878472e-05 "Constant thermal conductance of material"; Real TC_969_1644.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_969_1644.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_969_1644.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_969_1644.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_969_1644.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_969_1644.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_969_1644.G(quantity = "ThermalConductance", unit = "W/K") = 0.000907635091970076 "Constant thermal conductance of material"; Real TC_970_971.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_970_971.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_970_971.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_970_971.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_970_971.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_970_971.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_970_971.G(quantity = "ThermalConductance", unit = "W/K") = 7.28005744461233e-05 "Constant thermal conductance of material"; Real TC_970_1645.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_970_1645.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_970_1645.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_970_1645.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_970_1645.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_970_1645.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_970_1645.G(quantity = "ThermalConductance", unit = "W/K") = 0.000907640632886939 "Constant thermal conductance of material"; Real TC_971_972.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_971_972.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_971_972.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_971_972.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_971_972.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_971_972.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_971_972.G(quantity = "ThermalConductance", unit = "W/K") = 7.27987335008016e-05 "Constant thermal conductance of material"; Real TC_971_1646.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_971_1646.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_971_1646.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_971_1646.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_971_1646.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_971_1646.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_971_1646.G(quantity = "ThermalConductance", unit = "W/K") = 0.000907638280886329 "Constant thermal conductance of material"; Real TC_972_973.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_972_973.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_972_973.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_972_973.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_972_973.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_972_973.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_972_973.G(quantity = "ThermalConductance", unit = "W/K") = 7.28005901155642e-05 "Constant thermal conductance of material"; Real TC_972_1035.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_972_1035.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_972_1035.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_972_1035.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_972_1035.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_972_1035.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_972_1035.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606662754571373 "Constant thermal conductance of material"; Real TC_973_974.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_973_974.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_973_974.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_973_974.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_973_974.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_973_974.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_973_974.G(quantity = "ThermalConductance", unit = "W/K") = 0.000104000476519938 "Constant thermal conductance of material"; Real TC_973_1036.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_973_1036.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_973_1036.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_973_1036.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_973_1036.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_973_1036.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_973_1036.G(quantity = "ThermalConductance", unit = "W/K") = 0.000606669422264353 "Constant thermal conductance of material"; Real TC_974_1037.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_974_1037.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_974_1037.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_974_1037.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_974_1037.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_974_1037.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_974_1037.G(quantity = "ThermalConductance", unit = "W/K") = 0.000242667613508274 "Constant thermal conductance of material"; Real TC_975_976.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_975_976.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_975_976.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_975_976.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_975_976.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_975_976.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_975_976.G(quantity = "ThermalConductance", unit = "W/K") = 3.71425413245027e-05 "Constant thermal conductance of material"; Real TC_975_983.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_975_983.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_975_983.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_975_983.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_975_983.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_975_983.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_975_983.G(quantity = "ThermalConductance", unit = "W/K") = 2.5993614757004e-05 "Constant thermal conductance of material"; Real TC_975_1058.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_975_1058.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_975_1058.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_975_1058.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_975_1058.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_975_1058.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_975_1058.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003009781789e-05 "Constant thermal conductance of material"; Real TC_975_1598.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_975_1598.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_975_1598.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_975_1598.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_975_1598.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_975_1598.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_975_1598.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012991548908687 "Constant thermal conductance of material"; Real TC_975_1649.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_975_1649.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_975_1649.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_975_1649.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_975_1649.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_975_1649.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_975_1649.G(quantity = "ThermalConductance", unit = "W/K") = 5.17303965928903e-05 "Constant thermal conductance of material"; Real TC_976_984.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_976_984.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_976_984.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_976_984.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_976_984.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_976_984.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_976_984.G(quantity = "ThermalConductance", unit = "W/K") = 1.03964809384179e-05 "Constant thermal conductance of material"; Real TC_976_1059.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_976_1059.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_976_1059.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_976_1059.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_976_1059.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_976_1059.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_976_1059.G(quantity = "ThermalConductance", unit = "W/K") = 1.04002301643117e-05 "Constant thermal conductance of material"; Real TC_976_1123.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_976_1123.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_976_1123.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_976_1123.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_976_1123.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_976_1123.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_976_1123.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260000776005897 "Constant thermal conductance of material"; Real TC_977_978.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_977_978.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_977_978.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_977_978.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_977_978.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_977_978.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_977_978.G(quantity = "ThermalConductance", unit = "W/K") = 3.71431753566829e-05 "Constant thermal conductance of material"; Real TC_977_985.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_977_985.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_977_985.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_977_985.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_977_985.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_977_985.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_977_985.G(quantity = "ThermalConductance", unit = "W/K") = 1.04001474442988e-05 "Constant thermal conductance of material"; Real TC_977_1060.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_977_1060.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_977_1060.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_977_1060.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_977_1060.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_977_1060.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_977_1060.G(quantity = "ThermalConductance", unit = "W/K") = 1.04001615001571e-05 "Constant thermal conductance of material"; Real TC_977_1124.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_977_1124.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_977_1124.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_977_1124.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_977_1124.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_977_1124.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_977_1124.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259999603936867 "Constant thermal conductance of material"; Real TC_978_979.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_978_979.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_978_979.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_978_979.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_978_979.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_978_979.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_978_979.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001576085528e-05 "Constant thermal conductance of material"; Real TC_978_986.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_978_986.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_978_986.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_978_986.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_978_986.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_978_986.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_978_986.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004884153972e-05 "Constant thermal conductance of material"; Real TC_978_1061.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_978_1061.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_978_1061.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_978_1061.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_978_1061.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_978_1061.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_978_1061.G(quantity = "ThermalConductance", unit = "W/K") = 2.59994414727932e-05 "Constant thermal conductance of material"; Real TC_978_1599.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_978_1599.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_978_1599.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_978_1599.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_978_1599.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_978_1599.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_978_1599.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916521659142 "Constant thermal conductance of material"; Real TC_979_980.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_979_980.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_979_980.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_979_980.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_979_980.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_979_980.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_979_980.G(quantity = "ThermalConductance", unit = "W/K") = 2.60015866719561e-05 "Constant thermal conductance of material"; Real TC_979_1062.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_979_1062.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_979_1062.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_979_1062.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_979_1062.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_979_1062.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_979_1062.G(quantity = "ThermalConductance", unit = "W/K") = 2.59994736149493e-05 "Constant thermal conductance of material"; Real TC_979_1600.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_979_1600.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_979_1600.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_979_1600.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_979_1600.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_979_1600.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_979_1600.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916709049717 "Constant thermal conductance of material"; Real TC_979_1656.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_979_1656.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_979_1656.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_979_1656.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_979_1656.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_979_1656.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_979_1656.G(quantity = "ThermalConductance", unit = "W/K") = 5.1730116997179e-05 "Constant thermal conductance of material"; Real TC_980_981.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_980_981.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_980_981.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_980_981.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_980_981.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_980_981.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_980_981.G(quantity = "ThermalConductance", unit = "W/K") = 2.60033780217464e-05 "Constant thermal conductance of material"; Real TC_980_1063.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_980_1063.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_980_1063.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_980_1063.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_980_1063.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_980_1063.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_980_1063.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002032158915e-05 "Constant thermal conductance of material"; Real TC_980_1601.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_980_1601.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_980_1601.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_980_1601.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_980_1601.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_980_1601.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_980_1601.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129913976346079 "Constant thermal conductance of material"; Real TC_980_1657.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_980_1657.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_980_1657.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_980_1657.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_980_1657.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_980_1657.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_980_1657.G(quantity = "ThermalConductance", unit = "W/K") = 5.17313759253905e-05 "Constant thermal conductance of material"; Real TC_981_982.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_981_982.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_981_982.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_981_982.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_981_982.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_981_982.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_981_982.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997039011026e-05 "Constant thermal conductance of material"; Real TC_981_1064.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_981_1064.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_981_1064.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_981_1064.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_981_1064.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_981_1064.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_981_1064.G(quantity = "ThermalConductance", unit = "W/K") = 2.59992982250944e-05 "Constant thermal conductance of material"; Real TC_981_1602.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_981_1602.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_981_1602.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_981_1602.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_981_1602.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_981_1602.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_981_1602.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129914673498387 "Constant thermal conductance of material"; Real TC_981_1658.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_981_1658.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_981_1658.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_981_1658.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_981_1658.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_981_1658.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_981_1658.G(quantity = "ThermalConductance", unit = "W/K") = 5.17318761269597e-05 "Constant thermal conductance of material"; Real TC_982_987.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_982_987.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_982_987.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_982_987.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_982_987.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_982_987.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_982_987.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002924119107e-05 "Constant thermal conductance of material"; Real TC_982_1065.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_982_1065.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_982_1065.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_982_1065.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_982_1065.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_982_1065.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_982_1065.G(quantity = "ThermalConductance", unit = "W/K") = 2.59995168498613e-05 "Constant thermal conductance of material"; Real TC_982_1603.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_982_1603.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_982_1603.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_982_1603.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_982_1603.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_982_1603.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_982_1603.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129914736995877 "Constant thermal conductance of material"; Real TC_982_1650.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_982_1650.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_982_1650.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_982_1650.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_982_1650.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_982_1650.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_982_1650.G(quantity = "ThermalConductance", unit = "W/K") = 5.17298822066085e-05 "Constant thermal conductance of material"; Real TC_983_984.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_983_984.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_983_984.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_983_984.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_983_984.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_983_984.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_983_984.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430192997365e-05 "Constant thermal conductance of material"; Real TC_983_988.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_983_988.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_983_988.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_983_988.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_983_988.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_983_988.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_983_988.G(quantity = "ThermalConductance", unit = "W/K") = 2.59990218986035e-05 "Constant thermal conductance of material"; Real TC_983_1607.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_983_1607.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_983_1607.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_983_1607.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_983_1607.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_983_1607.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_983_1607.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129914392138124 "Constant thermal conductance of material"; Real TC_983_1652.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_983_1652.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_983_1652.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_983_1652.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_983_1652.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_983_1652.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_983_1652.G(quantity = "ThermalConductance", unit = "W/K") = 5.17311754441463e-05 "Constant thermal conductance of material"; Real TC_984_989.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_984_989.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_984_989.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_984_989.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_984_989.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_984_989.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_984_989.G(quantity = "ThermalConductance", unit = "W/K") = 1.03997993838218e-05 "Constant thermal conductance of material"; Real TC_984_1125.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_984_1125.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_984_1125.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_984_1125.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_984_1125.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_984_1125.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_984_1125.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001838768308 "Constant thermal conductance of material"; Real TC_985_986.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_985_986.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_985_986.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_985_986.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_985_986.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_985_986.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_985_986.G(quantity = "ThermalConductance", unit = "W/K") = 3.71427477194729e-05 "Constant thermal conductance of material"; Real TC_985_990.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_985_990.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_985_990.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_985_990.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_985_990.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_985_990.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_985_990.G(quantity = "ThermalConductance", unit = "W/K") = 1.03932411674311e-05 "Constant thermal conductance of material"; Real TC_985_1126.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_985_1126.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_985_1126.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_985_1126.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_985_1126.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_985_1126.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_985_1126.G(quantity = "ThermalConductance", unit = "W/K") = 0.00025999841828463 "Constant thermal conductance of material"; Real TC_986_991.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_986_991.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_986_991.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_986_991.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_986_991.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_986_991.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_986_991.G(quantity = "ThermalConductance", unit = "W/K") = 2.59992280972594e-05 "Constant thermal conductance of material"; Real TC_986_1527.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_986_1527.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_986_1527.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_986_1527.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_986_1527.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_986_1527.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_986_1527.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916251457649 "Constant thermal conductance of material"; Real TC_986_1656.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_986_1656.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_986_1656.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_986_1656.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_986_1656.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_986_1656.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_986_1656.G(quantity = "ThermalConductance", unit = "W/K") = 5.1730803022316e-05 "Constant thermal conductance of material"; Real TC_987_992.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_987_992.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_987_992.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_987_992.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_987_992.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_987_992.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_987_992.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000945045599e-05 "Constant thermal conductance of material"; Real TC_987_1531.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_987_1531.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_987_1531.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_987_1531.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_987_1531.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_987_1531.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_987_1531.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915168728278 "Constant thermal conductance of material"; Real TC_987_1653.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_987_1653.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_987_1653.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_987_1653.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_987_1653.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_987_1653.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_987_1653.G(quantity = "ThermalConductance", unit = "W/K") = 5.17302539073352e-05 "Constant thermal conductance of material"; Real TC_987_1658.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_987_1658.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_987_1658.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_987_1658.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_987_1658.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_987_1658.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_987_1658.G(quantity = "ThermalConductance", unit = "W/K") = 5.17299166446403e-05 "Constant thermal conductance of material"; Real TC_988_989.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_988_989.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_988_989.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_988_989.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_988_989.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_988_989.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_988_989.G(quantity = "ThermalConductance", unit = "W/K") = 3.71431253972969e-05 "Constant thermal conductance of material"; Real TC_988_996.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_988_996.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_988_996.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_988_996.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_988_996.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_988_996.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_988_996.G(quantity = "ThermalConductance", unit = "W/K") = 2.59989893492962e-05 "Constant thermal conductance of material"; Real TC_988_1535.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_988_1535.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_988_1535.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_988_1535.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_988_1535.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_988_1535.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_988_1535.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916735144205 "Constant thermal conductance of material"; Real TC_988_1655.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_988_1655.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_988_1655.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_988_1655.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_988_1655.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_988_1655.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_988_1655.G(quantity = "ThermalConductance", unit = "W/K") = 5.17308579012664e-05 "Constant thermal conductance of material"; Real TC_989_997.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_989_997.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_989_997.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_989_997.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_989_997.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_989_997.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_989_997.G(quantity = "ThermalConductance", unit = "W/K") = 1.04002668445631e-05 "Constant thermal conductance of material"; Real TC_989_1127.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_989_1127.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_989_1127.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_989_1127.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_989_1127.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_989_1127.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_989_1127.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260000495994841 "Constant thermal conductance of material"; Real TC_990_991.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_990_991.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_990_991.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_990_991.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_990_991.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_990_991.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_990_991.G(quantity = "ThermalConductance", unit = "W/K") = 3.71428608242774e-05 "Constant thermal conductance of material"; Real TC_990_998.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_990_998.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_990_998.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_990_998.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_990_998.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_990_998.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_990_998.G(quantity = "ThermalConductance", unit = "W/K") = 1.03996435878819e-05 "Constant thermal conductance of material"; Real TC_990_1128.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_990_1128.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_990_1128.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_990_1128.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_990_1128.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_990_1128.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_990_1128.G(quantity = "ThermalConductance", unit = "W/K") = 0.00026 "Constant thermal conductance of material"; Real TC_991_999.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_991_999.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_991_999.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_991_999.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_991_999.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_991_999.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_991_999.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999374941397e-05 "Constant thermal conductance of material"; Real TC_991_1536.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_991_1536.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_991_1536.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_991_1536.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_991_1536.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_991_1536.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_991_1536.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915717304333 "Constant thermal conductance of material"; Real TC_991_1659.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_991_1659.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_991_1659.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_991_1659.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_991_1659.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_991_1659.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_991_1659.G(quantity = "ThermalConductance", unit = "W/K") = 5.17318272893602e-05 "Constant thermal conductance of material"; Real TC_992_993.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_992_993.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_992_993.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_992_993.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_992_993.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_992_993.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_992_993.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002514379104e-05 "Constant thermal conductance of material"; Real TC_992_1000.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_992_1000.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_992_1000.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_992_1000.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_992_1000.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_992_1000.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_992_1000.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001436472024e-05 "Constant thermal conductance of material"; Real TC_992_1540.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_992_1540.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_992_1540.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_992_1540.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_992_1540.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_992_1540.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_992_1540.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012991457252433 "Constant thermal conductance of material"; Real TC_992_1661.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_992_1661.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_992_1661.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_992_1661.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_992_1661.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_992_1661.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_992_1661.G(quantity = "ThermalConductance", unit = "W/K") = 5.17301923327748e-05 "Constant thermal conductance of material"; Real TC_993_994.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_993_994.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_993_994.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_993_994.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_993_994.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_993_994.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_993_994.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002895892663e-05 "Constant thermal conductance of material"; Real TC_993_1001.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_993_1001.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_993_1001.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_993_1001.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_993_1001.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_993_1001.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_993_1001.G(quantity = "ThermalConductance", unit = "W/K") = 2.60008066955733e-05 "Constant thermal conductance of material"; Real TC_993_1541.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_993_1541.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_993_1541.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_993_1541.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_993_1541.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_993_1541.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_993_1541.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129914048691487 "Constant thermal conductance of material"; Real TC_993_1653.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_993_1653.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_993_1653.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_993_1653.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_993_1653.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_993_1653.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_993_1653.G(quantity = "ThermalConductance", unit = "W/K") = 5.17316017316017e-05 "Constant thermal conductance of material"; Real TC_994_995.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_994_995.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_994_995.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_994_995.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_994_995.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_994_995.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_994_995.G(quantity = "ThermalConductance", unit = "W/K") = 2.60008963250672e-05 "Constant thermal conductance of material"; Real TC_994_1002.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_994_1002.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_994_1002.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_994_1002.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_994_1002.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_994_1002.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_994_1002.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002852298477e-05 "Constant thermal conductance of material"; Real TC_994_1542.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_994_1542.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_994_1542.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_994_1542.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_994_1542.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_994_1542.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_994_1542.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129914029057178 "Constant thermal conductance of material"; Real TC_994_1654.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_994_1654.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_994_1654.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_994_1654.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_994_1654.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_994_1654.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_994_1654.G(quantity = "ThermalConductance", unit = "W/K") = 5.1731980563982e-05 "Constant thermal conductance of material"; Real TC_995_996.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_995_996.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_995_996.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_995_996.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_995_996.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_995_996.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_995_996.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997204975143e-05 "Constant thermal conductance of material"; Real TC_995_1003.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_995_1003.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_995_1003.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_995_1003.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_995_1003.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_995_1003.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_995_1003.G(quantity = "ThermalConductance", unit = "W/K") = 2.6000714796283e-05 "Constant thermal conductance of material"; Real TC_995_1543.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_995_1543.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_995_1543.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_995_1543.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_995_1543.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_995_1543.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_995_1543.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129914037928727 "Constant thermal conductance of material"; Real TC_995_1655.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_995_1655.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_995_1655.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_995_1655.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_995_1655.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_995_1655.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_995_1655.G(quantity = "ThermalConductance", unit = "W/K") = 5.17298044063114e-05 "Constant thermal conductance of material"; Real TC_996_997.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_996_997.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_996_997.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_996_997.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_996_997.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_996_997.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_996_997.G(quantity = "ThermalConductance", unit = "W/K") = 3.71424868767429e-05 "Constant thermal conductance of material"; Real TC_996_1004.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_996_1004.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_996_1004.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_996_1004.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_996_1004.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_996_1004.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_996_1004.G(quantity = "ThermalConductance", unit = "W/K") = 2.59990608123974e-05 "Constant thermal conductance of material"; Real TC_996_1544.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_996_1544.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_996_1544.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_996_1544.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_996_1544.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_996_1544.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_996_1544.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129914980412827 "Constant thermal conductance of material"; Real TC_997_1005.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_997_1005.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_997_1005.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_997_1005.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_997_1005.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_997_1005.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_997_1005.G(quantity = "ThermalConductance", unit = "W/K") = 1.03998541343787e-05 "Constant thermal conductance of material"; Real TC_997_1129.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_997_1129.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_997_1129.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_997_1129.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_997_1129.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_997_1129.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_997_1129.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001763201975 "Constant thermal conductance of material"; Real TC_998_999.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_998_999.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_998_999.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_998_999.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_998_999.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_998_999.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_998_999.G(quantity = "ThermalConductance", unit = "W/K") = 3.71428331874665e-05 "Constant thermal conductance of material"; Real TC_998_1006.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_998_1006.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_998_1006.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_998_1006.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_998_1006.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_998_1006.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_998_1006.G(quantity = "ThermalConductance", unit = "W/K") = 5.20002625447146e-06 "Constant thermal conductance of material"; Real TC_998_1130.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_998_1130.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_998_1130.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_998_1130.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_998_1130.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_998_1130.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_998_1130.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259998964353856 "Constant thermal conductance of material"; Real TC_999_1007.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_999_1007.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_999_1007.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_999_1007.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_999_1007.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_999_1007.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_999_1007.G(quantity = "ThermalConductance", unit = "W/K") = 1.30000845332357e-05 "Constant thermal conductance of material"; Real TC_999_1545.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_999_1545.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_999_1545.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_999_1545.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_999_1545.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_999_1545.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_999_1545.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916662032366 "Constant thermal conductance of material"; Real TC_999_1662.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_999_1662.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_999_1662.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_999_1662.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_999_1662.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_999_1662.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_999_1662.G(quantity = "ThermalConductance", unit = "W/K") = 5.17316746952578e-05 "Constant thermal conductance of material"; Real TC_1000_1001.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1000_1001.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1000_1001.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1000_1001.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1000_1001.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1000_1001.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1000_1001.G(quantity = "ThermalConductance", unit = "W/K") = 2.59994838202219e-05 "Constant thermal conductance of material"; Real TC_1000_1011.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1000_1011.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1000_1011.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1000_1011.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1000_1011.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1000_1011.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1000_1011.G(quantity = "ThermalConductance", unit = "W/K") = 1.29997139383537e-05 "Constant thermal conductance of material"; Real TC_1000_1549.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1000_1549.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1000_1549.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1000_1549.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1000_1549.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1000_1549.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1000_1549.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012991676015178 "Constant thermal conductance of material"; Real TC_1000_1664.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1000_1664.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1000_1664.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1000_1664.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1000_1664.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1000_1664.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1000_1664.G(quantity = "ThermalConductance", unit = "W/K") = 5.1731196054254e-05 "Constant thermal conductance of material"; Real TC_1001_1002.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1001_1002.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1001_1002.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1001_1002.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1001_1002.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1001_1002.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1001_1002.G(quantity = "ThermalConductance", unit = "W/K") = 2.59996003818575e-05 "Constant thermal conductance of material"; Real TC_1001_1012.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1001_1012.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1001_1012.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1001_1012.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1001_1012.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1001_1012.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1001_1012.G(quantity = "ThermalConductance", unit = "W/K") = 1.30002009175234e-05 "Constant thermal conductance of material"; Real TC_1001_1550.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1001_1550.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1001_1550.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1001_1550.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1001_1550.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1001_1550.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1001_1550.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915697421372 "Constant thermal conductance of material"; Real TC_1002_1003.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1002_1003.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1002_1003.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1002_1003.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1002_1003.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1002_1003.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1002_1003.G(quantity = "ThermalConductance", unit = "W/K") = 2.60016056768445e-05 "Constant thermal conductance of material"; Real TC_1002_1013.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1002_1013.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1002_1013.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1002_1013.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1002_1013.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1002_1013.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1002_1013.G(quantity = "ThermalConductance", unit = "W/K") = 1.30000569595017e-05 "Constant thermal conductance of material"; Real TC_1002_1551.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1002_1551.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1002_1551.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1002_1551.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1002_1551.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1002_1551.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1002_1551.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012991630051623 "Constant thermal conductance of material"; Real TC_1003_1004.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1003_1004.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1003_1004.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1003_1004.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1003_1004.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1003_1004.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1003_1004.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998522385854e-05 "Constant thermal conductance of material"; Real TC_1003_1014.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1003_1014.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1003_1014.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1003_1014.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1003_1014.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1003_1014.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1003_1014.G(quantity = "ThermalConductance", unit = "W/K") = 1.30003033673779e-05 "Constant thermal conductance of material"; Real TC_1003_1552.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1003_1552.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1003_1552.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1003_1552.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1003_1552.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1003_1552.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1003_1552.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915137367922 "Constant thermal conductance of material"; Real TC_1004_1005.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1004_1005.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1004_1005.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1004_1005.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1004_1005.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1004_1005.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1004_1005.G(quantity = "ThermalConductance", unit = "W/K") = 3.71431200592026e-05 "Constant thermal conductance of material"; Real TC_1004_1015.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1004_1015.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1004_1015.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1004_1015.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1004_1015.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1004_1015.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1004_1015.G(quantity = "ThermalConductance", unit = "W/K") = 1.30003327988382e-05 "Constant thermal conductance of material"; Real TC_1004_1553.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1004_1553.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1004_1553.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1004_1553.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1004_1553.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1004_1553.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1004_1553.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915827802134 "Constant thermal conductance of material"; Real TC_1005_1016.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1005_1016.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1005_1016.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1005_1016.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1005_1016.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1005_1016.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1005_1016.G(quantity = "ThermalConductance", unit = "W/K") = 5.19993258332281e-06 "Constant thermal conductance of material"; Real TC_1005_1131.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1005_1131.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1005_1131.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1005_1131.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1005_1131.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1005_1131.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1005_1131.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259998790934856 "Constant thermal conductance of material"; Real TC_1006_1007.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1006_1007.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1006_1007.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1006_1007.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1006_1007.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1006_1007.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1006_1007.G(quantity = "ThermalConductance", unit = "W/K") = 0.000111425707563404 "Constant thermal conductance of material"; Real TC_1006_1017.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1006_1017.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1006_1017.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1006_1017.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1006_1017.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1006_1017.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1006_1017.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001143255165e-06 "Constant thermal conductance of material"; Real TC_1006_1132.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1006_1132.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1006_1132.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1006_1132.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1006_1132.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1006_1132.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1006_1132.G(quantity = "ThermalConductance", unit = "W/K") = 0.000779989862233524 "Constant thermal conductance of material"; Real TC_1007_1008.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1007_1008.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1007_1008.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1007_1008.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1007_1008.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1007_1008.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1007_1008.G(quantity = "ThermalConductance", unit = "W/K") = 7.80012787094873e-05 "Constant thermal conductance of material"; Real TC_1007_1018.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1007_1018.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1007_1018.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1007_1018.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1007_1018.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1007_1018.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1007_1018.G(quantity = "ThermalConductance", unit = "W/K") = 1.2999868942946e-05 "Constant thermal conductance of material"; Real TC_1007_1554.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1007_1554.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1007_1554.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1007_1554.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1007_1554.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1007_1554.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1007_1554.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389754136582062 "Constant thermal conductance of material"; Real TC_1008_1009.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1008_1009.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1008_1009.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1008_1009.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1008_1009.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1008_1009.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1008_1009.G(quantity = "ThermalConductance", unit = "W/K") = 7.79973916823664e-05 "Constant thermal conductance of material"; Real TC_1008_1019.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1008_1019.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1008_1019.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1008_1019.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1008_1019.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1008_1019.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1008_1019.G(quantity = "ThermalConductance", unit = "W/K") = 1.29999570973416e-05 "Constant thermal conductance of material"; Real TC_1008_1555.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1008_1555.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1008_1555.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1008_1555.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1008_1555.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1008_1555.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1008_1555.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389747852425048 "Constant thermal conductance of material"; Real TC_1008_1662.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1008_1662.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1008_1662.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1008_1662.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1008_1662.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1008_1662.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1008_1662.G(quantity = "ThermalConductance", unit = "W/K") = 1.73033198543696e-05 "Constant thermal conductance of material"; Real TC_1009_1010.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1009_1010.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1009_1010.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1009_1010.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1009_1010.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1009_1010.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1009_1010.G(quantity = "ThermalConductance", unit = "W/K") = 7.80001250703538e-05 "Constant thermal conductance of material"; Real TC_1009_1020.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1009_1020.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1009_1020.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1009_1020.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1009_1020.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1009_1020.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1009_1020.G(quantity = "ThermalConductance", unit = "W/K") = 1.29998654635919e-05 "Constant thermal conductance of material"; Real TC_1009_1556.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1009_1556.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1009_1556.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1009_1556.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1009_1556.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1009_1556.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1009_1556.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389738163524814 "Constant thermal conductance of material"; Real TC_1009_1663.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1009_1663.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1009_1663.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1009_1663.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1009_1663.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1009_1663.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1009_1663.G(quantity = "ThermalConductance", unit = "W/K") = 1.73032818020885e-05 "Constant thermal conductance of material"; Real TC_1010_1011.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1010_1011.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1010_1011.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1010_1011.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1010_1011.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1010_1011.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1010_1011.G(quantity = "ThermalConductance", unit = "W/K") = 7.80011487650775e-05 "Constant thermal conductance of material"; Real TC_1010_1021.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1010_1021.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1010_1021.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1010_1021.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1010_1021.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1010_1021.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1010_1021.G(quantity = "ThermalConductance", unit = "W/K") = 1.30001363924564e-05 "Constant thermal conductance of material"; Real TC_1010_1557.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1010_1557.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1010_1557.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1010_1557.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1010_1557.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1010_1557.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1010_1557.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389752044356823 "Constant thermal conductance of material"; Real TC_1010_1664.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1010_1664.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1010_1664.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1010_1664.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1010_1664.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1010_1664.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1010_1664.G(quantity = "ThermalConductance", unit = "W/K") = 1.73034169602215e-05 "Constant thermal conductance of material"; Real TC_1011_1012.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1011_1012.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1011_1012.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1011_1012.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1011_1012.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1011_1012.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1011_1012.G(quantity = "ThermalConductance", unit = "W/K") = 7.79971534990763e-05 "Constant thermal conductance of material"; Real TC_1011_1022.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1011_1022.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1011_1022.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1011_1022.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1011_1022.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1011_1022.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1011_1022.G(quantity = "ThermalConductance", unit = "W/K") = 1.29999845905355e-05 "Constant thermal conductance of material"; Real TC_1011_1558.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1011_1558.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1011_1558.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1011_1558.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1011_1558.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1011_1558.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1011_1558.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389736437906957 "Constant thermal conductance of material"; Real TC_1012_1013.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1012_1013.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1012_1013.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1012_1013.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1012_1013.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1012_1013.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1012_1013.G(quantity = "ThermalConductance", unit = "W/K") = 7.80012286203876e-05 "Constant thermal conductance of material"; Real TC_1012_1023.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1012_1023.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1012_1023.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1012_1023.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1012_1023.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1012_1023.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1012_1023.G(quantity = "ThermalConductance", unit = "W/K") = 1.29998678347557e-05 "Constant thermal conductance of material"; Real TC_1012_1559.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1012_1559.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1012_1559.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1012_1559.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1012_1559.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1012_1559.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1012_1559.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389746669405946 "Constant thermal conductance of material"; Real TC_1013_1014.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1013_1014.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1013_1014.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1013_1014.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1013_1014.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1013_1014.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1013_1014.G(quantity = "ThermalConductance", unit = "W/K") = 7.80009326908134e-05 "Constant thermal conductance of material"; Real TC_1013_1024.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1013_1024.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1013_1024.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1013_1024.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1013_1024.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1013_1024.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1013_1024.G(quantity = "ThermalConductance", unit = "W/K") = 1.30001834358388e-05 "Constant thermal conductance of material"; Real TC_1013_1560.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1013_1560.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1013_1560.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1013_1560.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1013_1560.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1013_1560.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1013_1560.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389748390279692 "Constant thermal conductance of material"; Real TC_1014_1015.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1014_1015.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1014_1015.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1014_1015.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1014_1015.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1014_1015.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1014_1015.G(quantity = "ThermalConductance", unit = "W/K") = 7.8001006369583e-05 "Constant thermal conductance of material"; Real TC_1014_1025.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1014_1025.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1014_1025.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1014_1025.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1014_1025.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1014_1025.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1014_1025.G(quantity = "ThermalConductance", unit = "W/K") = 1.29998926060705e-05 "Constant thermal conductance of material"; Real TC_1014_1561.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1014_1561.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1014_1561.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1014_1561.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1014_1561.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1014_1561.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1014_1561.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389761417269257 "Constant thermal conductance of material"; Real TC_1015_1016.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1015_1016.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1015_1016.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1015_1016.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1015_1016.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1015_1016.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1015_1016.G(quantity = "ThermalConductance", unit = "W/K") = 0.000111425653121022 "Constant thermal conductance of material"; Real TC_1015_1026.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1015_1026.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1015_1026.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1015_1026.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1015_1026.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1015_1026.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1015_1026.G(quantity = "ThermalConductance", unit = "W/K") = 1.29997887255402e-05 "Constant thermal conductance of material"; Real TC_1015_1562.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1015_1562.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1015_1562.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1015_1562.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1015_1562.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1015_1562.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1015_1562.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389744516595448 "Constant thermal conductance of material"; Real TC_1016_1027.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1016_1027.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1016_1027.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1016_1027.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1016_1027.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1016_1027.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1016_1027.G(quantity = "ThermalConductance", unit = "W/K") = 5.19999209777684e-06 "Constant thermal conductance of material"; Real TC_1016_1133.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1016_1133.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1016_1133.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1016_1133.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1016_1133.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1016_1133.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1016_1133.G(quantity = "ThermalConductance", unit = "W/K") = 0.000779993004547047 "Constant thermal conductance of material"; Real TC_1017_1018.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1017_1018.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1017_1018.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1017_1018.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1017_1018.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1017_1018.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1017_1018.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430860118153e-05 "Constant thermal conductance of material"; Real TC_1017_1134.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1017_1134.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1017_1134.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1017_1134.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1017_1134.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1017_1134.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1017_1134.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260011562921564 "Constant thermal conductance of material"; Real TC_1018_1019.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1018_1019.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1018_1019.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1018_1019.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1018_1019.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1018_1019.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1018_1019.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997254758419e-05 "Constant thermal conductance of material"; Real TC_1018_1135.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1018_1135.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1018_1135.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1018_1135.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1018_1135.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1018_1135.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1018_1135.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649999372151139 "Constant thermal conductance of material"; Real TC_1019_1020.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1019_1020.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1019_1020.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1019_1020.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1019_1020.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1019_1020.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1019_1020.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997894810709e-05 "Constant thermal conductance of material"; Real TC_1019_1136.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1019_1136.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1019_1136.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1019_1136.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1019_1136.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1019_1136.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1019_1136.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649999999999999 "Constant thermal conductance of material"; Real TC_1020_1021.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1020_1021.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1020_1021.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1020_1021.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1020_1021.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1020_1021.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1020_1021.G(quantity = "ThermalConductance", unit = "W/K") = 2.60006138735425e-05 "Constant thermal conductance of material"; Real TC_1020_1137.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1020_1137.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1020_1137.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1020_1137.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1020_1137.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1020_1137.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1020_1137.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650008611992813 "Constant thermal conductance of material"; Real TC_1021_1022.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1021_1022.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1021_1022.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1021_1022.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1021_1022.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1021_1022.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1021_1022.G(quantity = "ThermalConductance", unit = "W/K") = 2.59995466908435e-05 "Constant thermal conductance of material"; Real TC_1021_1138.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1021_1138.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1021_1138.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1021_1138.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1021_1138.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1021_1138.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1021_1138.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650006807520454 "Constant thermal conductance of material"; Real TC_1022_1023.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1022_1023.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1022_1023.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1022_1023.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1022_1023.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1022_1023.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1022_1023.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998008364868e-05 "Constant thermal conductance of material"; Real TC_1022_1139.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1022_1139.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1022_1139.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1022_1139.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1022_1139.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1022_1139.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1022_1139.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650003115070715 "Constant thermal conductance of material"; Real TC_1023_1024.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1023_1024.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1023_1024.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1023_1024.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1023_1024.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1023_1024.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1023_1024.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004805670685e-05 "Constant thermal conductance of material"; Real TC_1023_1140.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1023_1140.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1023_1140.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1023_1140.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1023_1140.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1023_1140.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1023_1140.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650000000000002 "Constant thermal conductance of material"; Real TC_1024_1025.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1024_1025.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1024_1025.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1024_1025.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1024_1025.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1024_1025.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1024_1025.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001858217971e-05 "Constant thermal conductance of material"; Real TC_1024_1141.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1024_1141.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1024_1141.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1024_1141.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1024_1141.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1024_1141.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1024_1141.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649993064924912 "Constant thermal conductance of material"; Real TC_1025_1026.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1025_1026.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1025_1026.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1025_1026.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1025_1026.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1025_1026.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1025_1026.G(quantity = "ThermalConductance", unit = "W/K") = 2.59994720675754e-05 "Constant thermal conductance of material"; Real TC_1025_1142.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1025_1142.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1025_1142.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1025_1142.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1025_1142.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1025_1142.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1025_1142.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650008838160655 "Constant thermal conductance of material"; Real TC_1026_1027.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1026_1027.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1026_1027.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1026_1027.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1026_1027.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1026_1027.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1026_1027.G(quantity = "ThermalConductance", unit = "W/K") = 3.71427724792468e-05 "Constant thermal conductance of material"; Real TC_1026_1143.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1026_1143.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1026_1143.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1026_1143.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1026_1143.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1026_1143.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1026_1143.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650004534794834 "Constant thermal conductance of material"; Real TC_1027_1144.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1027_1144.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1027_1144.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1027_1144.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1027_1144.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1027_1144.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1027_1144.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259996383036436 "Constant thermal conductance of material"; Real TC_1028_1029.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1028_1029.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1028_1029.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1028_1029.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1028_1029.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1028_1029.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1028_1029.G(quantity = "ThermalConductance", unit = "W/K") = 3.64006007546064e-05 "Constant thermal conductance of material"; Real TC_1028_1035.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1028_1035.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1028_1035.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1028_1035.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1028_1035.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1028_1035.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1028_1035.G(quantity = "ThermalConductance", unit = "W/K") = 1.85687478676227e-05 "Constant thermal conductance of material"; Real TC_1028_1092.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1028_1092.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1028_1092.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1028_1092.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1028_1092.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1028_1092.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1028_1092.G(quantity = "ThermalConductance", unit = "W/K") = 1.85716643559781e-05 "Constant thermal conductance of material"; Real TC_1028_1633.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1028_1633.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1028_1633.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1028_1633.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1028_1633.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1028_1633.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1028_1633.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181880422303287 "Constant thermal conductance of material"; Real TC_1028_1642.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1028_1642.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1028_1642.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1028_1642.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1028_1642.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1028_1642.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1028_1642.G(quantity = "ThermalConductance", unit = "W/K") = 7.24228529010349e-05 "Constant thermal conductance of material"; Real TC_1029_1030.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1029_1030.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1029_1030.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1029_1030.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1029_1030.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1029_1030.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1029_1030.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000361392473e-05 "Constant thermal conductance of material"; Real TC_1029_1036.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1029_1036.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1029_1036.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1029_1036.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1029_1036.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1029_1036.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1029_1036.G(quantity = "ThermalConductance", unit = "W/K") = 1.85727199678579e-05 "Constant thermal conductance of material"; Real TC_1029_1093.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1029_1093.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1029_1093.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1029_1093.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1029_1093.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1029_1093.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1029_1093.G(quantity = "ThermalConductance", unit = "W/K") = 1.85710802243355e-05 "Constant thermal conductance of material"; Real TC_1029_1634.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1029_1634.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1029_1634.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1029_1634.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1029_1634.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1029_1634.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1029_1634.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181882725102179 "Constant thermal conductance of material"; Real TC_1030_1037.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1030_1037.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1030_1037.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1030_1037.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1030_1037.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1030_1037.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1030_1037.G(quantity = "ThermalConductance", unit = "W/K") = 7.42915890252512e-06 "Constant thermal conductance of material"; Real TC_1030_1094.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1030_1094.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1030_1094.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1030_1094.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1030_1094.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1030_1094.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1030_1094.G(quantity = "ThermalConductance", unit = "W/K") = 7.42849846782435e-06 "Constant thermal conductance of material"; Real TC_1030_1115.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1030_1115.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1030_1115.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1030_1115.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1030_1115.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1030_1115.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1030_1115.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363991240254422 "Constant thermal conductance of material"; Real TC_1031_1032.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1031_1032.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1031_1032.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1031_1032.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1031_1032.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1031_1032.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1031_1032.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000340222846e-05 "Constant thermal conductance of material"; Real TC_1031_1038.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1031_1038.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1031_1038.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1031_1038.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1031_1038.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1031_1038.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1031_1038.G(quantity = "ThermalConductance", unit = "W/K") = 4.95198281813304e-06 "Constant thermal conductance of material"; Real TC_1031_1095.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1031_1095.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1031_1095.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1031_1095.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1031_1095.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1031_1095.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1031_1095.G(quantity = "ThermalConductance", unit = "W/K") = 7.42727972297032e-06 "Constant thermal conductance of material"; Real TC_1031_1116.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1031_1116.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1031_1116.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1031_1116.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1031_1116.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1031_1116.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1031_1116.G(quantity = "ThermalConductance", unit = "W/K") = 0.00036399993588305 "Constant thermal conductance of material"; Real TC_1032_1033.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1032_1033.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1032_1033.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1032_1033.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1032_1033.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1032_1033.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1032_1033.G(quantity = "ThermalConductance", unit = "W/K") = 3.64002929153418e-05 "Constant thermal conductance of material"; Real TC_1032_1039.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1032_1039.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1032_1039.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1032_1039.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1032_1039.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1032_1039.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1032_1039.G(quantity = "ThermalConductance", unit = "W/K") = 1.2381102610616e-05 "Constant thermal conductance of material"; Real TC_1032_1096.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1032_1096.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1032_1096.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1032_1096.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1032_1096.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1032_1096.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1032_1096.G(quantity = "ThermalConductance", unit = "W/K") = 1.85740979381417e-05 "Constant thermal conductance of material"; Real TC_1032_1563.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1032_1563.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1032_1563.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1032_1563.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1032_1563.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1032_1563.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1032_1563.G(quantity = "ThermalConductance", unit = "W/K") = 0.001818814361258 "Constant thermal conductance of material"; Real TC_1033_1034.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1033_1034.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1033_1034.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1033_1034.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1033_1034.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1033_1034.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1033_1034.G(quantity = "ThermalConductance", unit = "W/K") = 3.63999426913572e-05 "Constant thermal conductance of material"; Real TC_1033_1040.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1033_1040.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1033_1040.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1033_1040.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1033_1040.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1033_1040.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1033_1040.G(quantity = "ThermalConductance", unit = "W/K") = 1.23808788800221e-05 "Constant thermal conductance of material"; Real TC_1033_1097.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1033_1097.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1033_1097.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1033_1097.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1033_1097.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1033_1097.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1033_1097.G(quantity = "ThermalConductance", unit = "W/K") = 1.85734265734289e-05 "Constant thermal conductance of material"; Real TC_1033_1564.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1033_1564.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1033_1564.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1033_1564.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1033_1564.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1033_1564.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1033_1564.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181880713243052 "Constant thermal conductance of material"; Real TC_1034_1041.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1034_1041.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1034_1041.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1034_1041.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1034_1041.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1034_1041.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1034_1041.G(quantity = "ThermalConductance", unit = "W/K") = 1.23812289115612e-05 "Constant thermal conductance of material"; Real TC_1034_1098.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1034_1098.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1034_1098.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1034_1098.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1034_1098.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1034_1098.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1034_1098.G(quantity = "ThermalConductance", unit = "W/K") = 1.85730784036968e-05 "Constant thermal conductance of material"; Real TC_1034_1565.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1034_1565.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1034_1565.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1034_1565.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1034_1565.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1034_1565.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1034_1565.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181880733944954 "Constant thermal conductance of material"; Real TC_1034_1643.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1034_1643.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1034_1643.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1034_1643.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1034_1643.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1034_1643.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1034_1643.G(quantity = "ThermalConductance", unit = "W/K") = 7.2424970977994e-05 "Constant thermal conductance of material"; Real TC_1035_1036.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1035_1036.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1035_1036.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1035_1036.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1035_1036.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1035_1036.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1035_1036.G(quantity = "ThermalConductance", unit = "W/K") = 3.63998782135451e-05 "Constant thermal conductance of material"; Real TC_1035_1046.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1035_1046.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1035_1046.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1035_1046.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1035_1046.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1035_1046.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1035_1046.G(quantity = "ThermalConductance", unit = "W/K") = 1.23805478870251e-05 "Constant thermal conductance of material"; Real TC_1035_1570.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1035_1570.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1035_1570.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1035_1570.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1035_1570.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1035_1570.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1035_1570.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181880442226788 "Constant thermal conductance of material"; Real TC_1035_1646.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1035_1646.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1035_1646.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1035_1646.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1035_1646.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1035_1646.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1035_1646.G(quantity = "ThermalConductance", unit = "W/K") = 7.24236863954804e-05 "Constant thermal conductance of material"; Real TC_1036_1037.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1036_1037.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1036_1037.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1036_1037.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1036_1037.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1036_1037.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1036_1037.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000248180526e-05 "Constant thermal conductance of material"; Real TC_1036_1047.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1036_1047.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1036_1047.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1036_1047.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1036_1047.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1036_1047.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1036_1047.G(quantity = "ThermalConductance", unit = "W/K") = 1.23832853025934e-05 "Constant thermal conductance of material"; Real TC_1036_1571.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1036_1571.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1036_1571.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1036_1571.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1036_1571.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1036_1571.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1036_1571.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181882703701065 "Constant thermal conductance of material"; Real TC_1037_1048.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1037_1048.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1037_1048.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1037_1048.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1037_1048.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1037_1048.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1037_1048.G(quantity = "ThermalConductance", unit = "W/K") = 4.95231092436983e-06 "Constant thermal conductance of material"; Real TC_1037_1117.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1037_1117.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1037_1117.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1037_1117.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1037_1117.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1037_1117.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1037_1117.G(quantity = "ThermalConductance", unit = "W/K") = 0.000364011458022592 "Constant thermal conductance of material"; Real TC_1038_1039.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1038_1039.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1038_1039.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1038_1039.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1038_1039.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1038_1039.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1038_1039.G(quantity = "ThermalConductance", unit = "W/K") = 0.000103999307778835 "Constant thermal conductance of material"; Real TC_1038_1049.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1038_1049.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1038_1049.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1038_1049.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1038_1049.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1038_1049.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1038_1049.G(quantity = "ThermalConductance", unit = "W/K") = 5.47333574094142e-06 "Constant thermal conductance of material"; Real TC_1038_1118.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1038_1118.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1038_1118.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1038_1118.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1038_1118.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1038_1118.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1038_1118.G(quantity = "ThermalConductance", unit = "W/K") = 0.000727982565430365 "Constant thermal conductance of material"; Real TC_1039_1040.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1039_1040.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1039_1040.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1039_1040.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1039_1040.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1039_1040.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1039_1040.G(quantity = "ThermalConductance", unit = "W/K") = 7.28007789870704e-05 "Constant thermal conductance of material"; Real TC_1039_1050.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1039_1050.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1039_1050.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1039_1050.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1039_1050.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1039_1050.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1039_1050.G(quantity = "ThermalConductance", unit = "W/K") = 1.36844289773635e-05 "Constant thermal conductance of material"; Real TC_1039_1572.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1039_1572.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1039_1572.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1039_1572.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1039_1572.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1039_1572.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1039_1572.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363761762692736 "Constant thermal conductance of material"; Real TC_1040_1041.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1040_1041.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1040_1041.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1040_1041.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1040_1041.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1040_1041.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1040_1041.G(quantity = "ThermalConductance", unit = "W/K") = 7.28021978021964e-05 "Constant thermal conductance of material"; Real TC_1040_1051.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1040_1051.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1040_1051.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1040_1051.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1040_1051.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1040_1051.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1040_1051.G(quantity = "ThermalConductance", unit = "W/K") = 1.36843489985857e-05 "Constant thermal conductance of material"; Real TC_1040_1573.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1040_1573.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1040_1573.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1040_1573.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1040_1573.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1040_1573.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1040_1573.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363760325992167 "Constant thermal conductance of material"; Real TC_1041_1042.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1041_1042.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1041_1042.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1041_1042.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1041_1042.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1041_1042.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1041_1042.G(quantity = "ThermalConductance", unit = "W/K") = 7.27929437272107e-05 "Constant thermal conductance of material"; Real TC_1041_1052.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1041_1052.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1041_1052.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1041_1052.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1041_1052.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1041_1052.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1041_1052.G(quantity = "ThermalConductance", unit = "W/K") = 1.36839953922189e-05 "Constant thermal conductance of material"; Real TC_1041_1574.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1041_1574.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1041_1574.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1041_1574.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1041_1574.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1041_1574.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1041_1574.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363763473329045 "Constant thermal conductance of material"; Real TC_1042_1043.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1042_1043.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1042_1043.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1042_1043.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1042_1043.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1042_1043.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1042_1043.G(quantity = "ThermalConductance", unit = "W/K") = 7.27853492333924e-05 "Constant thermal conductance of material"; Real TC_1042_1053.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1042_1053.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1042_1053.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1042_1053.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1042_1053.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1042_1053.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1042_1053.G(quantity = "ThermalConductance", unit = "W/K") = 1.36847920069172e-05 "Constant thermal conductance of material"; Real TC_1042_1575.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1042_1575.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1042_1575.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1042_1575.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1042_1575.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1042_1575.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1042_1575.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363752157809174 "Constant thermal conductance of material"; Real TC_1042_1643.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1042_1643.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1042_1643.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1042_1643.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1042_1643.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1042_1643.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1042_1643.G(quantity = "ThermalConductance", unit = "W/K") = 1.85233378106111e-05 "Constant thermal conductance of material"; Real TC_1043_1044.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1043_1044.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1043_1044.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1043_1044.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1043_1044.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1043_1044.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1043_1044.G(quantity = "ThermalConductance", unit = "W/K") = 7.28011154088324e-05 "Constant thermal conductance of material"; Real TC_1043_1054.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1043_1054.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1043_1054.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1043_1054.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1043_1054.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1043_1054.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1043_1054.G(quantity = "ThermalConductance", unit = "W/K") = 1.36845598973317e-05 "Constant thermal conductance of material"; Real TC_1043_1576.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1043_1576.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1043_1576.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1043_1576.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1043_1576.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1043_1576.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1043_1576.G(quantity = "ThermalConductance", unit = "W/K") = 0.003637598084088 "Constant thermal conductance of material"; Real TC_1043_1644.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1043_1644.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1043_1644.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1043_1644.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1043_1644.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1043_1644.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1043_1644.G(quantity = "ThermalConductance", unit = "W/K") = 1.85232671197336e-05 "Constant thermal conductance of material"; Real TC_1044_1045.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1044_1045.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1044_1045.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1044_1045.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1044_1045.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1044_1045.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1044_1045.G(quantity = "ThermalConductance", unit = "W/K") = 7.28001364256489e-05 "Constant thermal conductance of material"; Real TC_1044_1055.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1044_1055.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1044_1055.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1044_1055.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1044_1055.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1044_1055.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1044_1055.G(quantity = "ThermalConductance", unit = "W/K") = 1.36844192759404e-05 "Constant thermal conductance of material"; Real TC_1044_1577.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1044_1577.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1044_1577.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1044_1577.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1044_1577.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1044_1577.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1044_1577.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363759663637597 "Constant thermal conductance of material"; Real TC_1044_1645.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1044_1645.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1044_1645.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1044_1645.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1044_1645.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1044_1645.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1044_1645.G(quantity = "ThermalConductance", unit = "W/K") = 1.85233309443439e-05 "Constant thermal conductance of material"; Real TC_1045_1046.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1045_1046.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1045_1046.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1045_1046.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1045_1046.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1045_1046.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1045_1046.G(quantity = "ThermalConductance", unit = "W/K") = 7.27965140994757e-05 "Constant thermal conductance of material"; Real TC_1045_1056.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1045_1056.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1045_1056.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1045_1056.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1045_1056.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1045_1056.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1045_1056.G(quantity = "ThermalConductance", unit = "W/K") = 1.36842846331205e-05 "Constant thermal conductance of material"; Real TC_1045_1578.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1045_1578.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1045_1578.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1045_1578.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1045_1578.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1045_1578.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1045_1578.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363778577184105 "Constant thermal conductance of material"; Real TC_1045_1646.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1045_1646.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1045_1646.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1045_1646.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1045_1646.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1045_1646.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1045_1646.G(quantity = "ThermalConductance", unit = "W/K") = 1.8523256423855e-05 "Constant thermal conductance of material"; Real TC_1046_1047.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1046_1047.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1046_1047.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1046_1047.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1046_1047.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1046_1047.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1046_1047.G(quantity = "ThermalConductance", unit = "W/K") = 7.27996318055067e-05 "Constant thermal conductance of material"; Real TC_1046_1057.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1046_1057.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1046_1057.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1046_1057.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1046_1057.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1046_1057.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1046_1057.G(quantity = "ThermalConductance", unit = "W/K") = 1.36840471756674e-05 "Constant thermal conductance of material"; Real TC_1046_1579.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1046_1579.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1046_1579.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1046_1579.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1046_1579.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1046_1579.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1046_1579.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363767649268659 "Constant thermal conductance of material"; Real TC_1047_1048.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1047_1048.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1047_1048.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1047_1048.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1047_1048.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1047_1048.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1047_1048.G(quantity = "ThermalConductance", unit = "W/K") = 0.000104003586492443 "Constant thermal conductance of material"; Real TC_1047_1058.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1047_1058.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1047_1058.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1047_1058.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1047_1058.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1047_1058.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1047_1058.G(quantity = "ThermalConductance", unit = "W/K") = 1.3684267768775e-05 "Constant thermal conductance of material"; Real TC_1047_1580.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1047_1580.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1047_1580.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1047_1580.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1047_1580.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1047_1580.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1047_1580.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363764144416054 "Constant thermal conductance of material"; Real TC_1048_1059.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1048_1059.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1048_1059.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1048_1059.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1048_1059.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1048_1059.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1048_1059.G(quantity = "ThermalConductance", unit = "W/K") = 5.47373374113531e-06 "Constant thermal conductance of material"; Real TC_1048_1119.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1048_1119.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1048_1119.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1048_1119.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1048_1119.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1048_1119.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1048_1119.G(quantity = "ThermalConductance", unit = "W/K") = 0.000728002017984217 "Constant thermal conductance of material"; Real TC_1049_1050.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1049_1050.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1049_1050.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1049_1050.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1049_1050.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1049_1050.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1049_1050.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430216016643e-05 "Constant thermal conductance of material"; Real TC_1049_1060.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1049_1060.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1049_1060.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1049_1060.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1049_1060.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1049_1060.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1049_1060.G(quantity = "ThermalConductance", unit = "W/K") = 1.04001775748352e-05 "Constant thermal conductance of material"; Real TC_1049_1120.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1049_1120.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1049_1120.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1049_1120.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1049_1120.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1049_1120.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1049_1120.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259999919590555 "Constant thermal conductance of material"; Real TC_1050_1051.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1050_1051.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1050_1051.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1050_1051.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1050_1051.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1050_1051.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1050_1051.G(quantity = "ThermalConductance", unit = "W/K") = 2.59994764202101e-05 "Constant thermal conductance of material"; Real TC_1050_1061.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1050_1061.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1050_1061.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1050_1061.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1050_1061.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1050_1061.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1050_1061.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002530284341e-05 "Constant thermal conductance of material"; Real TC_1050_1581.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1050_1581.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1050_1581.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1050_1581.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1050_1581.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1050_1581.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1050_1581.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915339560573 "Constant thermal conductance of material"; Real TC_1051_1052.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1051_1052.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1051_1052.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1051_1052.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1051_1052.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1051_1052.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1051_1052.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004637143522e-05 "Constant thermal conductance of material"; Real TC_1051_1062.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1051_1062.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1051_1062.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1051_1062.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1051_1062.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1051_1062.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1051_1062.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997788099978e-05 "Constant thermal conductance of material"; Real TC_1051_1582.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1051_1582.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1051_1582.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1051_1582.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1051_1582.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1051_1582.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1051_1582.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915239839163 "Constant thermal conductance of material"; Real TC_1052_1053.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1052_1053.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1052_1053.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1052_1053.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1052_1053.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1052_1053.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1052_1053.G(quantity = "ThermalConductance", unit = "W/K") = 2.59990133201776e-05 "Constant thermal conductance of material"; Real TC_1052_1063.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1052_1063.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1052_1063.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1052_1063.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1052_1063.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1052_1063.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1052_1063.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000000000001e-05 "Constant thermal conductance of material"; Real TC_1052_1583.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1052_1583.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1052_1583.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1052_1583.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1052_1583.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1052_1583.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1052_1583.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129914813693609 "Constant thermal conductance of material"; Real TC_1053_1054.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1053_1054.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1053_1054.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1053_1054.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1053_1054.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1053_1054.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1053_1054.G(quantity = "ThermalConductance", unit = "W/K") = 2.59894551845283e-05 "Constant thermal conductance of material"; Real TC_1053_1064.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1053_1064.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1053_1064.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1053_1064.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1053_1064.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1053_1064.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1053_1064.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998793327097e-05 "Constant thermal conductance of material"; Real TC_1053_1584.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1053_1584.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1053_1584.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1053_1584.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1053_1584.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1053_1584.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1053_1584.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916527986898 "Constant thermal conductance of material"; Real TC_1054_1055.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1054_1055.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1054_1055.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1054_1055.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1054_1055.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1054_1055.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1054_1055.G(quantity = "ThermalConductance", unit = "W/K") = 2.59996572114152e-05 "Constant thermal conductance of material"; Real TC_1054_1065.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1054_1065.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1054_1065.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1054_1065.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1054_1065.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1054_1065.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1054_1065.G(quantity = "ThermalConductance", unit = "W/K") = 2.59992377685674e-05 "Constant thermal conductance of material"; Real TC_1054_1585.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1054_1585.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1054_1585.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1054_1585.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1054_1585.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1054_1585.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1054_1585.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916239362131 "Constant thermal conductance of material"; Real TC_1055_1056.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1055_1056.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1055_1056.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1055_1056.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1055_1056.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1055_1056.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1055_1056.G(quantity = "ThermalConductance", unit = "W/K") = 2.60019486846382e-05 "Constant thermal conductance of material"; Real TC_1055_1586.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1055_1586.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1055_1586.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1055_1586.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1055_1586.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1055_1586.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1055_1586.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916209601058 "Constant thermal conductance of material"; Real TC_1055_1647.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1055_1647.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1055_1647.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1055_1647.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1055_1647.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1055_1647.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1055_1647.G(quantity = "ThermalConductance", unit = "W/K") = 5.17304704054244e-05 "Constant thermal conductance of material"; Real TC_1056_1057.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1056_1057.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1056_1057.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1056_1057.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1056_1057.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1056_1057.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1056_1057.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003357535569e-05 "Constant thermal conductance of material"; Real TC_1056_1587.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1056_1587.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1056_1587.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1056_1587.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1056_1587.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1056_1587.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1056_1587.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129917043848251 "Constant thermal conductance of material"; Real TC_1056_1648.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1056_1648.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1056_1648.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1056_1648.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1056_1648.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1056_1648.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1056_1648.G(quantity = "ThermalConductance", unit = "W/K") = 5.17305778846365e-05 "Constant thermal conductance of material"; Real TC_1057_1058.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1057_1058.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1057_1058.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1057_1058.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1057_1058.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1057_1058.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1057_1058.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003661736884e-05 "Constant thermal conductance of material"; Real TC_1057_1588.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1057_1588.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1057_1588.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1057_1588.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1057_1588.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1057_1588.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1057_1588.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129917203882425 "Constant thermal conductance of material"; Real TC_1057_1649.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1057_1649.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1057_1649.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1057_1649.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1057_1649.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1057_1649.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1057_1649.G(quantity = "ThermalConductance", unit = "W/K") = 5.1730641258782e-05 "Constant thermal conductance of material"; Real TC_1058_1059.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1058_1059.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1058_1059.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1058_1059.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1058_1059.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1058_1059.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1058_1059.G(quantity = "ThermalConductance", unit = "W/K") = 3.71426303773711e-05 "Constant thermal conductance of material"; Real TC_1058_1589.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1058_1589.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1058_1589.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1058_1589.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1058_1589.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1058_1589.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1058_1589.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915118334385 "Constant thermal conductance of material"; Real TC_1059_1121.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1059_1121.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1059_1121.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1059_1121.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1059_1121.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1059_1121.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1059_1121.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259998595702851 "Constant thermal conductance of material"; Real TC_1060_1061.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1060_1061.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1060_1061.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1060_1061.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1060_1061.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1060_1061.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1060_1061.G(quantity = "ThermalConductance", unit = "W/K") = 3.71425608111818e-05 "Constant thermal conductance of material"; Real TC_1060_1122.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1060_1122.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1060_1122.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1060_1122.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1060_1122.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1060_1122.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1060_1122.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001197150781 "Constant thermal conductance of material"; Real TC_1061_1062.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1061_1062.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1061_1062.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1061_1062.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1061_1062.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1061_1062.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1061_1062.G(quantity = "ThermalConductance", unit = "W/K") = 2.59991978104944e-05 "Constant thermal conductance of material"; Real TC_1061_1590.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1061_1590.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1061_1590.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1061_1590.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1061_1590.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1061_1590.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1061_1590.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915829542623 "Constant thermal conductance of material"; Real TC_1062_1063.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1062_1063.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1062_1063.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1062_1063.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1062_1063.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1062_1063.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1062_1063.G(quantity = "ThermalConductance", unit = "W/K") = 2.60009182736459e-05 "Constant thermal conductance of material"; Real TC_1062_1591.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1062_1591.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1062_1591.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1062_1591.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1062_1591.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1062_1591.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1062_1591.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916986151809 "Constant thermal conductance of material"; Real TC_1063_1064.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1063_1064.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1063_1064.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1063_1064.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1063_1064.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1063_1064.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1063_1064.G(quantity = "ThermalConductance", unit = "W/K") = 2.59965237543342e-05 "Constant thermal conductance of material"; Real TC_1063_1592.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1063_1592.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1063_1592.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1063_1592.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1063_1592.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1063_1592.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1063_1592.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916598357989 "Constant thermal conductance of material"; Real TC_1064_1065.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1064_1065.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1064_1065.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1064_1065.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1064_1065.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1064_1065.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1064_1065.G(quantity = "ThermalConductance", unit = "W/K") = 2.6000726040659e-05 "Constant thermal conductance of material"; Real TC_1064_1593.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1064_1593.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1064_1593.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1064_1593.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1064_1593.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1064_1593.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1064_1593.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915588479765 "Constant thermal conductance of material"; Real TC_1065_1594.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1065_1594.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1065_1594.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1065_1594.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1065_1594.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1065_1594.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1065_1594.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129913708757342 "Constant thermal conductance of material"; Real TC_1065_1647.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1065_1647.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1065_1647.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1065_1647.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1065_1647.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1065_1647.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1065_1647.G(quantity = "ThermalConductance", unit = "W/K") = 5.17308372825611e-05 "Constant thermal conductance of material"; Real TC_1066_1067.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1066_1067.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1066_1067.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1066_1067.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1066_1067.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1066_1067.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1066_1067.G(quantity = "ThermalConductance", unit = "W/K") = 3.71428146871331e-05 "Constant thermal conductance of material"; Real TC_1066_1077.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1066_1077.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1066_1077.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1066_1077.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1066_1077.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1066_1077.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1066_1077.G(quantity = "ThermalConductance", unit = "W/K") = 6.93327926620473e-06 "Constant thermal conductance of material"; Real TC_1066_1099.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1066_1099.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1066_1099.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1066_1099.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1066_1099.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1066_1099.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1066_1099.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259993307119549 "Constant thermal conductance of material"; Real TC_1067_1068.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1067_1068.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1067_1068.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1067_1068.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1067_1068.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1067_1068.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1067_1068.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998780016674e-05 "Constant thermal conductance of material"; Real TC_1067_1078.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1067_1078.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1067_1078.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1067_1078.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1067_1078.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1067_1078.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1067_1078.G(quantity = "ThermalConductance", unit = "W/K") = 1.73331044316323e-05 "Constant thermal conductance of material"; Real TC_1067_1100.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1067_1100.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1067_1100.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1067_1100.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1067_1100.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1067_1100.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1067_1100.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649998682719921 "Constant thermal conductance of material"; Real TC_1068_1069.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1068_1069.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1068_1069.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1068_1069.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1068_1069.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1068_1069.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1068_1069.G(quantity = "ThermalConductance", unit = "W/K") = 2.6000164006123e-05 "Constant thermal conductance of material"; Real TC_1068_1079.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1068_1079.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1068_1079.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1068_1079.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1068_1079.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1068_1079.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1068_1079.G(quantity = "ThermalConductance", unit = "W/K") = 1.73334371033559e-05 "Constant thermal conductance of material"; Real TC_1068_1101.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1068_1101.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1068_1101.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1068_1101.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1068_1101.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1068_1101.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1068_1101.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650005075884471 "Constant thermal conductance of material"; Real TC_1069_1070.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1069_1070.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1069_1070.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1069_1070.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1069_1070.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1069_1070.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1069_1070.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999999999994e-05 "Constant thermal conductance of material"; Real TC_1069_1080.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1069_1080.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1069_1080.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1069_1080.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1069_1080.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1069_1080.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1069_1080.G(quantity = "ThermalConductance", unit = "W/K") = 1.73335023116819e-05 "Constant thermal conductance of material"; Real TC_1069_1102.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1069_1102.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1069_1102.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1069_1102.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1069_1102.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1069_1102.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1069_1102.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649999999999997 "Constant thermal conductance of material"; Real TC_1070_1071.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1070_1071.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1070_1071.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1070_1071.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1070_1071.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1070_1071.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1070_1071.G(quantity = "ThermalConductance", unit = "W/K") = 2.60034858387782e-05 "Constant thermal conductance of material"; Real TC_1070_1081.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1070_1081.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1070_1081.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1070_1081.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1070_1081.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1070_1081.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1070_1081.G(quantity = "ThermalConductance", unit = "W/K") = 1.73333972441835e-05 "Constant thermal conductance of material"; Real TC_1070_1103.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1070_1103.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1070_1103.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1070_1103.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1070_1103.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1070_1103.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1070_1103.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650014054634196 "Constant thermal conductance of material"; Real TC_1071_1072.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1071_1072.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1071_1072.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1071_1072.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1071_1072.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1071_1072.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1071_1072.G(quantity = "ThermalConductance", unit = "W/K") = 2.60011344299482e-05 "Constant thermal conductance of material"; Real TC_1071_1082.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1071_1082.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1071_1082.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1071_1082.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1071_1082.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1071_1082.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1071_1082.G(quantity = "ThermalConductance", unit = "W/K") = 1.73333190744286e-05 "Constant thermal conductance of material"; Real TC_1071_1104.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1071_1104.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1071_1104.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1071_1104.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1071_1104.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1071_1104.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1071_1104.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650001285578384 "Constant thermal conductance of material"; Real TC_1072_1073.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1072_1073.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1072_1073.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1072_1073.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1072_1073.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1072_1073.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1072_1073.G(quantity = "ThermalConductance", unit = "W/K") = 2.59995408368247e-05 "Constant thermal conductance of material"; Real TC_1072_1083.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1072_1083.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1072_1083.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1072_1083.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1072_1083.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1072_1083.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1072_1083.G(quantity = "ThermalConductance", unit = "W/K") = 1.73331253273527e-05 "Constant thermal conductance of material"; Real TC_1072_1105.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1072_1105.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1072_1105.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1072_1105.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1072_1105.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1072_1105.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1072_1105.G(quantity = "ThermalConductance", unit = "W/K") = 0.0006500012922234 "Constant thermal conductance of material"; Real TC_1073_1074.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1073_1074.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1073_1074.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1073_1074.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1073_1074.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1073_1074.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1073_1074.G(quantity = "ThermalConductance", unit = "W/K") = 2.59996243526793e-05 "Constant thermal conductance of material"; Real TC_1073_1084.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1073_1084.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1073_1084.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1073_1084.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1073_1084.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1073_1084.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1073_1084.G(quantity = "ThermalConductance", unit = "W/K") = 1.73332258739836e-05 "Constant thermal conductance of material"; Real TC_1073_1106.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1073_1106.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1073_1106.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1073_1106.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1073_1106.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1073_1106.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1073_1106.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650006464124112 "Constant thermal conductance of material"; Real TC_1074_1075.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1074_1075.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1074_1075.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1074_1075.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1074_1075.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1074_1075.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1074_1075.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999149912866e-05 "Constant thermal conductance of material"; Real TC_1074_1085.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1074_1085.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1074_1085.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1074_1085.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1074_1085.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1074_1085.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1074_1085.G(quantity = "ThermalConductance", unit = "W/K") = 1.7333582555743e-05 "Constant thermal conductance of material"; Real TC_1074_1107.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1074_1107.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1074_1107.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1074_1107.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1074_1107.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1074_1107.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1074_1107.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649991002339392 "Constant thermal conductance of material"; Real TC_1075_1076.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1075_1076.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1075_1076.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1075_1076.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1075_1076.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1075_1076.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1075_1076.G(quantity = "ThermalConductance", unit = "W/K") = 3.71427585387084e-05 "Constant thermal conductance of material"; Real TC_1075_1086.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1075_1086.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1075_1086.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1075_1086.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1075_1086.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1075_1086.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1075_1086.G(quantity = "ThermalConductance", unit = "W/K") = 1.73335213314181e-05 "Constant thermal conductance of material"; Real TC_1075_1108.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1075_1108.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1075_1108.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1075_1108.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1075_1108.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1075_1108.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1075_1108.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650002631855984 "Constant thermal conductance of material"; Real TC_1076_1087.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1076_1087.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1076_1087.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1076_1087.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1076_1087.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1076_1087.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1076_1087.G(quantity = "ThermalConductance", unit = "W/K") = 6.93335137502626e-06 "Constant thermal conductance of material"; Real TC_1076_1109.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1076_1109.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1076_1109.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1076_1109.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1076_1109.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1076_1109.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1076_1109.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259994020032894 "Constant thermal conductance of material"; Real TC_1077_1078.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1077_1078.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1077_1078.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1077_1078.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1077_1078.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1077_1078.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1077_1078.G(quantity = "ThermalConductance", unit = "W/K") = 7.42860670282027e-05 "Constant thermal conductance of material"; Real TC_1077_1088.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1077_1088.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1077_1088.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1077_1088.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1077_1088.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1077_1088.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1077_1088.G(quantity = "ThermalConductance", unit = "W/K") = 6.11767257822024e-06 "Constant thermal conductance of material"; Real TC_1077_1110.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1077_1110.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1077_1110.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1077_1110.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1077_1110.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1077_1110.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1077_1110.G(quantity = "ThermalConductance", unit = "W/K") = 0.000519980898660865 "Constant thermal conductance of material"; Real TC_1078_1079.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1078_1079.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1078_1079.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1078_1079.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1078_1079.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1078_1079.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1078_1079.G(quantity = "ThermalConductance", unit = "W/K") = 5.19995658361272e-05 "Constant thermal conductance of material"; Real TC_1078_1089.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1078_1089.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1078_1089.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1078_1089.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1078_1089.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1078_1089.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1078_1089.G(quantity = "ThermalConductance", unit = "W/K") = 1.52941940511755e-05 "Constant thermal conductance of material"; Real TC_1078_1608.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1078_1608.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1078_1608.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1078_1608.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1078_1608.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1078_1608.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1078_1608.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259835114737038 "Constant thermal conductance of material"; Real TC_1079_1080.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1079_1080.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1079_1080.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1079_1080.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1079_1080.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1079_1080.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1079_1080.G(quantity = "ThermalConductance", unit = "W/K") = 5.1996962115798e-05 "Constant thermal conductance of material"; Real TC_1079_1090.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1079_1090.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1079_1090.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1079_1090.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1079_1090.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1079_1090.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1079_1090.G(quantity = "ThermalConductance", unit = "W/K") = 1.52943282360763e-05 "Constant thermal conductance of material"; Real TC_1079_1609.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1079_1609.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1079_1609.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1079_1609.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1079_1609.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1079_1609.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1079_1609.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259831016718922 "Constant thermal conductance of material"; Real TC_1080_1081.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1080_1081.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1080_1081.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1080_1081.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1080_1081.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1080_1081.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1080_1081.G(quantity = "ThermalConductance", unit = "W/K") = 5.20014006692063e-05 "Constant thermal conductance of material"; Real TC_1080_1091.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1080_1091.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1080_1091.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1080_1091.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1080_1091.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1080_1091.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1080_1091.G(quantity = "ThermalConductance", unit = "W/K") = 1.52940784875012e-05 "Constant thermal conductance of material"; Real TC_1080_1610.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1080_1610.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1080_1610.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1080_1610.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1080_1610.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1080_1610.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1080_1610.G(quantity = "ThermalConductance", unit = "W/K") = 0.0025983122164776 "Constant thermal conductance of material"; Real TC_1081_1082.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1081_1082.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1081_1082.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1081_1082.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1081_1082.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1081_1082.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1081_1082.G(quantity = "ThermalConductance", unit = "W/K") = 5.20040760869547e-05 "Constant thermal conductance of material"; Real TC_1081_1611.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1081_1611.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1081_1611.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1081_1611.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1081_1611.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1081_1611.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1081_1611.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259832082639201 "Constant thermal conductance of material"; Real TC_1081_1635.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1081_1635.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1081_1635.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1081_1635.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1081_1635.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1081_1635.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1081_1635.G(quantity = "ThermalConductance", unit = "W/K") = 2.59061437833824e-05 "Constant thermal conductance of material"; Real TC_1082_1083.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1082_1083.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1082_1083.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1082_1083.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1082_1083.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1082_1083.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1082_1083.G(quantity = "ThermalConductance", unit = "W/K") = 5.19991766582615e-05 "Constant thermal conductance of material"; Real TC_1082_1612.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1082_1612.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1082_1612.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1082_1612.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1082_1612.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1082_1612.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1082_1612.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259832899219811 "Constant thermal conductance of material"; Real TC_1082_1636.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1082_1636.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1082_1636.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1082_1636.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1082_1636.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1082_1636.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1082_1636.G(quantity = "ThermalConductance", unit = "W/K") = 2.59050873551404e-05 "Constant thermal conductance of material"; Real TC_1083_1084.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1083_1084.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1083_1084.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1083_1084.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1083_1084.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1083_1084.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1083_1084.G(quantity = "ThermalConductance", unit = "W/K") = 5.19994151619266e-05 "Constant thermal conductance of material"; Real TC_1083_1613.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1083_1613.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1083_1613.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1083_1613.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1083_1613.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1083_1613.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1083_1613.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259831023086181 "Constant thermal conductance of material"; Real TC_1083_1637.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1083_1637.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1083_1637.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1083_1637.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1083_1637.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1083_1637.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1083_1637.G(quantity = "ThermalConductance", unit = "W/K") = 2.59056246288424e-05 "Constant thermal conductance of material"; Real TC_1084_1085.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1084_1085.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1084_1085.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1084_1085.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1084_1085.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1084_1085.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1084_1085.G(quantity = "ThermalConductance", unit = "W/K") = 5.20009193758467e-05 "Constant thermal conductance of material"; Real TC_1084_1614.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1084_1614.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1084_1614.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1084_1614.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1084_1614.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1084_1614.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1084_1614.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259831422196382 "Constant thermal conductance of material"; Real TC_1084_1638.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1084_1638.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1084_1638.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1084_1638.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1084_1638.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1084_1638.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1084_1638.G(quantity = "ThermalConductance", unit = "W/K") = 2.59052557567235e-05 "Constant thermal conductance of material"; Real TC_1085_1086.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1085_1086.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1085_1086.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1085_1086.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1085_1086.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1085_1086.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1085_1086.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000615209881e-05 "Constant thermal conductance of material"; Real TC_1085_1092.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1085_1092.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1085_1092.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1085_1092.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1085_1092.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1085_1092.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1085_1092.G(quantity = "ThermalConductance", unit = "W/K") = 1.5294452887538e-05 "Constant thermal conductance of material"; Real TC_1085_1615.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1085_1615.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1085_1615.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1085_1615.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1085_1615.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1085_1615.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1085_1615.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259831695328094 "Constant thermal conductance of material"; Real TC_1086_1087.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1086_1087.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1086_1087.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1086_1087.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1086_1087.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1086_1087.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1086_1087.G(quantity = "ThermalConductance", unit = "W/K") = 7.4284806799264e-05 "Constant thermal conductance of material"; Real TC_1086_1093.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1086_1093.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1086_1093.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1086_1093.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1086_1093.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1086_1093.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1086_1093.G(quantity = "ThermalConductance", unit = "W/K") = 1.52941176470588e-05 "Constant thermal conductance of material"; Real TC_1086_1616.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1086_1616.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1086_1616.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1086_1616.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1086_1616.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1086_1616.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1086_1616.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259825585401143 "Constant thermal conductance of material"; Real TC_1087_1094.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1087_1094.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1087_1094.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1087_1094.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1087_1094.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1087_1094.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1087_1094.G(quantity = "ThermalConductance", unit = "W/K") = 6.11775956647053e-06 "Constant thermal conductance of material"; Real TC_1087_1111.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1087_1111.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1087_1111.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1087_1111.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1087_1111.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1087_1111.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1087_1111.G(quantity = "ThermalConductance", unit = "W/K") = 0.00052 "Constant thermal conductance of material"; Real TC_1088_1089.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1088_1089.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1088_1089.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1088_1089.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1088_1089.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1088_1089.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1088_1089.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001593026325e-05 "Constant thermal conductance of material"; Real TC_1088_1095.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1088_1095.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1088_1095.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1088_1095.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1088_1095.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1088_1095.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1088_1095.G(quantity = "ThermalConductance", unit = "W/K") = 7.42863800535946e-06 "Constant thermal conductance of material"; Real TC_1088_1112.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1088_1112.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1088_1112.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1088_1112.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1088_1112.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1088_1112.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1088_1112.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363998488648788 "Constant thermal conductance of material"; Real TC_1089_1090.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1089_1090.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1089_1090.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1089_1090.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1089_1090.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1089_1090.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1089_1090.G(quantity = "ThermalConductance", unit = "W/K") = 3.64003041317408e-05 "Constant thermal conductance of material"; Real TC_1089_1096.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1089_1096.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1089_1096.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1089_1096.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1089_1096.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1089_1096.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1089_1096.G(quantity = "ThermalConductance", unit = "W/K") = 1.85712820512818e-05 "Constant thermal conductance of material"; Real TC_1089_1617.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1089_1617.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1089_1617.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1089_1617.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1089_1617.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1089_1617.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1089_1617.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181880537881541 "Constant thermal conductance of material"; Real TC_1090_1091.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1090_1091.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1090_1091.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1090_1091.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1090_1091.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1090_1091.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1090_1091.G(quantity = "ThermalConductance", unit = "W/K") = 3.63994862611028e-05 "Constant thermal conductance of material"; Real TC_1090_1097.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1090_1097.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1090_1097.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1090_1097.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1090_1097.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1090_1097.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1090_1097.G(quantity = "ThermalConductance", unit = "W/K") = 1.85715170086981e-05 "Constant thermal conductance of material"; Real TC_1090_1618.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1090_1618.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1090_1618.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1090_1618.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1090_1618.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1090_1618.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1090_1618.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181881896716746 "Constant thermal conductance of material"; Real TC_1091_1098.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1091_1098.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1091_1098.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1091_1098.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1091_1098.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1091_1098.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1091_1098.G(quantity = "ThermalConductance", unit = "W/K") = 1.85715473517918e-05 "Constant thermal conductance of material"; Real TC_1091_1619.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1091_1619.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1091_1619.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1091_1619.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1091_1619.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1091_1619.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1091_1619.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181881377140125 "Constant thermal conductance of material"; Real TC_1091_1635.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1091_1635.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1091_1635.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1091_1635.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1091_1635.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1091_1635.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1091_1635.G(quantity = "ThermalConductance", unit = "W/K") = 7.24245466188766e-05 "Constant thermal conductance of material"; Real TC_1092_1093.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1092_1093.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1092_1093.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1092_1093.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1092_1093.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1092_1093.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1092_1093.G(quantity = "ThermalConductance", unit = "W/K") = 3.63993717997565e-05 "Constant thermal conductance of material"; Real TC_1092_1624.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1092_1624.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1092_1624.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1092_1624.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1092_1624.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1092_1624.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1092_1624.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181881206995164 "Constant thermal conductance of material"; Real TC_1092_1638.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1092_1638.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1092_1638.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1092_1638.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1092_1638.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1092_1638.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1092_1638.G(quantity = "ThermalConductance", unit = "W/K") = 7.24223765229923e-05 "Constant thermal conductance of material"; Real TC_1093_1094.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1093_1094.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1093_1094.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1093_1094.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1093_1094.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1093_1094.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1093_1094.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000121470522e-05 "Constant thermal conductance of material"; Real TC_1093_1625.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1093_1625.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1093_1625.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1093_1625.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1093_1625.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1093_1625.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1093_1625.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181880852218754 "Constant thermal conductance of material"; Real TC_1094_1113.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1094_1113.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1094_1113.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1094_1113.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1094_1113.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1094_1113.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1094_1113.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363997089181821 "Constant thermal conductance of material"; Real TC_1095_1096.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1095_1096.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1095_1096.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1095_1096.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1095_1096.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1095_1096.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1095_1096.G(quantity = "ThermalConductance", unit = "W/K") = 5.1999661332656e-05 "Constant thermal conductance of material"; Real TC_1095_1114.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1095_1114.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1095_1114.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1095_1114.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1095_1114.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1095_1114.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1095_1114.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363999711940084 "Constant thermal conductance of material"; Real TC_1096_1097.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1096_1097.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1096_1097.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1096_1097.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1096_1097.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1096_1097.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1096_1097.G(quantity = "ThermalConductance", unit = "W/K") = 3.6399621297507e-05 "Constant thermal conductance of material"; Real TC_1096_1626.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1096_1626.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1096_1626.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1096_1626.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1096_1626.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1096_1626.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1096_1626.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181882157744554 "Constant thermal conductance of material"; Real TC_1097_1098.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1097_1098.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1097_1098.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1097_1098.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1097_1098.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1097_1098.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1097_1098.G(quantity = "ThermalConductance", unit = "W/K") = 3.63999661332656e-05 "Constant thermal conductance of material"; Real TC_1097_1627.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1097_1627.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1097_1627.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1097_1627.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1097_1627.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1097_1627.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1097_1627.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181881111283563 "Constant thermal conductance of material"; Real TC_1098_1628.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1098_1628.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1098_1628.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1098_1628.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1098_1628.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1098_1628.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1098_1628.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181881695388914 "Constant thermal conductance of material"; Real TC_1098_1639.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1098_1639.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1098_1639.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1098_1639.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1098_1639.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1098_1639.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1098_1639.G(quantity = "ThermalConductance", unit = "W/K") = 7.24243788888817e-05 "Constant thermal conductance of material"; Real TC_1099_1100.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1099_1100.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1099_1100.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1099_1100.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1099_1100.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1099_1100.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1099_1100.G(quantity = "ThermalConductance", unit = "W/K") = 3.7142539824523e-05 "Constant thermal conductance of material"; Real TC_1099_1110.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1099_1110.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1099_1110.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1099_1110.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1099_1110.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1099_1110.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1099_1110.G(quantity = "ThermalConductance", unit = "W/K") = 6.93333283787851e-06 "Constant thermal conductance of material"; Real TC_1099_1145.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1099_1145.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1099_1145.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1099_1145.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1099_1145.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1099_1145.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1099_1145.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260014054813772 "Constant thermal conductance of material"; Real TC_1100_1101.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1100_1101.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1100_1101.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1100_1101.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1100_1101.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1100_1101.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1100_1101.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004740647098e-05 "Constant thermal conductance of material"; Real TC_1100_1146.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1100_1146.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1100_1146.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1100_1146.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1100_1146.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1100_1146.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1100_1146.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650004293196715 "Constant thermal conductance of material"; Real TC_1100_1608.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1100_1608.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1100_1608.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1100_1608.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1100_1608.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1100_1608.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1100_1608.G(quantity = "ThermalConductance", unit = "W/K") = 5.19341282468051e-05 "Constant thermal conductance of material"; Real TC_1101_1102.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1101_1102.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1101_1102.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1101_1102.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1101_1102.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1101_1102.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1101_1102.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997267759563e-05 "Constant thermal conductance of material"; Real TC_1101_1147.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1101_1147.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1101_1147.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1101_1147.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1101_1147.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1101_1147.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1101_1147.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649998540870222 "Constant thermal conductance of material"; Real TC_1101_1609.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1101_1609.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1101_1609.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1101_1609.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1101_1609.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1101_1609.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1101_1609.G(quantity = "ThermalConductance", unit = "W/K") = 5.193125735753e-05 "Constant thermal conductance of material"; Real TC_1102_1103.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1102_1103.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1102_1103.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1102_1103.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1102_1103.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1102_1103.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1102_1103.G(quantity = "ThermalConductance", unit = "W/K") = 2.6000982731995e-05 "Constant thermal conductance of material"; Real TC_1102_1148.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1102_1148.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1102_1148.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1102_1148.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1102_1148.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1102_1148.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1102_1148.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650000741366783 "Constant thermal conductance of material"; Real TC_1102_1610.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1102_1610.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1102_1610.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1102_1610.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1102_1610.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1102_1610.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1102_1610.G(quantity = "ThermalConductance", unit = "W/K") = 5.19338790748154e-05 "Constant thermal conductance of material"; Real TC_1103_1104.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1103_1104.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1103_1104.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1103_1104.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1103_1104.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1103_1104.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1103_1104.G(quantity = "ThermalConductance", unit = "W/K") = 2.59895316804428e-05 "Constant thermal conductance of material"; Real TC_1103_1149.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1103_1149.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1103_1149.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1103_1149.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1103_1149.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1103_1149.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1103_1149.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650003711676937 "Constant thermal conductance of material"; Real TC_1103_1611.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1103_1611.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1103_1611.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1103_1611.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1103_1611.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1103_1611.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1103_1611.G(quantity = "ThermalConductance", unit = "W/K") = 5.19305235742068e-05 "Constant thermal conductance of material"; Real TC_1104_1105.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1104_1105.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1104_1105.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1104_1105.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1104_1105.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1104_1105.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1104_1105.G(quantity = "ThermalConductance", unit = "W/K") = 2.5998389694042e-05 "Constant thermal conductance of material"; Real TC_1104_1150.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1104_1150.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1104_1150.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1104_1150.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1104_1150.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1104_1150.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1104_1150.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649993300879821 "Constant thermal conductance of material"; Real TC_1104_1612.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1104_1612.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1104_1612.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1104_1612.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1104_1612.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1104_1612.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1104_1612.G(quantity = "ThermalConductance", unit = "W/K") = 5.19313767662971e-05 "Constant thermal conductance of material"; Real TC_1105_1106.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1105_1106.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1105_1106.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1105_1106.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1105_1106.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1105_1106.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1105_1106.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997708918034e-05 "Constant thermal conductance of material"; Real TC_1105_1151.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1105_1151.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1105_1151.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1105_1151.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1105_1151.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1105_1151.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1105_1151.G(quantity = "ThermalConductance", unit = "W/K") = 0.00065000374728322 "Constant thermal conductance of material"; Real TC_1105_1613.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1105_1613.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1105_1613.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1105_1613.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1105_1613.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1105_1613.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1105_1613.G(quantity = "ThermalConductance", unit = "W/K") = 5.1934605450824e-05 "Constant thermal conductance of material"; Real TC_1106_1107.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1106_1107.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1106_1107.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1106_1107.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1106_1107.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1106_1107.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1106_1107.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003802178106e-05 "Constant thermal conductance of material"; Real TC_1106_1152.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1106_1152.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1106_1152.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1106_1152.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1106_1152.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1106_1152.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1106_1152.G(quantity = "ThermalConductance", unit = "W/K") = 0.00065000605107104 "Constant thermal conductance of material"; Real TC_1106_1614.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1106_1614.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1106_1614.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1106_1614.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1106_1614.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1106_1614.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1106_1614.G(quantity = "ThermalConductance", unit = "W/K") = 5.19325768872912e-05 "Constant thermal conductance of material"; Real TC_1107_1108.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1107_1108.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1107_1108.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1107_1108.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1107_1108.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1107_1108.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1107_1108.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003753362388e-05 "Constant thermal conductance of material"; Real TC_1107_1153.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1107_1153.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1107_1153.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1107_1153.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1107_1153.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1107_1153.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1107_1153.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649989361378763 "Constant thermal conductance of material"; Real TC_1107_1615.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1107_1615.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1107_1615.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1107_1615.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1107_1615.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1107_1615.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1107_1615.G(quantity = "ThermalConductance", unit = "W/K") = 5.19343883077515e-05 "Constant thermal conductance of material"; Real TC_1108_1109.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1108_1109.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1108_1109.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1108_1109.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1108_1109.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1108_1109.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1108_1109.G(quantity = "ThermalConductance", unit = "W/K") = 3.71432016994591e-05 "Constant thermal conductance of material"; Real TC_1108_1154.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1108_1154.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1108_1154.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1108_1154.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1108_1154.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1108_1154.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1108_1154.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649990803752067 "Constant thermal conductance of material"; Real TC_1108_1616.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1108_1616.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1108_1616.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1108_1616.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1108_1616.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1108_1616.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1108_1616.G(quantity = "ThermalConductance", unit = "W/K") = 5.19307028744569e-05 "Constant thermal conductance of material"; Real TC_1109_1111.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1109_1111.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1109_1111.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1109_1111.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1109_1111.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1109_1111.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1109_1111.G(quantity = "ThermalConductance", unit = "W/K") = 6.93330472943668e-06 "Constant thermal conductance of material"; Real TC_1109_1155.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1109_1155.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1109_1155.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1109_1155.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1109_1155.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1109_1155.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1109_1155.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260012505862132 "Constant thermal conductance of material"; Real TC_1110_1112.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1110_1112.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1110_1112.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1110_1112.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1110_1112.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1110_1112.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1110_1112.G(quantity = "ThermalConductance", unit = "W/K") = 6.11764192393867e-06 "Constant thermal conductance of material"; Real TC_1110_1156.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1110_1156.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1110_1156.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1110_1156.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1110_1156.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1110_1156.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1110_1156.G(quantity = "ThermalConductance", unit = "W/K") = 0.000520008469193309 "Constant thermal conductance of material"; Real TC_1110_1608.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1110_1608.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1110_1608.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1110_1608.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1110_1608.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1110_1608.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1110_1608.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259578678985402 "Constant thermal conductance of material"; Real TC_1111_1113.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1111_1113.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1111_1113.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1111_1113.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1111_1113.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1111_1113.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1111_1113.G(quantity = "ThermalConductance", unit = "W/K") = 6.11784867877627e-06 "Constant thermal conductance of material"; Real TC_1111_1166.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1111_1166.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1111_1166.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1111_1166.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1111_1166.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1111_1166.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1111_1166.G(quantity = "ThermalConductance", unit = "W/K") = 0.000519985932568881 "Constant thermal conductance of material"; Real TC_1111_1616.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1111_1616.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1111_1616.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1111_1616.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1111_1616.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1111_1616.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1111_1616.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259577947264341 "Constant thermal conductance of material"; Real TC_1112_1114.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1112_1114.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1112_1114.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1112_1114.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1112_1114.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1112_1114.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1112_1114.G(quantity = "ThermalConductance", unit = "W/K") = 7.42872436330858e-06 "Constant thermal conductance of material"; Real TC_1112_1167.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1112_1167.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1112_1167.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1112_1167.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1112_1167.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1112_1167.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1112_1167.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363998226608582 "Constant thermal conductance of material"; Real TC_1112_1617.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1112_1617.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1112_1617.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1112_1617.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1112_1617.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1112_1617.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1112_1617.G(quantity = "ThermalConductance", unit = "W/K") = 0.000181706070811037 "Constant thermal conductance of material"; Real TC_1113_1115.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1113_1115.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1113_1115.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1113_1115.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1113_1115.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1113_1115.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1113_1115.G(quantity = "ThermalConductance", unit = "W/K") = 7.42857693642285e-06 "Constant thermal conductance of material"; Real TC_1113_1173.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1113_1173.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1113_1173.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1113_1173.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1113_1173.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1113_1173.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1113_1173.G(quantity = "ThermalConductance", unit = "W/K") = 0.000364001441044334 "Constant thermal conductance of material"; Real TC_1113_1625.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1113_1625.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1113_1625.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1113_1625.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1113_1625.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1113_1625.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1113_1625.G(quantity = "ThermalConductance", unit = "W/K") = 0.000181704531828802 "Constant thermal conductance of material"; Real TC_1114_1116.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1114_1116.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1114_1116.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1114_1116.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1114_1116.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1114_1116.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1114_1116.G(quantity = "ThermalConductance", unit = "W/K") = 7.42845223195598e-06 "Constant thermal conductance of material"; Real TC_1114_1174.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1114_1174.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1114_1174.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1114_1174.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1114_1174.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1114_1174.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1114_1174.G(quantity = "ThermalConductance", unit = "W/K") = 0.000364002475271839 "Constant thermal conductance of material"; Real TC_1114_1626.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1114_1626.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1114_1626.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1114_1626.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1114_1626.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1114_1626.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1114_1626.G(quantity = "ThermalConductance", unit = "W/K") = 0.000181701941727143 "Constant thermal conductance of material"; Real TC_1115_1117.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1115_1117.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1115_1117.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1115_1117.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1115_1117.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1115_1117.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1115_1117.G(quantity = "ThermalConductance", unit = "W/K") = 7.42884650099283e-06 "Constant thermal conductance of material"; Real TC_1115_1180.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1115_1180.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1115_1180.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1115_1180.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1115_1180.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1115_1180.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1115_1180.G(quantity = "ThermalConductance", unit = "W/K") = 0.000364001106806863 "Constant thermal conductance of material"; Real TC_1115_1634.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1115_1634.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1115_1634.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1115_1634.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1115_1634.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1115_1634.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1115_1634.G(quantity = "ThermalConductance", unit = "W/K") = 0.000181706404168912 "Constant thermal conductance of material"; Real TC_1116_1118.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1116_1118.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1116_1118.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1116_1118.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1116_1118.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1116_1118.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1116_1118.G(quantity = "ThermalConductance", unit = "W/K") = 4.95245455669588e-06 "Constant thermal conductance of material"; Real TC_1116_1181.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1116_1181.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1116_1181.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1116_1181.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1116_1181.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1116_1181.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1116_1181.G(quantity = "ThermalConductance", unit = "W/K") = 0.000364001288500136 "Constant thermal conductance of material"; Real TC_1116_1563.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1116_1563.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1116_1563.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1116_1563.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1116_1563.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1116_1563.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1116_1563.G(quantity = "ThermalConductance", unit = "W/K") = 0.00018170229304314 "Constant thermal conductance of material"; Real TC_1117_1119.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1117_1119.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1117_1119.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1117_1119.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1117_1119.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1117_1119.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1117_1119.G(quantity = "ThermalConductance", unit = "W/K") = 4.95233615553455e-06 "Constant thermal conductance of material"; Real TC_1117_1187.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1117_1187.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1117_1187.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1117_1187.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1117_1187.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1117_1187.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1117_1187.G(quantity = "ThermalConductance", unit = "W/K") = 0.000364000382491452 "Constant thermal conductance of material"; Real TC_1117_1571.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1117_1571.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1117_1571.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1117_1571.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1117_1571.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1117_1571.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1117_1571.G(quantity = "ThermalConductance", unit = "W/K") = 0.000181705476380977 "Constant thermal conductance of material"; Real TC_1118_1120.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1118_1120.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1118_1120.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1118_1120.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1118_1120.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1118_1120.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1118_1120.G(quantity = "ThermalConductance", unit = "W/K") = 5.47375092426319e-06 "Constant thermal conductance of material"; Real TC_1118_1188.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1118_1188.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1118_1188.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1118_1188.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1118_1188.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1118_1188.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1118_1188.G(quantity = "ThermalConductance", unit = "W/K") = 0.000728017457432319 "Constant thermal conductance of material"; Real TC_1118_1572.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1118_1572.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1118_1572.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1118_1572.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1118_1572.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1118_1572.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1118_1572.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363410154105387 "Constant thermal conductance of material"; Real TC_1119_1121.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1119_1121.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1119_1121.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1119_1121.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1119_1121.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1119_1121.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1119_1121.G(quantity = "ThermalConductance", unit = "W/K") = 5.47367467697148e-06 "Constant thermal conductance of material"; Real TC_1119_1198.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1119_1198.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1119_1198.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1119_1198.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1119_1198.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1119_1198.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1119_1198.G(quantity = "ThermalConductance", unit = "W/K") = 0.000728012040239747 "Constant thermal conductance of material"; Real TC_1119_1580.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1119_1580.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1119_1580.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1119_1580.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1119_1580.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1119_1580.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1119_1580.G(quantity = "ThermalConductance", unit = "W/K") = 0.00036341278489125 "Constant thermal conductance of material"; Real TC_1120_1122.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1120_1122.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1120_1122.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1120_1122.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1120_1122.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1120_1122.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1120_1122.G(quantity = "ThermalConductance", unit = "W/K") = 1.04003175323205e-05 "Constant thermal conductance of material"; Real TC_1120_1199.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1120_1199.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1120_1199.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1120_1199.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1120_1199.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1120_1199.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1120_1199.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260000801466684 "Constant thermal conductance of material"; Real TC_1120_1581.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1120_1581.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1120_1581.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1120_1581.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1120_1581.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1120_1581.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1120_1581.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129789376394827 "Constant thermal conductance of material"; Real TC_1121_1123.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1121_1123.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1121_1123.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1121_1123.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1121_1123.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1121_1123.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1121_1123.G(quantity = "ThermalConductance", unit = "W/K") = 1.04005872483217e-05 "Constant thermal conductance of material"; Real TC_1121_1206.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1121_1206.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1121_1206.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1121_1206.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1121_1206.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1121_1206.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1121_1206.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260000283998127 "Constant thermal conductance of material"; Real TC_1121_1589.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1121_1589.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1121_1589.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1121_1589.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1121_1589.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1121_1589.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1121_1589.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129790764172948 "Constant thermal conductance of material"; Real TC_1122_1124.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1122_1124.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1122_1124.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1122_1124.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1122_1124.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1122_1124.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1122_1124.G(quantity = "ThermalConductance", unit = "W/K") = 1.03999007485215e-05 "Constant thermal conductance of material"; Real TC_1122_1207.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1122_1207.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1122_1207.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1122_1207.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1122_1207.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1122_1207.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1122_1207.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259997728069699 "Constant thermal conductance of material"; Real TC_1122_1590.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1122_1590.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1122_1590.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1122_1590.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1122_1590.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1122_1590.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1122_1590.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129789982743825 "Constant thermal conductance of material"; Real TC_1123_1125.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1123_1125.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1123_1125.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1123_1125.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1123_1125.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1123_1125.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1123_1125.G(quantity = "ThermalConductance", unit = "W/K") = 1.04020000000021e-05 "Constant thermal conductance of material"; Real TC_1123_1214.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1123_1214.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1123_1214.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1123_1214.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1123_1214.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1123_1214.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1123_1214.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259992930364086 "Constant thermal conductance of material"; Real TC_1123_1598.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1123_1598.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1123_1598.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1123_1598.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1123_1598.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1123_1598.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1123_1598.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129788044038204 "Constant thermal conductance of material"; Real TC_1124_1126.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1124_1126.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1124_1126.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1124_1126.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1124_1126.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1124_1126.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1124_1126.G(quantity = "ThermalConductance", unit = "W/K") = 1.04000644615446e-05 "Constant thermal conductance of material"; Real TC_1124_1215.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1124_1215.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1124_1215.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1124_1215.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1124_1215.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1124_1215.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1124_1215.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001351860257 "Constant thermal conductance of material"; Real TC_1124_1599.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1124_1599.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1124_1599.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1124_1599.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1124_1599.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1124_1599.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1124_1599.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129791889838035 "Constant thermal conductance of material"; Real TC_1125_1127.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1125_1127.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1125_1127.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1125_1127.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1125_1127.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1125_1127.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1125_1127.G(quantity = "ThermalConductance", unit = "W/K") = 1.04001655857597e-05 "Constant thermal conductance of material"; Real TC_1125_1222.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1125_1222.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1125_1222.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1125_1222.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1125_1222.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1125_1222.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1125_1222.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259995221967706 "Constant thermal conductance of material"; Real TC_1125_1607.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1125_1607.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1125_1607.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1125_1607.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1125_1607.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1125_1607.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1125_1607.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129788987849044 "Constant thermal conductance of material"; Real TC_1126_1128.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1126_1128.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1126_1128.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1126_1128.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1126_1128.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1126_1128.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1126_1128.G(quantity = "ThermalConductance", unit = "W/K") = 1.0399366085574e-05 "Constant thermal conductance of material"; Real TC_1126_1223.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1126_1223.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1126_1223.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1126_1223.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1126_1223.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1126_1223.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1126_1223.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260000470333702 "Constant thermal conductance of material"; Real TC_1126_1527.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1126_1527.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1126_1527.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1126_1527.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1126_1527.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1126_1527.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1126_1527.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129791894523214 "Constant thermal conductance of material"; Real TC_1127_1129.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1127_1129.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1127_1129.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1127_1129.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1127_1129.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1127_1129.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1127_1129.G(quantity = "ThermalConductance", unit = "W/K") = 1.03998231430013e-05 "Constant thermal conductance of material"; Real TC_1127_1230.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1127_1230.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1127_1230.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1127_1230.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1127_1230.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1127_1230.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1127_1230.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259993832697912 "Constant thermal conductance of material"; Real TC_1127_1535.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1127_1535.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1127_1535.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1127_1535.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1127_1535.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1127_1535.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1127_1535.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129791362527295 "Constant thermal conductance of material"; Real TC_1128_1130.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1128_1130.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1128_1130.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1128_1130.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1128_1130.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1128_1130.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1128_1130.G(quantity = "ThermalConductance", unit = "W/K") = 1.0399987539329e-05 "Constant thermal conductance of material"; Real TC_1128_1231.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1128_1231.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1128_1231.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1128_1231.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1128_1231.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1128_1231.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1128_1231.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259997310868264 "Constant thermal conductance of material"; Real TC_1128_1536.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1128_1536.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1128_1536.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1128_1536.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1128_1536.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1128_1536.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1128_1536.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129786004298166 "Constant thermal conductance of material"; Real TC_1129_1131.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1129_1131.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1129_1131.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1129_1131.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1129_1131.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1129_1131.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1129_1131.G(quantity = "ThermalConductance", unit = "W/K") = 1.04000978832743e-05 "Constant thermal conductance of material"; Real TC_1129_1238.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1129_1238.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1129_1238.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1129_1238.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1129_1238.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1129_1238.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1129_1238.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001720726148 "Constant thermal conductance of material"; Real TC_1129_1544.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1129_1544.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1129_1544.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1129_1544.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1129_1544.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1129_1544.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1129_1544.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129786005848889 "Constant thermal conductance of material"; Real TC_1130_1132.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1130_1132.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1130_1132.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1130_1132.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1130_1132.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1130_1132.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1130_1132.G(quantity = "ThermalConductance", unit = "W/K") = 5.20003234856825e-06 "Constant thermal conductance of material"; Real TC_1130_1239.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1130_1239.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1130_1239.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1130_1239.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1130_1239.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1130_1239.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1130_1239.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259998900968064 "Constant thermal conductance of material"; Real TC_1130_1545.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1130_1545.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1130_1545.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1130_1545.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1130_1545.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1130_1545.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1130_1545.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129791916730916 "Constant thermal conductance of material"; Real TC_1131_1133.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1131_1133.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1131_1133.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1131_1133.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1131_1133.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1131_1133.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1131_1133.G(quantity = "ThermalConductance", unit = "W/K") = 5.19991129915065e-06 "Constant thermal conductance of material"; Real TC_1131_1246.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1131_1246.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1131_1246.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1131_1246.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1131_1246.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1131_1246.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1131_1246.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260003919263178 "Constant thermal conductance of material"; Real TC_1131_1553.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1131_1553.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1131_1553.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1131_1553.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1131_1553.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1131_1553.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1131_1553.G(quantity = "ThermalConductance", unit = "W/K") = 0.000129791893661119 "Constant thermal conductance of material"; Real TC_1132_1134.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1132_1134.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1132_1134.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1132_1134.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1132_1134.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1132_1134.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1132_1134.G(quantity = "ThermalConductance", unit = "W/K") = 5.19996601384936e-06 "Constant thermal conductance of material"; Real TC_1132_1247.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1132_1247.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1132_1247.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1132_1247.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1132_1247.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1132_1247.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1132_1247.G(quantity = "ThermalConductance", unit = "W/K") = 0.0007799777437168 "Constant thermal conductance of material"; Real TC_1132_1554.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1132_1554.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1132_1554.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1132_1554.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1132_1554.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1132_1554.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1132_1554.G(quantity = "ThermalConductance", unit = "W/K") = 0.000389364436261401 "Constant thermal conductance of material"; Real TC_1133_1144.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1133_1144.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1133_1144.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1133_1144.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1133_1144.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1133_1144.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1133_1144.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001939154617e-06 "Constant thermal conductance of material"; Real TC_1133_1257.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1133_1257.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1133_1257.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1133_1257.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1133_1257.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1133_1257.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1133_1257.G(quantity = "ThermalConductance", unit = "W/K") = 0.00077999656266403 "Constant thermal conductance of material"; Real TC_1133_1562.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1133_1562.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1133_1562.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1133_1562.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1133_1562.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1133_1562.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1133_1562.G(quantity = "ThermalConductance", unit = "W/K") = 0.000389370196783916 "Constant thermal conductance of material"; Real TC_1134_1135.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1134_1135.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1134_1135.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1134_1135.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1134_1135.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1134_1135.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1134_1135.G(quantity = "ThermalConductance", unit = "W/K") = 3.7142480889463e-05 "Constant thermal conductance of material"; Real TC_1134_1258.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1134_1258.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1134_1258.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1134_1258.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1134_1258.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1134_1258.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1134_1258.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260013876040709 "Constant thermal conductance of material"; Real TC_1135_1136.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1135_1136.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1135_1136.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1135_1136.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1135_1136.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1135_1136.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1135_1136.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997540442942e-05 "Constant thermal conductance of material"; Real TC_1135_1259.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1135_1259.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1135_1259.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1135_1259.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1135_1259.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1135_1259.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1135_1259.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650004547757958 "Constant thermal conductance of material"; Real TC_1135_1554.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1135_1554.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1135_1554.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1135_1554.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1135_1554.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1135_1554.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1135_1554.G(quantity = "ThermalConductance", unit = "W/K") = 5.18987282162692e-05 "Constant thermal conductance of material"; Real TC_1136_1137.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1136_1137.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1136_1137.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1136_1137.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1136_1137.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1136_1137.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1136_1137.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004266970095e-05 "Constant thermal conductance of material"; Real TC_1136_1260.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1136_1260.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1136_1260.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1136_1260.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1136_1260.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1136_1260.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1136_1260.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650001946307852 "Constant thermal conductance of material"; Real TC_1136_1555.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1136_1555.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1136_1555.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1136_1555.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1136_1555.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1136_1555.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1136_1555.G(quantity = "ThermalConductance", unit = "W/K") = 5.18989486450094e-05 "Constant thermal conductance of material"; Real TC_1137_1138.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1137_1138.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1137_1138.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1137_1138.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1137_1138.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1137_1138.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1137_1138.G(quantity = "ThermalConductance", unit = "W/K") = 2.60013273602143e-05 "Constant thermal conductance of material"; Real TC_1137_1261.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1137_1261.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1137_1261.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1137_1261.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1137_1261.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1137_1261.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1137_1261.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649994728240812 "Constant thermal conductance of material"; Real TC_1137_1556.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1137_1556.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1137_1556.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1137_1556.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1137_1556.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1137_1556.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1137_1556.G(quantity = "ThermalConductance", unit = "W/K") = 5.19006838765326e-05 "Constant thermal conductance of material"; Real TC_1138_1139.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1138_1139.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1138_1139.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1138_1139.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1138_1139.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1138_1139.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1138_1139.G(quantity = "ThermalConductance", unit = "W/K") = 2.60020202020192e-05 "Constant thermal conductance of material"; Real TC_1138_1262.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1138_1262.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1138_1262.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1138_1262.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1138_1262.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1138_1262.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1138_1262.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650011361965489 "Constant thermal conductance of material"; Real TC_1138_1557.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1138_1557.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1138_1557.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1138_1557.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1138_1557.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1138_1557.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1138_1557.G(quantity = "ThermalConductance", unit = "W/K") = 5.19002982813943e-05 "Constant thermal conductance of material"; Real TC_1139_1140.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1139_1140.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1139_1140.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1139_1140.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1139_1140.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1139_1140.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1139_1140.G(quantity = "ThermalConductance", unit = "W/K") = 2.60007549306409e-05 "Constant thermal conductance of material"; Real TC_1139_1263.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1139_1263.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1139_1263.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1139_1263.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1139_1263.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1139_1263.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1139_1263.G(quantity = "ThermalConductance", unit = "W/K") = 0.00064999320744464 "Constant thermal conductance of material"; Real TC_1139_1558.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1139_1558.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1139_1558.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1139_1558.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1139_1558.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1139_1558.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1139_1558.G(quantity = "ThermalConductance", unit = "W/K") = 5.189827937243e-05 "Constant thermal conductance of material"; Real TC_1140_1141.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1140_1141.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1140_1141.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1140_1141.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1140_1141.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1140_1141.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1140_1141.G(quantity = "ThermalConductance", unit = "W/K") = 2.600058685446e-05 "Constant thermal conductance of material"; Real TC_1140_1264.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1140_1264.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1140_1264.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1140_1264.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1140_1264.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1140_1264.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1140_1264.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650002066428798 "Constant thermal conductance of material"; Real TC_1140_1559.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1140_1559.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1140_1559.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1140_1559.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1140_1559.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1140_1559.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1140_1559.G(quantity = "ThermalConductance", unit = "W/K") = 5.18969364121355e-05 "Constant thermal conductance of material"; Real TC_1141_1142.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1141_1142.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1141_1142.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1141_1142.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1141_1142.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1141_1142.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1141_1142.G(quantity = "ThermalConductance", unit = "W/K") = 2.59995678212014e-05 "Constant thermal conductance of material"; Real TC_1141_1265.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1141_1265.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1141_1265.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1141_1265.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1141_1265.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1141_1265.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1141_1265.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649998610223203 "Constant thermal conductance of material"; Real TC_1141_1560.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1141_1560.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1141_1560.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1141_1560.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1141_1560.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1141_1560.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1141_1560.G(quantity = "ThermalConductance", unit = "W/K") = 5.18970175232522e-05 "Constant thermal conductance of material"; Real TC_1142_1143.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1142_1143.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1142_1143.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1142_1143.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1142_1143.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1142_1143.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1142_1143.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001171440286e-05 "Constant thermal conductance of material"; Real TC_1142_1266.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1142_1266.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1142_1266.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1142_1266.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1142_1266.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1142_1266.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1142_1266.G(quantity = "ThermalConductance", unit = "W/K") = 0.00065000973006033 "Constant thermal conductance of material"; Real TC_1142_1561.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1142_1561.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1142_1561.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1142_1561.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1142_1561.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1142_1561.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1142_1561.G(quantity = "ThermalConductance", unit = "W/K") = 5.19006389539652e-05 "Constant thermal conductance of material"; Real TC_1143_1144.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1143_1144.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1143_1144.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1143_1144.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1143_1144.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1143_1144.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1143_1144.G(quantity = "ThermalConductance", unit = "W/K") = 3.71422618082957e-05 "Constant thermal conductance of material"; Real TC_1143_1267.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1143_1267.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1143_1267.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1143_1267.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1143_1267.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1143_1267.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1143_1267.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649994372221287 "Constant thermal conductance of material"; Real TC_1143_1562.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1143_1562.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1143_1562.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1143_1562.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1143_1562.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1143_1562.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1143_1562.G(quantity = "ThermalConductance", unit = "W/K") = 5.18997562064717e-05 "Constant thermal conductance of material"; Real TC_1144_1268.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1144_1268.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1144_1268.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1144_1268.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1144_1268.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1144_1268.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1144_1268.G(quantity = "ThermalConductance", unit = "W/K") = 0.00025996819430389 "Constant thermal conductance of material"; Real TC_1145_1146.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1145_1146.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1145_1146.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1145_1146.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1145_1146.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1145_1146.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1145_1146.G(quantity = "ThermalConductance", unit = "W/K") = 3.71437296042442e-05 "Constant thermal conductance of material"; Real TC_1145_1156.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1145_1156.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1145_1156.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1145_1156.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1145_1156.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1145_1156.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1145_1156.G(quantity = "ThermalConductance", unit = "W/K") = 6.93334432873097e-06 "Constant thermal conductance of material"; Real TC_1145_1269.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1145_1269.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1145_1269.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1145_1269.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1145_1269.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1145_1269.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1145_1269.G(quantity = "ThermalConductance", unit = "W/K") = 0.00026000211405317 "Constant thermal conductance of material"; Real TC_1146_1147.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1146_1147.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1146_1147.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1146_1147.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1146_1147.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1146_1147.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1146_1147.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000389878748e-05 "Constant thermal conductance of material"; Real TC_1146_1157.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1146_1157.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1146_1157.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1146_1157.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1146_1157.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1146_1157.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1146_1157.G(quantity = "ThermalConductance", unit = "W/K") = 1.73334101337517e-05 "Constant thermal conductance of material"; Real TC_1146_1270.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1146_1270.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1146_1270.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1146_1270.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1146_1270.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1146_1270.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1146_1270.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650002330676363 "Constant thermal conductance of material"; Real TC_1147_1148.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1147_1148.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1147_1148.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1147_1148.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1147_1148.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1147_1148.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1147_1148.G(quantity = "ThermalConductance", unit = "W/K") = 2.6000371441458e-05 "Constant thermal conductance of material"; Real TC_1147_1158.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1147_1158.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1147_1158.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1147_1158.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1147_1158.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1147_1158.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1147_1158.G(quantity = "ThermalConductance", unit = "W/K") = 1.7333445055531e-05 "Constant thermal conductance of material"; Real TC_1147_1271.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1147_1271.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1147_1271.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1147_1271.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1147_1271.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1147_1271.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1147_1271.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649994960411231 "Constant thermal conductance of material"; Real TC_1148_1149.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1148_1149.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1148_1149.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1148_1149.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1148_1149.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1148_1149.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1148_1149.G(quantity = "ThermalConductance", unit = "W/K") = 2.59990233012414e-05 "Constant thermal conductance of material"; Real TC_1148_1159.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1148_1159.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1148_1159.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1148_1159.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1148_1159.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1148_1159.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1148_1159.G(quantity = "ThermalConductance", unit = "W/K") = 1.73331039377603e-05 "Constant thermal conductance of material"; Real TC_1148_1272.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1148_1272.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1148_1272.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1148_1272.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1148_1272.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1148_1272.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1148_1272.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650006769258538 "Constant thermal conductance of material"; Real TC_1149_1150.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1149_1150.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1149_1150.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1149_1150.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1149_1150.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1149_1150.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1149_1150.G(quantity = "ThermalConductance", unit = "W/K") = 2.60100150225329e-05 "Constant thermal conductance of material"; Real TC_1149_1160.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1149_1160.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1149_1160.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1149_1160.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1149_1160.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1149_1160.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1149_1160.G(quantity = "ThermalConductance", unit = "W/K") = 1.73335481590319e-05 "Constant thermal conductance of material"; Real TC_1149_1273.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1149_1273.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1149_1273.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1149_1273.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1149_1273.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1149_1273.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1149_1273.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650005080899203 "Constant thermal conductance of material"; Real TC_1150_1151.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1150_1151.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1150_1151.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1150_1151.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1150_1151.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1150_1151.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1150_1151.G(quantity = "ThermalConductance", unit = "W/K") = 2.60008578781803e-05 "Constant thermal conductance of material"; Real TC_1150_1161.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1150_1161.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1150_1161.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1150_1161.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1150_1161.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1150_1161.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1150_1161.G(quantity = "ThermalConductance", unit = "W/K") = 1.73332360768204e-05 "Constant thermal conductance of material"; Real TC_1150_1274.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1150_1274.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1150_1274.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1150_1274.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1150_1274.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1150_1274.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1150_1274.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650006793785948 "Constant thermal conductance of material"; Real TC_1151_1152.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1151_1152.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1151_1152.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1151_1152.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1151_1152.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1151_1152.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1151_1152.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001187084517e-05 "Constant thermal conductance of material"; Real TC_1151_1162.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1151_1162.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1151_1162.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1151_1162.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1151_1162.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1151_1162.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1151_1162.G(quantity = "ThermalConductance", unit = "W/K") = 1.73335661923704e-05 "Constant thermal conductance of material"; Real TC_1151_1275.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1151_1275.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1151_1275.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1151_1275.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1151_1275.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1151_1275.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1151_1275.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650004562876436 "Constant thermal conductance of material"; Real TC_1152_1153.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1152_1153.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1152_1153.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1152_1153.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1152_1153.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1152_1153.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1152_1153.G(quantity = "ThermalConductance", unit = "W/K") = 2.6e-05 "Constant thermal conductance of material"; Real TC_1152_1163.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1152_1163.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1152_1163.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1152_1163.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1152_1163.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1152_1163.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1152_1163.G(quantity = "ThermalConductance", unit = "W/K") = 1.73334531787198e-05 "Constant thermal conductance of material"; Real TC_1152_1276.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1152_1276.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1152_1276.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1152_1276.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1152_1276.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1152_1276.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1152_1276.G(quantity = "ThermalConductance", unit = "W/K") = 0.00064999654465458 "Constant thermal conductance of material"; Real TC_1153_1154.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1153_1154.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1153_1154.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1153_1154.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1153_1154.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1153_1154.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1153_1154.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004194630873e-05 "Constant thermal conductance of material"; Real TC_1153_1164.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1153_1164.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1153_1164.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1153_1164.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1153_1164.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1153_1164.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1153_1164.G(quantity = "ThermalConductance", unit = "W/K") = 1.73334769867684e-05 "Constant thermal conductance of material"; Real TC_1153_1277.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1153_1277.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1153_1277.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1153_1277.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1153_1277.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1153_1277.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1153_1277.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649995927343815 "Constant thermal conductance of material"; Real TC_1154_1155.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1154_1155.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1154_1155.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1154_1155.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1154_1155.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1154_1155.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1154_1155.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430731430732e-05 "Constant thermal conductance of material"; Real TC_1154_1165.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1154_1165.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1154_1165.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1154_1165.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1154_1165.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1154_1165.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1154_1165.G(quantity = "ThermalConductance", unit = "W/K") = 1.73333883707547e-05 "Constant thermal conductance of material"; Real TC_1154_1278.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1154_1278.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1154_1278.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1154_1278.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1154_1278.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1154_1278.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1154_1278.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650006843094076 "Constant thermal conductance of material"; Real TC_1155_1166.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1155_1166.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1155_1166.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1155_1166.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1155_1166.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1155_1166.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1155_1166.G(quantity = "ThermalConductance", unit = "W/K") = 6.93336116232418e-06 "Constant thermal conductance of material"; Real TC_1155_1279.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1155_1279.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1155_1279.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1155_1279.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1155_1279.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1155_1279.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1155_1279.G(quantity = "ThermalConductance", unit = "W/K") = 0.00025998787143723 "Constant thermal conductance of material"; Real TC_1156_1157.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1156_1157.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1156_1157.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1156_1157.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1156_1157.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1156_1157.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1156_1157.G(quantity = "ThermalConductance", unit = "W/K") = 7.42886170857912e-05 "Constant thermal conductance of material"; Real TC_1156_1167.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1156_1167.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1156_1167.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1156_1167.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1156_1167.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1156_1167.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1156_1167.G(quantity = "ThermalConductance", unit = "W/K") = 6.11778021263531e-06 "Constant thermal conductance of material"; Real TC_1156_1280.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1156_1280.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1156_1280.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1156_1280.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1156_1280.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1156_1280.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1156_1280.G(quantity = "ThermalConductance", unit = "W/K") = 0.00051998677235422 "Constant thermal conductance of material"; Real TC_1157_1158.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1157_1158.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1157_1158.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1157_1158.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1157_1158.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1157_1158.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1157_1158.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000273541681e-05 "Constant thermal conductance of material"; Real TC_1157_1168.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1157_1168.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1157_1168.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1157_1168.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1157_1168.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1157_1168.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1157_1168.G(quantity = "ThermalConductance", unit = "W/K") = 1.52942464624084e-05 "Constant thermal conductance of material"; Real TC_1157_1281.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1157_1281.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1157_1281.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1157_1281.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1157_1281.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1157_1281.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1157_1281.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129999774244707 "Constant thermal conductance of material"; Real TC_1157_1608.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1157_1608.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1157_1608.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1157_1608.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1157_1608.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1157_1608.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1157_1608.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259842769831553 "Constant thermal conductance of material"; Real TC_1158_1159.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1158_1159.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1158_1159.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1158_1159.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1158_1159.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1158_1159.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1158_1159.G(quantity = "ThermalConductance", unit = "W/K") = 5.19969856819889e-05 "Constant thermal conductance of material"; Real TC_1158_1282.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1158_1282.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1158_1282.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1158_1282.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1158_1282.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1158_1282.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1158_1282.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130000596052201 "Constant thermal conductance of material"; Real TC_1158_1497.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1158_1497.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1158_1497.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1158_1497.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1158_1497.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1158_1497.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1158_1497.G(quantity = "ThermalConductance", unit = "W/K") = 2.59060581418021e-05 "Constant thermal conductance of material"; Real TC_1158_1609.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1158_1609.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1158_1609.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1158_1609.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1158_1609.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1158_1609.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1158_1609.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259830976466532 "Constant thermal conductance of material"; Real TC_1159_1160.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1159_1160.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1159_1160.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1159_1160.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1159_1160.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1159_1160.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1159_1160.G(quantity = "ThermalConductance", unit = "W/K") = 5.20040603248282e-05 "Constant thermal conductance of material"; Real TC_1159_1283.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1159_1283.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1159_1283.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1159_1283.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1159_1283.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1159_1283.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1159_1283.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130000600272123 "Constant thermal conductance of material"; Real TC_1159_1498.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1159_1498.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1159_1498.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1159_1498.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1159_1498.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1159_1498.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1159_1498.G(quantity = "ThermalConductance", unit = "W/K") = 2.59050794319826e-05 "Constant thermal conductance of material"; Real TC_1159_1610.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1159_1610.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1159_1610.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1159_1610.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1159_1610.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1159_1610.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1159_1610.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259832058508649 "Constant thermal conductance of material"; Real TC_1160_1161.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1160_1161.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1160_1161.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1160_1161.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1160_1161.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1160_1161.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1160_1161.G(quantity = "ThermalConductance", unit = "W/K") = 5.20039542437497e-05 "Constant thermal conductance of material"; Real TC_1160_1284.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1160_1284.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1160_1284.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1160_1284.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1160_1284.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1160_1284.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1160_1284.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129999915879438 "Constant thermal conductance of material"; Real TC_1160_1499.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1160_1499.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1160_1499.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1160_1499.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1160_1499.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1160_1499.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1160_1499.G(quantity = "ThermalConductance", unit = "W/K") = 2.59055653516809e-05 "Constant thermal conductance of material"; Real TC_1160_1611.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1160_1611.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1160_1611.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1160_1611.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1160_1611.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1160_1611.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1160_1611.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259832036717555 "Constant thermal conductance of material"; Real TC_1161_1162.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1161_1162.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1161_1162.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1161_1162.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1161_1162.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1161_1162.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1161_1162.G(quantity = "ThermalConductance", unit = "W/K") = 5.19986985218932e-05 "Constant thermal conductance of material"; Real TC_1161_1285.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1161_1285.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1161_1285.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1161_1285.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1161_1285.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1161_1285.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1161_1285.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130000558414374 "Constant thermal conductance of material"; Real TC_1161_1500.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1161_1500.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1161_1500.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1161_1500.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1161_1500.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1161_1500.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1161_1500.G(quantity = "ThermalConductance", unit = "W/K") = 2.59068199924282e-05 "Constant thermal conductance of material"; Real TC_1161_1612.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1161_1612.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1161_1612.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1161_1612.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1161_1612.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1161_1612.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1161_1612.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259832982515868 "Constant thermal conductance of material"; Real TC_1162_1163.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1162_1163.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1162_1163.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1162_1163.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1162_1163.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1162_1163.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1162_1163.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000157647894e-05 "Constant thermal conductance of material"; Real TC_1162_1169.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1162_1169.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1162_1169.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1162_1169.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1162_1169.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1162_1169.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1162_1169.G(quantity = "ThermalConductance", unit = "W/K") = 1.52940282935526e-05 "Constant thermal conductance of material"; Real TC_1162_1286.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1162_1286.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1162_1286.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1162_1286.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1162_1286.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1162_1286.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1162_1286.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129999642137157 "Constant thermal conductance of material"; Real TC_1162_1613.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1162_1613.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1162_1613.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1162_1613.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1162_1613.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1162_1613.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1162_1613.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259831915192683 "Constant thermal conductance of material"; Real TC_1163_1164.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1163_1164.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1163_1164.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1163_1164.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1163_1164.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1163_1164.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1163_1164.G(quantity = "ThermalConductance", unit = "W/K") = 5.1999134841182e-05 "Constant thermal conductance of material"; Real TC_1163_1170.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1163_1170.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1163_1170.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1163_1170.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1163_1170.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1163_1170.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1163_1170.G(quantity = "ThermalConductance", unit = "W/K") = 1.52941723208477e-05 "Constant thermal conductance of material"; Real TC_1163_1287.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1163_1287.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1163_1287.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1163_1287.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1163_1287.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1163_1287.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1163_1287.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012999965808459 "Constant thermal conductance of material"; Real TC_1163_1614.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1163_1614.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1163_1614.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1163_1614.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1163_1614.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1163_1614.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1163_1614.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259831575772873 "Constant thermal conductance of material"; Real TC_1164_1165.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1164_1165.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1164_1165.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1164_1165.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1164_1165.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1164_1165.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1164_1165.G(quantity = "ThermalConductance", unit = "W/K") = 5.20002746372496e-05 "Constant thermal conductance of material"; Real TC_1164_1171.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1164_1171.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1164_1171.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1164_1171.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1164_1171.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1164_1171.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1164_1171.G(quantity = "ThermalConductance", unit = "W/K") = 1.52938980667228e-05 "Constant thermal conductance of material"; Real TC_1164_1288.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1164_1288.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1164_1288.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1164_1288.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1164_1288.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1164_1288.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1164_1288.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129999125468379 "Constant thermal conductance of material"; Real TC_1164_1615.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1164_1615.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1164_1615.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1164_1615.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1164_1615.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1164_1615.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1164_1615.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259831984665063 "Constant thermal conductance of material"; Real TC_1165_1166.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1165_1166.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1165_1166.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1165_1166.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1165_1166.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1165_1166.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1165_1166.G(quantity = "ThermalConductance", unit = "W/K") = 7.42877280861125e-05 "Constant thermal conductance of material"; Real TC_1165_1172.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1165_1172.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1165_1172.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1165_1172.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1165_1172.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1165_1172.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1165_1172.G(quantity = "ThermalConductance", unit = "W/K") = 1.52940679300952e-05 "Constant thermal conductance of material"; Real TC_1165_1289.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1165_1289.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1165_1289.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1165_1289.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1165_1289.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1165_1289.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1165_1289.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130000214355052 "Constant thermal conductance of material"; Real TC_1165_1616.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1165_1616.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1165_1616.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1165_1616.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1165_1616.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1165_1616.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1165_1616.G(quantity = "ThermalConductance", unit = "W/K") = 0.00259830241498223 "Constant thermal conductance of material"; Real TC_1166_1173.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1166_1173.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1166_1173.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1166_1173.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1166_1173.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1166_1173.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1166_1173.G(quantity = "ThermalConductance", unit = "W/K") = 6.11758279850002e-06 "Constant thermal conductance of material"; Real TC_1166_1290.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1166_1290.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1166_1290.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1166_1290.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1166_1290.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1166_1290.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1166_1290.G(quantity = "ThermalConductance", unit = "W/K") = 0.000519999332335545 "Constant thermal conductance of material"; Real TC_1167_1168.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1167_1168.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1167_1168.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1167_1168.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1167_1168.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1167_1168.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1167_1168.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000237968227e-05 "Constant thermal conductance of material"; Real TC_1167_1174.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1167_1174.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1167_1174.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1167_1174.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1167_1174.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1167_1174.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1167_1174.G(quantity = "ThermalConductance", unit = "W/K") = 7.42854241762704e-06 "Constant thermal conductance of material"; Real TC_1167_1291.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1167_1291.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1167_1291.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1167_1291.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1167_1291.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1167_1291.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1167_1291.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363999929007945 "Constant thermal conductance of material"; Real TC_1168_1175.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1168_1175.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1168_1175.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1168_1175.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1168_1175.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1168_1175.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1168_1175.G(quantity = "ThermalConductance", unit = "W/K") = 1.85714285714286e-05 "Constant thermal conductance of material"; Real TC_1168_1292.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1168_1292.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1168_1292.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1168_1292.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1168_1292.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1168_1292.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1168_1292.G(quantity = "ThermalConductance", unit = "W/K") = 0.000910003658881284 "Constant thermal conductance of material"; Real TC_1168_1497.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1168_1497.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1168_1497.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1168_1497.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1168_1497.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1168_1497.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1168_1497.G(quantity = "ThermalConductance", unit = "W/K") = 7.24232846830478e-05 "Constant thermal conductance of material"; Real TC_1168_1617.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1168_1617.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1168_1617.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1168_1617.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1168_1617.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1168_1617.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1168_1617.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181882199084553 "Constant thermal conductance of material"; Real TC_1169_1170.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1169_1170.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1169_1170.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1169_1170.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1169_1170.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1169_1170.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1169_1170.G(quantity = "ThermalConductance", unit = "W/K") = 3.63999176064681e-05 "Constant thermal conductance of material"; Real TC_1169_1176.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1169_1176.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1169_1176.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1169_1176.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1169_1176.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1169_1176.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1169_1176.G(quantity = "ThermalConductance", unit = "W/K") = 1.85718076285238e-05 "Constant thermal conductance of material"; Real TC_1169_1297.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1169_1297.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1169_1297.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1169_1297.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1169_1297.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1169_1297.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1169_1297.G(quantity = "ThermalConductance", unit = "W/K") = 0.000909993231105673 "Constant thermal conductance of material"; Real TC_1169_1500.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1169_1500.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1169_1500.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1169_1500.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1169_1500.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1169_1500.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1169_1500.G(quantity = "ThermalConductance", unit = "W/K") = 7.24241433623584e-05 "Constant thermal conductance of material"; Real TC_1169_1622.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1169_1622.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1169_1622.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1169_1622.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1169_1622.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1169_1622.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1169_1622.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181881331013366 "Constant thermal conductance of material"; Real TC_1170_1171.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1170_1171.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1170_1171.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1170_1171.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1170_1171.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1170_1171.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1170_1171.G(quantity = "ThermalConductance", unit = "W/K") = 3.63998345227012e-05 "Constant thermal conductance of material"; Real TC_1170_1177.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1170_1177.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1170_1177.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1170_1177.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1170_1177.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1170_1177.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1170_1177.G(quantity = "ThermalConductance", unit = "W/K") = 1.85711763251758e-05 "Constant thermal conductance of material"; Real TC_1170_1298.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1170_1298.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1170_1298.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1170_1298.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1170_1298.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1170_1298.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1170_1298.G(quantity = "ThermalConductance", unit = "W/K") = 0.000910015822396234 "Constant thermal conductance of material"; Real TC_1170_1623.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1170_1623.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1170_1623.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1170_1623.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1170_1623.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1170_1623.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1170_1623.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181879287644654 "Constant thermal conductance of material"; Real TC_1171_1172.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1171_1172.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1171_1172.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1171_1172.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1171_1172.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1171_1172.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1171_1172.G(quantity = "ThermalConductance", unit = "W/K") = 3.6398907389043e-05 "Constant thermal conductance of material"; Real TC_1171_1178.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1171_1178.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1171_1178.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1171_1178.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1171_1178.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1171_1178.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1171_1178.G(quantity = "ThermalConductance", unit = "W/K") = 1.85715902659874e-05 "Constant thermal conductance of material"; Real TC_1171_1299.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1171_1299.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1171_1299.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1171_1299.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1171_1299.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1171_1299.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1171_1299.G(quantity = "ThermalConductance", unit = "W/K") = 0.000909979123491989 "Constant thermal conductance of material"; Real TC_1171_1624.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1171_1624.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1171_1624.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1171_1624.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1171_1624.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1171_1624.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1171_1624.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181881684893642 "Constant thermal conductance of material"; Real TC_1172_1173.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1172_1173.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1172_1173.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1172_1173.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1172_1173.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1172_1173.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1172_1173.G(quantity = "ThermalConductance", unit = "W/K") = 5.20003162201549e-05 "Constant thermal conductance of material"; Real TC_1172_1179.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1172_1179.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1172_1179.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1172_1179.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1172_1179.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1172_1179.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1172_1179.G(quantity = "ThermalConductance", unit = "W/K") = 1.85717485441244e-05 "Constant thermal conductance of material"; Real TC_1172_1300.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1172_1300.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1172_1300.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1172_1300.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1172_1300.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1172_1300.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1172_1300.G(quantity = "ThermalConductance", unit = "W/K") = 0.00091001623730703 "Constant thermal conductance of material"; Real TC_1172_1625.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1172_1625.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1172_1625.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1172_1625.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1172_1625.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1172_1625.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1172_1625.G(quantity = "ThermalConductance", unit = "W/K") = 0.0018188121667311 "Constant thermal conductance of material"; Real TC_1173_1180.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1173_1180.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1173_1180.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1173_1180.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1173_1180.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1173_1180.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1173_1180.G(quantity = "ThermalConductance", unit = "W/K") = 7.428672245186e-06 "Constant thermal conductance of material"; Real TC_1173_1301.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1173_1301.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1173_1301.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1173_1301.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1173_1301.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1173_1301.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1173_1301.G(quantity = "ThermalConductance", unit = "W/K") = 0.00036399502654105 "Constant thermal conductance of material"; Real TC_1174_1175.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1174_1175.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1174_1175.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1174_1175.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1174_1175.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1174_1175.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1174_1175.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000769477226e-05 "Constant thermal conductance of material"; Real TC_1174_1181.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1174_1181.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1174_1181.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1174_1181.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1174_1181.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1174_1181.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1174_1181.G(quantity = "ThermalConductance", unit = "W/K") = 7.42911067492103e-06 "Constant thermal conductance of material"; Real TC_1174_1302.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1174_1302.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1174_1302.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1174_1302.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1174_1302.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1174_1302.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1174_1302.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363997356758756 "Constant thermal conductance of material"; Real TC_1175_1182.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1175_1182.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1175_1182.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1175_1182.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1175_1182.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1175_1182.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1175_1182.G(quantity = "ThermalConductance", unit = "W/K") = 1.85132075471261e-05 "Constant thermal conductance of material"; Real TC_1175_1303.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1175_1303.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1175_1303.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1175_1303.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1175_1303.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1175_1303.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1175_1303.G(quantity = "ThermalConductance", unit = "W/K") = 0.000910000919657321 "Constant thermal conductance of material"; Real TC_1175_1501.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1175_1501.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1175_1501.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1175_1501.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1175_1501.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1175_1501.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1175_1501.G(quantity = "ThermalConductance", unit = "W/K") = 7.24232527040748e-05 "Constant thermal conductance of material"; Real TC_1175_1626.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1175_1626.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1175_1626.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1175_1626.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1175_1626.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1175_1626.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1175_1626.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181880561122245 "Constant thermal conductance of material"; Real TC_1176_1177.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1176_1177.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1176_1177.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1176_1177.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1176_1177.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1176_1177.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1176_1177.G(quantity = "ThermalConductance", unit = "W/K") = 3.63994000639273e-05 "Constant thermal conductance of material"; Real TC_1176_1183.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1176_1183.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1176_1183.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1176_1183.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1176_1183.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1176_1183.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1176_1183.G(quantity = "ThermalConductance", unit = "W/K") = 1.85698468786829e-05 "Constant thermal conductance of material"; Real TC_1176_1308.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1176_1308.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1176_1308.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1176_1308.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1176_1308.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1176_1308.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1176_1308.G(quantity = "ThermalConductance", unit = "W/K") = 0.000909992435270709 "Constant thermal conductance of material"; Real TC_1176_1504.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1176_1504.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1176_1504.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1176_1504.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1176_1504.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1176_1504.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1176_1504.G(quantity = "ThermalConductance", unit = "W/K") = 7.24219992002418e-05 "Constant thermal conductance of material"; Real TC_1176_1631.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1176_1631.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1176_1631.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1176_1631.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1176_1631.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1176_1631.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1176_1631.G(quantity = "ThermalConductance", unit = "W/K") = 0.0018187805170097 "Constant thermal conductance of material"; Real TC_1177_1178.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1177_1178.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1177_1178.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1177_1178.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1177_1178.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1177_1178.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1177_1178.G(quantity = "ThermalConductance", unit = "W/K") = 3.64009089112825e-05 "Constant thermal conductance of material"; Real TC_1177_1184.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1177_1184.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1177_1184.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1177_1184.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1177_1184.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1177_1184.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1177_1184.G(quantity = "ThermalConductance", unit = "W/K") = 1.85717488789227e-05 "Constant thermal conductance of material"; Real TC_1177_1309.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1177_1309.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1177_1309.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1177_1309.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1177_1309.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1177_1309.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1177_1309.G(quantity = "ThermalConductance", unit = "W/K") = 0.000910014568774605 "Constant thermal conductance of material"; Real TC_1177_1632.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1177_1632.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1177_1632.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1177_1632.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1177_1632.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1177_1632.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1177_1632.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181882553519131 "Constant thermal conductance of material"; Real TC_1178_1179.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1178_1179.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1178_1179.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1178_1179.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1178_1179.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1178_1179.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1178_1179.G(quantity = "ThermalConductance", unit = "W/K") = 3.63989229639474e-05 "Constant thermal conductance of material"; Real TC_1178_1185.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1178_1185.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1178_1185.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1178_1185.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1178_1185.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1178_1185.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1178_1185.G(quantity = "ThermalConductance", unit = "W/K") = 1.85721868365177e-05 "Constant thermal conductance of material"; Real TC_1178_1310.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1178_1310.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1178_1310.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1178_1310.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1178_1310.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1178_1310.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1178_1310.G(quantity = "ThermalConductance", unit = "W/K") = 0.000909995177236556 "Constant thermal conductance of material"; Real TC_1178_1633.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1178_1633.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1178_1633.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1178_1633.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1178_1633.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1178_1633.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1178_1633.G(quantity = "ThermalConductance", unit = "W/K") = 0.0018188640166893 "Constant thermal conductance of material"; Real TC_1179_1180.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1179_1180.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1179_1180.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1179_1180.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1179_1180.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1179_1180.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1179_1180.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001345450543e-05 "Constant thermal conductance of material"; Real TC_1179_1186.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1179_1186.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1179_1186.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1179_1186.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1179_1186.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1179_1186.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1179_1186.G(quantity = "ThermalConductance", unit = "W/K") = 1.85700445650072e-05 "Constant thermal conductance of material"; Real TC_1179_1311.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1179_1311.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1179_1311.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1179_1311.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1179_1311.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1179_1311.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1179_1311.G(quantity = "ThermalConductance", unit = "W/K") = 0.000909986977862366 "Constant thermal conductance of material"; Real TC_1179_1634.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1179_1634.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1179_1634.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1179_1634.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1179_1634.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1179_1634.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1179_1634.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181879073921322 "Constant thermal conductance of material"; Real TC_1180_1187.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1180_1187.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1180_1187.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1180_1187.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1180_1187.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1180_1187.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1180_1187.G(quantity = "ThermalConductance", unit = "W/K") = 7.4285279033161e-06 "Constant thermal conductance of material"; Real TC_1180_1312.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1180_1312.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1180_1312.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1180_1312.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1180_1312.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1180_1312.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1180_1312.G(quantity = "ThermalConductance", unit = "W/K") = 0.000364010657869684 "Constant thermal conductance of material"; Real TC_1181_1182.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1181_1182.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1181_1182.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1181_1182.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1181_1182.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1181_1182.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1181_1182.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000159915991e-05 "Constant thermal conductance of material"; Real TC_1181_1188.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1181_1188.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1181_1188.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1181_1188.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1181_1188.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1181_1188.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1181_1188.G(quantity = "ThermalConductance", unit = "W/K") = 4.95242897966042e-06 "Constant thermal conductance of material"; Real TC_1181_1313.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1181_1313.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1181_1313.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1181_1313.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1181_1313.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1181_1313.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1181_1313.G(quantity = "ThermalConductance", unit = "W/K") = 0.000364000612651248 "Constant thermal conductance of material"; Real TC_1182_1189.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1182_1189.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1182_1189.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1182_1189.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1182_1189.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1182_1189.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1182_1189.G(quantity = "ThermalConductance", unit = "W/K") = 1.23813422483001e-05 "Constant thermal conductance of material"; Real TC_1182_1314.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1182_1314.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1182_1314.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1182_1314.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1182_1314.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1182_1314.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1182_1314.G(quantity = "ThermalConductance", unit = "W/K") = 0.000910001589226119 "Constant thermal conductance of material"; Real TC_1182_1505.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1182_1505.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1182_1505.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1182_1505.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1182_1505.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1182_1505.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1182_1505.G(quantity = "ThermalConductance", unit = "W/K") = 7.24246024441803e-05 "Constant thermal conductance of material"; Real TC_1182_1563.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1182_1563.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1182_1563.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1182_1563.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1182_1563.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1182_1563.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1182_1563.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181879646223821 "Constant thermal conductance of material"; Real TC_1183_1184.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1183_1184.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1183_1184.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1183_1184.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1183_1184.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1183_1184.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1183_1184.G(quantity = "ThermalConductance", unit = "W/K") = 3.64012668074237e-05 "Constant thermal conductance of material"; Real TC_1183_1194.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1183_1194.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1183_1194.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1183_1194.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1183_1194.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1183_1194.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1183_1194.G(quantity = "ThermalConductance", unit = "W/K") = 1.23810368868044e-05 "Constant thermal conductance of material"; Real TC_1183_1319.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1183_1319.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1183_1319.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1183_1319.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1183_1319.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1183_1319.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1183_1319.G(quantity = "ThermalConductance", unit = "W/K") = 0.000909992222003385 "Constant thermal conductance of material"; Real TC_1183_1508.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1183_1508.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1183_1508.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1183_1508.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1183_1508.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1183_1508.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1183_1508.G(quantity = "ThermalConductance", unit = "W/K") = 7.24247878632037e-05 "Constant thermal conductance of material"; Real TC_1183_1568.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1183_1568.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1183_1568.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1183_1568.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1183_1568.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1183_1568.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1183_1568.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181882949521195 "Constant thermal conductance of material"; Real TC_1184_1185.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1184_1185.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1184_1185.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1184_1185.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1184_1185.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1184_1185.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1184_1185.G(quantity = "ThermalConductance", unit = "W/K") = 3.63997791275537e-05 "Constant thermal conductance of material"; Real TC_1184_1195.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1184_1195.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1184_1195.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1184_1195.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1184_1195.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1184_1195.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1184_1195.G(quantity = "ThermalConductance", unit = "W/K") = 1.23819224385086e-05 "Constant thermal conductance of material"; Real TC_1184_1320.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1184_1320.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1184_1320.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1184_1320.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1184_1320.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1184_1320.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1184_1320.G(quantity = "ThermalConductance", unit = "W/K") = 0.000910014644994485 "Constant thermal conductance of material"; Real TC_1184_1569.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1184_1569.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1184_1569.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1184_1569.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1184_1569.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1184_1569.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1184_1569.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181877891576266 "Constant thermal conductance of material"; Real TC_1185_1186.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1185_1186.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1185_1186.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1185_1186.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1185_1186.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1185_1186.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1185_1186.G(quantity = "ThermalConductance", unit = "W/K") = 3.63995701196741e-05 "Constant thermal conductance of material"; Real TC_1185_1196.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1185_1196.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1185_1196.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1185_1196.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1185_1196.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1185_1196.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1185_1196.G(quantity = "ThermalConductance", unit = "W/K") = 1.23811033608118e-05 "Constant thermal conductance of material"; Real TC_1185_1321.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1185_1321.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1185_1321.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1185_1321.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1185_1321.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1185_1321.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1185_1321.G(quantity = "ThermalConductance", unit = "W/K") = 0.000909994438988605 "Constant thermal conductance of material"; Real TC_1185_1570.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1185_1570.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1185_1570.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1185_1570.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1185_1570.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1185_1570.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1185_1570.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181882452750154 "Constant thermal conductance of material"; Real TC_1186_1187.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1186_1187.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1186_1187.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1186_1187.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1186_1187.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1186_1187.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1186_1187.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000736251651e-05 "Constant thermal conductance of material"; Real TC_1186_1197.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1186_1197.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1186_1197.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1186_1197.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1186_1197.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1186_1197.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1186_1197.G(quantity = "ThermalConductance", unit = "W/K") = 1.23816828589281e-05 "Constant thermal conductance of material"; Real TC_1186_1322.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1186_1322.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1186_1322.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1186_1322.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1186_1322.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1186_1322.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1186_1322.G(quantity = "ThermalConductance", unit = "W/K") = 0.000909999707207303 "Constant thermal conductance of material"; Real TC_1186_1571.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1186_1571.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1186_1571.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1186_1571.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1186_1571.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1186_1571.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1186_1571.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181880602953161 "Constant thermal conductance of material"; Real TC_1187_1198.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1187_1198.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1187_1198.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1187_1198.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1187_1198.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1187_1198.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1187_1198.G(quantity = "ThermalConductance", unit = "W/K") = 4.95210913312683e-06 "Constant thermal conductance of material"; Real TC_1187_1323.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1187_1323.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1187_1323.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1187_1323.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1187_1323.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1187_1323.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1187_1323.G(quantity = "ThermalConductance", unit = "W/K") = 0.00036399905756695 "Constant thermal conductance of material"; Real TC_1188_1189.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1188_1189.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1188_1189.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1188_1189.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1188_1189.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1188_1189.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1188_1189.G(quantity = "ThermalConductance", unit = "W/K") = 0.000104002478356931 "Constant thermal conductance of material"; Real TC_1188_1199.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1188_1199.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1188_1199.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1188_1199.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1188_1199.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1188_1199.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1188_1199.G(quantity = "ThermalConductance", unit = "W/K") = 5.47385329287883e-06 "Constant thermal conductance of material"; Real TC_1188_1324.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1188_1324.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1188_1324.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1188_1324.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1188_1324.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1188_1324.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1188_1324.G(quantity = "ThermalConductance", unit = "W/K") = 0.000728029677963859 "Constant thermal conductance of material"; Real TC_1189_1190.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1189_1190.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1189_1190.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1189_1190.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1189_1190.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1189_1190.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1189_1190.G(quantity = "ThermalConductance", unit = "W/K") = 7.28014654257707e-05 "Constant thermal conductance of material"; Real TC_1189_1200.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1189_1200.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1189_1200.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1189_1200.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1189_1200.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1189_1200.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1189_1200.G(quantity = "ThermalConductance", unit = "W/K") = 1.36841443875469e-05 "Constant thermal conductance of material"; Real TC_1189_1325.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1189_1325.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1189_1325.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1189_1325.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1189_1325.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1189_1325.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1189_1325.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181999709221542 "Constant thermal conductance of material"; Real TC_1189_1572.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1189_1572.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1189_1572.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1189_1572.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1189_1572.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1189_1572.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1189_1572.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363762548823397 "Constant thermal conductance of material"; Real TC_1190_1191.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1190_1191.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1190_1191.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1190_1191.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1190_1191.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1190_1191.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1190_1191.G(quantity = "ThermalConductance", unit = "W/K") = 7.27976024533017e-05 "Constant thermal conductance of material"; Real TC_1190_1201.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1190_1201.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1190_1201.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1190_1201.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1190_1201.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1190_1201.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1190_1201.G(quantity = "ThermalConductance", unit = "W/K") = 1.36840805998704e-05 "Constant thermal conductance of material"; Real TC_1190_1326.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1190_1326.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1190_1326.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1190_1326.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1190_1326.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1190_1326.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1190_1326.G(quantity = "ThermalConductance", unit = "W/K") = 0.00182001488547299 "Constant thermal conductance of material"; Real TC_1190_1505.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1190_1505.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1190_1505.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1190_1505.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1190_1505.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1190_1505.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1190_1505.G(quantity = "ThermalConductance", unit = "W/K") = 1.85233501013589e-05 "Constant thermal conductance of material"; Real TC_1190_1573.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1190_1573.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1190_1573.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1190_1573.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1190_1573.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1190_1573.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1190_1573.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363761142814516 "Constant thermal conductance of material"; Real TC_1191_1192.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1191_1192.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1191_1192.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1191_1192.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1191_1192.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1191_1192.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1191_1192.G(quantity = "ThermalConductance", unit = "W/K") = 7.27936031984037e-05 "Constant thermal conductance of material"; Real TC_1191_1202.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1191_1202.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1191_1202.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1191_1202.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1191_1202.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1191_1202.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1191_1202.G(quantity = "ThermalConductance", unit = "W/K") = 1.36842951294003e-05 "Constant thermal conductance of material"; Real TC_1191_1327.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1191_1327.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1191_1327.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1191_1327.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1191_1327.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1191_1327.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1191_1327.G(quantity = "ThermalConductance", unit = "W/K") = 0.00182001674369531 "Constant thermal conductance of material"; Real TC_1191_1506.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1191_1506.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1191_1506.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1191_1506.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1191_1506.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1191_1506.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1191_1506.G(quantity = "ThermalConductance", unit = "W/K") = 1.85232809058753e-05 "Constant thermal conductance of material"; Real TC_1191_1574.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1191_1574.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1191_1574.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1191_1574.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1191_1574.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1191_1574.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1191_1574.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363768048942105 "Constant thermal conductance of material"; Real TC_1192_1193.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1192_1193.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1192_1193.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1192_1193.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1192_1193.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1192_1193.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1192_1193.G(quantity = "ThermalConductance", unit = "W/K") = 7.31198501872126e-05 "Constant thermal conductance of material"; Real TC_1192_1203.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1192_1203.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1192_1203.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1192_1203.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1192_1203.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1192_1203.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1192_1203.G(quantity = "ThermalConductance", unit = "W/K") = 1.36844139530388e-05 "Constant thermal conductance of material"; Real TC_1192_1328.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1192_1328.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1192_1328.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1192_1328.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1192_1328.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1192_1328.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1192_1328.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181997925706095 "Constant thermal conductance of material"; Real TC_1192_1507.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1192_1507.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1192_1507.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1192_1507.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1192_1507.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1192_1507.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1192_1507.G(quantity = "ThermalConductance", unit = "W/K") = 1.85233487589398e-05 "Constant thermal conductance of material"; Real TC_1192_1575.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1192_1575.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1192_1575.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1192_1575.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1192_1575.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1192_1575.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1192_1575.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363761766296466 "Constant thermal conductance of material"; Real TC_1193_1194.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1193_1194.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1193_1194.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1193_1194.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1193_1194.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1193_1194.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1193_1194.G(quantity = "ThermalConductance", unit = "W/K") = 7.28126100739654e-05 "Constant thermal conductance of material"; Real TC_1193_1204.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1193_1204.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1193_1204.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1193_1204.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1193_1204.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1193_1204.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1193_1204.G(quantity = "ThermalConductance", unit = "W/K") = 1.36839738144022e-05 "Constant thermal conductance of material"; Real TC_1193_1329.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1193_1329.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1193_1329.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1193_1329.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1193_1329.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1193_1329.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1193_1329.G(quantity = "ThermalConductance", unit = "W/K") = 0.00182002132506179 "Constant thermal conductance of material"; Real TC_1193_1508.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1193_1508.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1193_1508.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1193_1508.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1193_1508.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1193_1508.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1193_1508.G(quantity = "ThermalConductance", unit = "W/K") = 1.85231599749361e-05 "Constant thermal conductance of material"; Real TC_1193_1576.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1193_1576.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1193_1576.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1193_1576.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1193_1576.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1193_1576.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1193_1576.G(quantity = "ThermalConductance", unit = "W/K") = 0.0036375788598536 "Constant thermal conductance of material"; Real TC_1194_1195.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1194_1195.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1194_1195.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1194_1195.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1194_1195.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1194_1195.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1194_1195.G(quantity = "ThermalConductance", unit = "W/K") = 7.28026517083116e-05 "Constant thermal conductance of material"; Real TC_1194_1330.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1194_1330.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1194_1330.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1194_1330.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1194_1330.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1194_1330.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1194_1330.G(quantity = "ThermalConductance", unit = "W/K") = 0.00182000256772371 "Constant thermal conductance of material"; Real TC_1194_1509.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1194_1509.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1194_1509.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1194_1509.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1194_1509.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1194_1509.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1194_1509.G(quantity = "ThermalConductance", unit = "W/K") = 1.85368745390252e-05 "Constant thermal conductance of material"; Real TC_1194_1577.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1194_1577.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1194_1577.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1194_1577.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1194_1577.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1194_1577.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1194_1577.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363761625904237 "Constant thermal conductance of material"; Real TC_1195_1196.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1195_1196.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1195_1196.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1195_1196.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1195_1196.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1195_1196.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1195_1196.G(quantity = "ThermalConductance", unit = "W/K") = 7.27962085308076e-05 "Constant thermal conductance of material"; Real TC_1195_1331.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1195_1331.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1195_1331.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1195_1331.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1195_1331.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1195_1331.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1195_1331.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181998039631957 "Constant thermal conductance of material"; Real TC_1195_1510.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1195_1510.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1195_1510.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1195_1510.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1195_1510.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1195_1510.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1195_1510.G(quantity = "ThermalConductance", unit = "W/K") = 1.85372454536453e-05 "Constant thermal conductance of material"; Real TC_1195_1578.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1195_1578.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1195_1578.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1195_1578.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1195_1578.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1195_1578.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1195_1578.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363763610914181 "Constant thermal conductance of material"; Real TC_1196_1197.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1196_1197.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1196_1197.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1196_1197.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1196_1197.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1196_1197.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1196_1197.G(quantity = "ThermalConductance", unit = "W/K") = 7.27994011976052e-05 "Constant thermal conductance of material"; Real TC_1196_1332.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1196_1332.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1196_1332.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1196_1332.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1196_1332.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1196_1332.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1196_1332.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181998464386484 "Constant thermal conductance of material"; Real TC_1196_1511.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1196_1511.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1196_1511.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1196_1511.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1196_1511.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1196_1511.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1196_1511.G(quantity = "ThermalConductance", unit = "W/K") = 1.85373122571159e-05 "Constant thermal conductance of material"; Real TC_1196_1579.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1196_1579.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1196_1579.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1196_1579.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1196_1579.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1196_1579.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1196_1579.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363762271759408 "Constant thermal conductance of material"; Real TC_1197_1198.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1197_1198.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1197_1198.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1197_1198.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1197_1198.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1197_1198.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1197_1198.G(quantity = "ThermalConductance", unit = "W/K") = 0.000104002749011978 "Constant thermal conductance of material"; Real TC_1197_1205.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1197_1205.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1197_1205.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1197_1205.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1197_1205.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1197_1205.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1197_1205.G(quantity = "ThermalConductance", unit = "W/K") = 1.36841242968708e-05 "Constant thermal conductance of material"; Real TC_1197_1333.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1197_1333.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1197_1333.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1197_1333.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1197_1333.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1197_1333.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1197_1333.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181999102491561 "Constant thermal conductance of material"; Real TC_1197_1580.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1197_1580.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1197_1580.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1197_1580.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1197_1580.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1197_1580.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1197_1580.G(quantity = "ThermalConductance", unit = "W/K") = 0.00363762880279203 "Constant thermal conductance of material"; Real TC_1198_1206.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1198_1206.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1198_1206.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1198_1206.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1198_1206.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1198_1206.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1198_1206.G(quantity = "ThermalConductance", unit = "W/K") = 5.47376908471402e-06 "Constant thermal conductance of material"; Real TC_1198_1334.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1198_1334.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1198_1334.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1198_1334.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1198_1334.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1198_1334.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1198_1334.G(quantity = "ThermalConductance", unit = "W/K") = 0.000727912621359162 "Constant thermal conductance of material"; Real TC_1199_1200.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1199_1200.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1199_1200.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1199_1200.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1199_1200.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1199_1200.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1199_1200.G(quantity = "ThermalConductance", unit = "W/K") = 3.71427011660422e-05 "Constant thermal conductance of material"; Real TC_1199_1207.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1199_1207.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1199_1207.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1199_1207.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1199_1207.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1199_1207.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1199_1207.G(quantity = "ThermalConductance", unit = "W/K") = 1.04000270288533e-05 "Constant thermal conductance of material"; Real TC_1199_1335.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1199_1335.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1199_1335.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1199_1335.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1199_1335.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1199_1335.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1199_1335.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001744852685 "Constant thermal conductance of material"; Real TC_1200_1201.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1200_1201.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1200_1201.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1200_1201.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1200_1201.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1200_1201.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1200_1201.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998210611076e-05 "Constant thermal conductance of material"; Real TC_1200_1208.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1200_1208.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1200_1208.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1200_1208.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1200_1208.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1200_1208.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1200_1208.G(quantity = "ThermalConductance", unit = "W/K") = 2.60005947071068e-05 "Constant thermal conductance of material"; Real TC_1200_1336.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1200_1336.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1200_1336.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1200_1336.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1200_1336.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1200_1336.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1200_1336.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650003918431024 "Constant thermal conductance of material"; Real TC_1200_1581.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1200_1581.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1200_1581.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1200_1581.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1200_1581.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1200_1581.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1200_1581.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916994013469 "Constant thermal conductance of material"; Real TC_1201_1202.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1201_1202.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1201_1202.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1201_1202.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1201_1202.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1201_1202.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1201_1202.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003066073879e-05 "Constant thermal conductance of material"; Real TC_1201_1209.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1201_1209.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1201_1209.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1201_1209.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1201_1209.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1201_1209.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1201_1209.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003165057762e-05 "Constant thermal conductance of material"; Real TC_1201_1337.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1201_1337.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1201_1337.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1201_1337.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1201_1337.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1201_1337.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1201_1337.G(quantity = "ThermalConductance", unit = "W/K") = 0.00065001676675914 "Constant thermal conductance of material"; Real TC_1201_1582.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1201_1582.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1201_1582.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1201_1582.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1201_1582.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1201_1582.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1201_1582.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916461039926 "Constant thermal conductance of material"; Real TC_1202_1203.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1202_1203.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1202_1203.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1202_1203.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1202_1203.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1202_1203.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1202_1203.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000000000008e-05 "Constant thermal conductance of material"; Real TC_1202_1210.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1202_1210.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1202_1210.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1202_1210.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1202_1210.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1202_1210.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1202_1210.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002543962858e-05 "Constant thermal conductance of material"; Real TC_1202_1338.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1202_1338.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1202_1338.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1202_1338.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1202_1338.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1202_1338.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1202_1338.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649992394784772 "Constant thermal conductance of material"; Real TC_1202_1583.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1202_1583.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1202_1583.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1202_1583.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1202_1583.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1202_1583.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1202_1583.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129912195121951 "Constant thermal conductance of material"; Real TC_1203_1204.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1203_1204.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1203_1204.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1203_1204.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1203_1204.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1203_1204.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1203_1204.G(quantity = "ThermalConductance", unit = "W/K") = 2.60008656135044e-05 "Constant thermal conductance of material"; Real TC_1203_1211.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1203_1211.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1203_1211.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1203_1211.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1203_1211.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1203_1211.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1203_1211.G(quantity = "ThermalConductance", unit = "W/K") = 2.60006945650285e-05 "Constant thermal conductance of material"; Real TC_1203_1339.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1203_1339.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1203_1339.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1203_1339.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1203_1339.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1203_1339.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1203_1339.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649988740352528 "Constant thermal conductance of material"; Real TC_1203_1584.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1203_1584.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1203_1584.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1203_1584.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1203_1584.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1203_1584.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1203_1584.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129913604253329 "Constant thermal conductance of material"; Real TC_1204_1212.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1204_1212.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1204_1212.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1204_1212.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1204_1212.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1204_1212.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1204_1212.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001541069502e-05 "Constant thermal conductance of material"; Real TC_1204_1340.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1204_1340.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1204_1340.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1204_1340.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1204_1340.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1204_1340.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1204_1340.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649979505150739 "Constant thermal conductance of material"; Real TC_1204_1509.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1204_1509.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1204_1509.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1204_1509.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1204_1509.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1204_1509.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1204_1509.G(quantity = "ThermalConductance", unit = "W/K") = 5.17313555996096e-05 "Constant thermal conductance of material"; Real TC_1204_1585.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1204_1585.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1204_1585.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1204_1585.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1204_1585.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1204_1585.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1204_1585.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129918101598791 "Constant thermal conductance of material"; Real TC_1205_1206.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1205_1206.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1205_1206.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1205_1206.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1205_1206.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1205_1206.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1205_1206.G(quantity = "ThermalConductance", unit = "W/K") = 3.71429200412657e-05 "Constant thermal conductance of material"; Real TC_1205_1213.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1205_1213.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1205_1213.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1205_1213.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1205_1213.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1205_1213.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1205_1213.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002095777008e-05 "Constant thermal conductance of material"; Real TC_1205_1341.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1205_1341.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1205_1341.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1205_1341.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1205_1341.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1205_1341.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1205_1341.G(quantity = "ThermalConductance", unit = "W/K") = 0.00065000830626636 "Constant thermal conductance of material"; Real TC_1205_1511.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1205_1511.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1205_1511.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1205_1511.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1205_1511.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1205_1511.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1205_1511.G(quantity = "ThermalConductance", unit = "W/K") = 5.17310266850719e-05 "Constant thermal conductance of material"; Real TC_1205_1589.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1205_1589.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1205_1589.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1205_1589.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1205_1589.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1205_1589.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1205_1589.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012991905172486 "Constant thermal conductance of material"; Real TC_1206_1214.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1206_1214.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1206_1214.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1206_1214.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1206_1214.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1206_1214.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1206_1214.G(quantity = "ThermalConductance", unit = "W/K") = 1.0399942865305e-05 "Constant thermal conductance of material"; Real TC_1206_1342.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1206_1342.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1206_1342.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1206_1342.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1206_1342.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1206_1342.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1206_1342.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259999999999995 "Constant thermal conductance of material"; Real TC_1207_1208.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1207_1208.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1207_1208.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1207_1208.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1207_1208.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1207_1208.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1207_1208.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430191334741e-05 "Constant thermal conductance of material"; Real TC_1207_1215.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1207_1215.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1207_1215.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1207_1215.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1207_1215.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1207_1215.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1207_1215.G(quantity = "ThermalConductance", unit = "W/K") = 1.03998975934458e-05 "Constant thermal conductance of material"; Real TC_1207_1343.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1207_1343.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1207_1343.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1207_1343.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1207_1343.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1207_1343.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1207_1343.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001104924896 "Constant thermal conductance of material"; Real TC_1208_1209.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1208_1209.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1208_1209.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1208_1209.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1208_1209.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1208_1209.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1208_1209.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001986024658e-05 "Constant thermal conductance of material"; Real TC_1208_1216.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1208_1216.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1208_1216.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1208_1216.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1208_1216.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1208_1216.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1208_1216.G(quantity = "ThermalConductance", unit = "W/K") = 2.60005231493587e-05 "Constant thermal conductance of material"; Real TC_1208_1344.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1208_1344.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1208_1344.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1208_1344.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1208_1344.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1208_1344.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1208_1344.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649994158930995 "Constant thermal conductance of material"; Real TC_1208_1590.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1208_1590.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1208_1590.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1208_1590.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1208_1590.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1208_1590.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1208_1590.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916356906624 "Constant thermal conductance of material"; Real TC_1209_1210.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1209_1210.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1209_1210.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1209_1210.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1209_1210.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1209_1210.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1209_1210.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001550627993e-05 "Constant thermal conductance of material"; Real TC_1209_1217.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1209_1217.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1209_1217.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1209_1217.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1209_1217.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1209_1217.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1209_1217.G(quantity = "ThermalConductance", unit = "W/K") = 2.60008807016256e-05 "Constant thermal conductance of material"; Real TC_1209_1345.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1209_1345.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1209_1345.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1209_1345.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1209_1345.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1209_1345.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1209_1345.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650000365435637 "Constant thermal conductance of material"; Real TC_1209_1591.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1209_1591.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1209_1591.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1209_1591.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1209_1591.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1209_1591.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1209_1591.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012991251562221 "Constant thermal conductance of material"; Real TC_1210_1211.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1210_1211.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1210_1211.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1210_1211.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1210_1211.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1210_1211.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1210_1211.G(quantity = "ThermalConductance", unit = "W/K") = 2.60018220467656e-05 "Constant thermal conductance of material"; Real TC_1210_1218.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1210_1218.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1210_1218.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1210_1218.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1210_1218.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1210_1218.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1210_1218.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999277378329e-05 "Constant thermal conductance of material"; Real TC_1210_1346.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1210_1346.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1210_1346.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1210_1346.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1210_1346.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1210_1346.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1210_1346.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650009555106735 "Constant thermal conductance of material"; Real TC_1210_1592.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1210_1592.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1210_1592.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1210_1592.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1210_1592.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1210_1592.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1210_1592.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012991886638096 "Constant thermal conductance of material"; Real TC_1211_1212.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1211_1212.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1211_1212.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1211_1212.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1211_1212.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1211_1212.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1211_1212.G(quantity = "ThermalConductance", unit = "W/K") = 2.59987505856649e-05 "Constant thermal conductance of material"; Real TC_1211_1219.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1211_1219.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1211_1219.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1211_1219.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1211_1219.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1211_1219.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1211_1219.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998303575218e-05 "Constant thermal conductance of material"; Real TC_1211_1347.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1211_1347.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1211_1347.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1211_1347.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1211_1347.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1211_1347.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1211_1347.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650002585531365 "Constant thermal conductance of material"; Real TC_1211_1593.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1211_1593.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1211_1593.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1211_1593.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1211_1593.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1211_1593.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1211_1593.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129914161720595 "Constant thermal conductance of material"; Real TC_1212_1220.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1212_1220.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1212_1220.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1212_1220.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1212_1220.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1212_1220.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1212_1220.G(quantity = "ThermalConductance", unit = "W/K") = 2.59996621336258e-05 "Constant thermal conductance of material"; Real TC_1212_1348.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1212_1348.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1212_1348.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1212_1348.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1212_1348.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1212_1348.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1212_1348.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649977728285079 "Constant thermal conductance of material"; Real TC_1212_1512.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1212_1512.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1212_1512.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1212_1512.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1212_1512.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1212_1512.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1212_1512.G(quantity = "ThermalConductance", unit = "W/K") = 5.17307950899976e-05 "Constant thermal conductance of material"; Real TC_1212_1594.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1212_1594.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1212_1594.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1212_1594.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1212_1594.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1212_1594.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1212_1594.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129911122186228 "Constant thermal conductance of material"; Real TC_1213_1214.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1213_1214.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1213_1214.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1213_1214.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1213_1214.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1213_1214.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1213_1214.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430451126398e-05 "Constant thermal conductance of material"; Real TC_1213_1221.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1213_1221.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1213_1221.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1213_1221.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1213_1221.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1213_1221.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1213_1221.G(quantity = "ThermalConductance", unit = "W/K") = 2.59808027923221e-05 "Constant thermal conductance of material"; Real TC_1213_1349.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1213_1349.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1213_1349.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1213_1349.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1213_1349.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1213_1349.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1213_1349.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650013572684676 "Constant thermal conductance of material"; Real TC_1213_1514.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1213_1514.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1213_1514.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1213_1514.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1213_1514.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1213_1514.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1213_1514.G(quantity = "ThermalConductance", unit = "W/K") = 5.17310266035582e-05 "Constant thermal conductance of material"; Real TC_1213_1598.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1213_1598.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1213_1598.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1213_1598.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1213_1598.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1213_1598.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1213_1598.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129912803881468 "Constant thermal conductance of material"; Real TC_1214_1222.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1214_1222.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1214_1222.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1214_1222.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1214_1222.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1214_1222.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1214_1222.G(quantity = "ThermalConductance", unit = "W/K") = 1.04088339222635e-05 "Constant thermal conductance of material"; Real TC_1214_1350.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1214_1350.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1214_1350.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1214_1350.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1214_1350.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1214_1350.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1214_1350.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259995723754571 "Constant thermal conductance of material"; Real TC_1215_1216.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1215_1216.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1215_1216.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1215_1216.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1215_1216.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1215_1216.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1215_1216.G(quantity = "ThermalConductance", unit = "W/K") = 3.71426431004752e-05 "Constant thermal conductance of material"; Real TC_1215_1223.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1215_1223.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1215_1223.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1215_1223.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1215_1223.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1215_1223.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1215_1223.G(quantity = "ThermalConductance", unit = "W/K") = 1.03999379139072e-05 "Constant thermal conductance of material"; Real TC_1215_1351.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1215_1351.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1215_1351.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1215_1351.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1215_1351.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1215_1351.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1215_1351.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260000838770362 "Constant thermal conductance of material"; Real TC_1216_1217.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1216_1217.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1216_1217.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1216_1217.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1216_1217.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1216_1217.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1216_1217.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998233440963e-05 "Constant thermal conductance of material"; Real TC_1216_1224.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1216_1224.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1216_1224.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1216_1224.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1216_1224.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1216_1224.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1216_1224.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004111918958e-05 "Constant thermal conductance of material"; Real TC_1216_1352.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1216_1352.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1216_1352.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1216_1352.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1216_1352.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1216_1352.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1216_1352.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649995603622615 "Constant thermal conductance of material"; Real TC_1216_1599.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1216_1599.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1216_1599.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1216_1599.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1216_1599.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1216_1599.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1216_1599.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916066590673 "Constant thermal conductance of material"; Real TC_1217_1218.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1217_1218.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1217_1218.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1217_1218.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1217_1218.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1217_1218.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1217_1218.G(quantity = "ThermalConductance", unit = "W/K") = 2.59985454545449e-05 "Constant thermal conductance of material"; Real TC_1217_1353.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1217_1353.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1217_1353.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1217_1353.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1217_1353.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1217_1353.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1217_1353.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649994685515373 "Constant thermal conductance of material"; Real TC_1217_1518.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1217_1518.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1217_1518.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1217_1518.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1217_1518.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1217_1518.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1217_1518.G(quantity = "ThermalConductance", unit = "W/K") = 5.17315143203291e-05 "Constant thermal conductance of material"; Real TC_1217_1600.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1217_1600.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1217_1600.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1217_1600.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1217_1600.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1217_1600.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1217_1600.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129914471198434 "Constant thermal conductance of material"; Real TC_1218_1219.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1218_1219.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1218_1219.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1218_1219.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1218_1219.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1218_1219.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1218_1219.G(quantity = "ThermalConductance", unit = "W/K") = 2.5996328778298e-05 "Constant thermal conductance of material"; Real TC_1218_1354.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1218_1354.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1218_1354.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1218_1354.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1218_1354.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1218_1354.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1218_1354.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649988831807014 "Constant thermal conductance of material"; Real TC_1218_1519.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1218_1519.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1218_1519.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1218_1519.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1218_1519.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1218_1519.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1218_1519.G(quantity = "ThermalConductance", unit = "W/K") = 5.17315886189697e-05 "Constant thermal conductance of material"; Real TC_1218_1601.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1218_1601.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1218_1601.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1218_1601.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1218_1601.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1218_1601.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1218_1601.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129917251072008 "Constant thermal conductance of material"; Real TC_1219_1220.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1219_1220.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1219_1220.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1219_1220.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1219_1220.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1219_1220.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1219_1220.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004684663587e-05 "Constant thermal conductance of material"; Real TC_1219_1355.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1219_1355.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1219_1355.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1219_1355.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1219_1355.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1219_1355.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1219_1355.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650014665252044 "Constant thermal conductance of material"; Real TC_1219_1520.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1219_1520.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1219_1520.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1219_1520.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1219_1520.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1219_1520.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1219_1520.G(quantity = "ThermalConductance", unit = "W/K") = 5.17290881704661e-05 "Constant thermal conductance of material"; Real TC_1219_1602.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1219_1602.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1219_1602.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1219_1602.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1219_1602.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1219_1602.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1219_1602.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916759369366 "Constant thermal conductance of material"; Real TC_1220_1225.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1220_1225.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1220_1225.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1220_1225.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1220_1225.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1220_1225.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1220_1225.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998000899601e-05 "Constant thermal conductance of material"; Real TC_1220_1356.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1220_1356.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1220_1356.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1220_1356.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1220_1356.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1220_1356.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1220_1356.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650002305567316 "Constant thermal conductance of material"; Real TC_1220_1515.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1220_1515.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1220_1515.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1220_1515.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1220_1515.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1220_1515.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1220_1515.G(quantity = "ThermalConductance", unit = "W/K") = 5.17305137877904e-05 "Constant thermal conductance of material"; Real TC_1220_1603.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1220_1603.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1220_1603.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1220_1603.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1220_1603.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1220_1603.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1220_1603.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129912692150963 "Constant thermal conductance of material"; Real TC_1221_1222.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1221_1222.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1221_1222.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1221_1222.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1221_1222.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1221_1222.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1221_1222.G(quantity = "ThermalConductance", unit = "W/K") = 3.7142848500614e-05 "Constant thermal conductance of material"; Real TC_1221_1229.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1221_1229.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1221_1229.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1221_1229.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1221_1229.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1221_1229.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1221_1229.G(quantity = "ThermalConductance", unit = "W/K") = 2.59991349480968e-05 "Constant thermal conductance of material"; Real TC_1221_1357.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1221_1357.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1221_1357.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1221_1357.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1221_1357.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1221_1357.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1221_1357.G(quantity = "ThermalConductance", unit = "W/K") = 0.00064998942246668 "Constant thermal conductance of material"; Real TC_1221_1517.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1221_1517.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1221_1517.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1221_1517.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1221_1517.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1221_1517.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1221_1517.G(quantity = "ThermalConductance", unit = "W/K") = 5.17310696268983e-05 "Constant thermal conductance of material"; Real TC_1221_1607.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1221_1607.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1221_1607.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1221_1607.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1221_1607.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1221_1607.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1221_1607.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129911350392055 "Constant thermal conductance of material"; Real TC_1222_1230.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1222_1230.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1222_1230.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1222_1230.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1222_1230.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1222_1230.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1222_1230.G(quantity = "ThermalConductance", unit = "W/K") = 1.04005722460656e-05 "Constant thermal conductance of material"; Real TC_1222_1358.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1222_1358.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1222_1358.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1222_1358.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1222_1358.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1222_1358.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1222_1358.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259931428571412 "Constant thermal conductance of material"; Real TC_1223_1224.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1223_1224.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1223_1224.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1223_1224.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1223_1224.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1223_1224.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1223_1224.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430609748808e-05 "Constant thermal conductance of material"; Real TC_1223_1231.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1223_1231.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1223_1231.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1223_1231.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1223_1231.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1223_1231.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1223_1231.G(quantity = "ThermalConductance", unit = "W/K") = 1.03992248061984e-05 "Constant thermal conductance of material"; Real TC_1223_1359.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1223_1359.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1223_1359.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1223_1359.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1223_1359.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1223_1359.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1223_1359.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260002559538351 "Constant thermal conductance of material"; Real TC_1224_1232.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1224_1232.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1224_1232.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1224_1232.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1224_1232.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1224_1232.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1224_1232.G(quantity = "ThermalConductance", unit = "W/K") = 2.59991349480984e-05 "Constant thermal conductance of material"; Real TC_1224_1360.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1224_1360.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1224_1360.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1224_1360.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1224_1360.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1224_1360.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1224_1360.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650000513577271 "Constant thermal conductance of material"; Real TC_1224_1518.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1224_1518.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1224_1518.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1224_1518.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1224_1518.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1224_1518.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1224_1518.G(quantity = "ThermalConductance", unit = "W/K") = 5.1730597279598e-05 "Constant thermal conductance of material"; Real TC_1224_1527.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1224_1527.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1224_1527.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1224_1527.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1224_1527.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1224_1527.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1224_1527.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915911528358 "Constant thermal conductance of material"; Real TC_1225_1226.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1225_1226.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1225_1226.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1225_1226.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1225_1226.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1225_1226.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1225_1226.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000796717524e-05 "Constant thermal conductance of material"; Real TC_1225_1233.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1225_1233.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1225_1233.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1225_1233.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1225_1233.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1225_1233.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1225_1233.G(quantity = "ThermalConductance", unit = "W/K") = 2.6000221901699e-05 "Constant thermal conductance of material"; Real TC_1225_1364.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1225_1364.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1225_1364.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1225_1364.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1225_1364.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1225_1364.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1225_1364.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649980538362323 "Constant thermal conductance of material"; Real TC_1225_1520.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1225_1520.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1225_1520.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1225_1520.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1225_1520.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1225_1520.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1225_1520.G(quantity = "ThermalConductance", unit = "W/K") = 5.17320850804845e-05 "Constant thermal conductance of material"; Real TC_1225_1531.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1225_1531.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1225_1531.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1225_1531.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1225_1531.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1225_1531.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1225_1531.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129913947622408 "Constant thermal conductance of material"; Real TC_1226_1227.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1226_1227.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1226_1227.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1226_1227.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1226_1227.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1226_1227.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1226_1227.G(quantity = "ThermalConductance", unit = "W/K") = 2.59992262628496e-05 "Constant thermal conductance of material"; Real TC_1226_1234.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1226_1234.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1226_1234.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1226_1234.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1226_1234.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1226_1234.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1226_1234.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002358351514e-05 "Constant thermal conductance of material"; Real TC_1226_1365.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1226_1365.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1226_1365.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1226_1365.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1226_1365.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1226_1365.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1226_1365.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649994888230038 "Constant thermal conductance of material"; Real TC_1226_1515.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1226_1515.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1226_1515.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1226_1515.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1226_1515.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1226_1515.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1226_1515.G(quantity = "ThermalConductance", unit = "W/K") = 5.17313682597606e-05 "Constant thermal conductance of material"; Real TC_1226_1532.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1226_1532.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1226_1532.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1226_1532.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1226_1532.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1226_1532.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1226_1532.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916534581802 "Constant thermal conductance of material"; Real TC_1227_1228.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1227_1228.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1227_1228.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1227_1228.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1227_1228.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1227_1228.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1227_1228.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998207403423e-05 "Constant thermal conductance of material"; Real TC_1227_1235.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1227_1235.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1227_1235.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1227_1235.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1227_1235.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1227_1235.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1227_1235.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999553342119e-05 "Constant thermal conductance of material"; Real TC_1227_1366.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1227_1366.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1227_1366.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1227_1366.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1227_1366.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1227_1366.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1227_1366.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649983686141131 "Constant thermal conductance of material"; Real TC_1227_1516.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1227_1516.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1227_1516.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1227_1516.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1227_1516.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1227_1516.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1227_1516.G(quantity = "ThermalConductance", unit = "W/K") = 5.1730429116634e-05 "Constant thermal conductance of material"; Real TC_1227_1533.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1227_1533.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1227_1533.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1227_1533.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1227_1533.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1227_1533.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1227_1533.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915228270861 "Constant thermal conductance of material"; Real TC_1228_1229.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1228_1229.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1228_1229.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1228_1229.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1228_1229.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1228_1229.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1228_1229.G(quantity = "ThermalConductance", unit = "W/K") = 2.60006722296104e-05 "Constant thermal conductance of material"; Real TC_1228_1236.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1228_1236.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1228_1236.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1228_1236.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1228_1236.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1228_1236.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1228_1236.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998702169543e-05 "Constant thermal conductance of material"; Real TC_1228_1367.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1228_1367.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1228_1367.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1228_1367.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1228_1367.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1228_1367.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1228_1367.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650017051025193 "Constant thermal conductance of material"; Real TC_1228_1517.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1228_1517.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1228_1517.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1228_1517.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1228_1517.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1228_1517.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1228_1517.G(quantity = "ThermalConductance", unit = "W/K") = 5.17309166328509e-05 "Constant thermal conductance of material"; Real TC_1228_1534.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1228_1534.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1228_1534.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1228_1534.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1228_1534.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1228_1534.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1228_1534.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129913500492719 "Constant thermal conductance of material"; Real TC_1229_1230.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1229_1230.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1229_1230.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1229_1230.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1229_1230.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1229_1230.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1229_1230.G(quantity = "ThermalConductance", unit = "W/K") = 3.71432463676789e-05 "Constant thermal conductance of material"; Real TC_1229_1237.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1229_1237.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1229_1237.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1229_1237.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1229_1237.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1229_1237.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1229_1237.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001876524674e-05 "Constant thermal conductance of material"; Real TC_1229_1368.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1229_1368.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1229_1368.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1229_1368.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1229_1368.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1229_1368.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1229_1368.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650007255840953 "Constant thermal conductance of material"; Real TC_1229_1535.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1229_1535.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1229_1535.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1229_1535.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1229_1535.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1229_1535.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1229_1535.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129919718034071 "Constant thermal conductance of material"; Real TC_1230_1238.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1230_1238.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1230_1238.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1230_1238.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1230_1238.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1230_1238.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1230_1238.G(quantity = "ThermalConductance", unit = "W/K") = 1.03998935391577e-05 "Constant thermal conductance of material"; Real TC_1230_1369.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1230_1369.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1230_1369.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1230_1369.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1230_1369.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1230_1369.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1230_1369.G(quantity = "ThermalConductance", unit = "W/K") = 0.00025999009655854 "Constant thermal conductance of material"; Real TC_1231_1232.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1231_1232.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1231_1232.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1231_1232.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1231_1232.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1231_1232.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1231_1232.G(quantity = "ThermalConductance", unit = "W/K") = 3.71426912161597e-05 "Constant thermal conductance of material"; Real TC_1231_1239.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1231_1239.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1231_1239.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1231_1239.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1231_1239.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1231_1239.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1231_1239.G(quantity = "ThermalConductance", unit = "W/K") = 1.04000919751669e-05 "Constant thermal conductance of material"; Real TC_1231_1370.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1231_1370.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1231_1370.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1231_1370.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1231_1370.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1231_1370.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1231_1370.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260000687135676 "Constant thermal conductance of material"; Real TC_1232_1240.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1232_1240.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1232_1240.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1232_1240.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1232_1240.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1232_1240.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1232_1240.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998337765958e-05 "Constant thermal conductance of material"; Real TC_1232_1371.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1232_1371.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1232_1371.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1232_1371.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1232_1371.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1232_1371.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1232_1371.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649998646893268 "Constant thermal conductance of material"; Real TC_1232_1521.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1232_1521.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1232_1521.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1232_1521.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1232_1521.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1232_1521.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1232_1521.G(quantity = "ThermalConductance", unit = "W/K") = 5.1731146930759e-05 "Constant thermal conductance of material"; Real TC_1232_1536.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1232_1536.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1232_1536.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1232_1536.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1232_1536.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1232_1536.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1232_1536.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916527032636 "Constant thermal conductance of material"; Real TC_1233_1234.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1233_1234.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1233_1234.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1233_1234.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1233_1234.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1233_1234.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1233_1234.G(quantity = "ThermalConductance", unit = "W/K") = 2.5999760057586e-05 "Constant thermal conductance of material"; Real TC_1233_1241.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1233_1241.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1233_1241.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1233_1241.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1233_1241.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1233_1241.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1233_1241.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998814955261e-05 "Constant thermal conductance of material"; Real TC_1233_1375.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1233_1375.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1233_1375.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1233_1375.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1233_1375.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1233_1375.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1233_1375.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649996225560504 "Constant thermal conductance of material"; Real TC_1233_1523.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1233_1523.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1233_1523.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1233_1523.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1233_1523.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1233_1523.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1233_1523.G(quantity = "ThermalConductance", unit = "W/K") = 5.17295325609928e-05 "Constant thermal conductance of material"; Real TC_1233_1540.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1233_1540.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1233_1540.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1233_1540.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1233_1540.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1233_1540.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1233_1540.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916385270944 "Constant thermal conductance of material"; Real TC_1234_1235.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1234_1235.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1234_1235.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1234_1235.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1234_1235.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1234_1235.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1234_1235.G(quantity = "ThermalConductance", unit = "W/K") = 2.59991709558188e-05 "Constant thermal conductance of material"; Real TC_1234_1242.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1234_1242.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1234_1242.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1234_1242.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1234_1242.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1234_1242.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1234_1242.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000535503909e-05 "Constant thermal conductance of material"; Real TC_1234_1376.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1234_1376.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1234_1376.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1234_1376.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1234_1376.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1234_1376.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1234_1376.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649990977986287 "Constant thermal conductance of material"; Real TC_1234_1541.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1234_1541.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1234_1541.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1234_1541.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1234_1541.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1234_1541.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1234_1541.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129912535388345 "Constant thermal conductance of material"; Real TC_1235_1236.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1235_1236.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1235_1236.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1235_1236.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1235_1236.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1235_1236.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1235_1236.G(quantity = "ThermalConductance", unit = "W/K") = 2.60005048805119e-05 "Constant thermal conductance of material"; Real TC_1235_1243.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1235_1243.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1235_1243.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1235_1243.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1235_1243.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1235_1243.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1235_1243.G(quantity = "ThermalConductance", unit = "W/K") = 2.59988419224087e-05 "Constant thermal conductance of material"; Real TC_1235_1377.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1235_1377.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1235_1377.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1235_1377.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1235_1377.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1235_1377.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1235_1377.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649977680747463 "Constant thermal conductance of material"; Real TC_1235_1542.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1235_1542.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1235_1542.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1235_1542.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1235_1542.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1235_1542.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1235_1542.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129917375755333 "Constant thermal conductance of material"; Real TC_1236_1237.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1236_1237.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1236_1237.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1236_1237.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1236_1237.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1236_1237.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1236_1237.G(quantity = "ThermalConductance", unit = "W/K") = 2.60005168721846e-05 "Constant thermal conductance of material"; Real TC_1236_1244.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1236_1244.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1236_1244.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1236_1244.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1236_1244.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1236_1244.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1236_1244.G(quantity = "ThermalConductance", unit = "W/K") = 2.5998733375554e-05 "Constant thermal conductance of material"; Real TC_1236_1378.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1236_1378.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1236_1378.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1236_1378.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1236_1378.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1236_1378.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1236_1378.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649981721548888 "Constant thermal conductance of material"; Real TC_1236_1543.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1236_1543.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1236_1543.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1236_1543.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1236_1543.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1236_1543.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1236_1543.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129918486464728 "Constant thermal conductance of material"; Real TC_1237_1238.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1237_1238.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1237_1238.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1237_1238.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1237_1238.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1237_1238.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1237_1238.G(quantity = "ThermalConductance", unit = "W/K") = 3.7142611072283e-05 "Constant thermal conductance of material"; Real TC_1237_1245.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1237_1245.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1237_1245.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1237_1245.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1237_1245.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1237_1245.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1237_1245.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999465697801e-05 "Constant thermal conductance of material"; Real TC_1237_1379.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1237_1379.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1237_1379.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1237_1379.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1237_1379.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1237_1379.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1237_1379.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650008462077805 "Constant thermal conductance of material"; Real TC_1237_1544.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1237_1544.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1237_1544.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1237_1544.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1237_1544.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1237_1544.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1237_1544.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129918785044379 "Constant thermal conductance of material"; Real TC_1238_1246.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1238_1246.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1238_1246.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1238_1246.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1238_1246.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1238_1246.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1238_1246.G(quantity = "ThermalConductance", unit = "W/K") = 1.04000437376988e-05 "Constant thermal conductance of material"; Real TC_1238_1380.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1238_1380.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1238_1380.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1238_1380.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1238_1380.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1238_1380.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1238_1380.G(quantity = "ThermalConductance", unit = "W/K") = 0.00025998925886146 "Constant thermal conductance of material"; Real TC_1239_1240.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1239_1240.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1239_1240.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1239_1240.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1239_1240.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1239_1240.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1239_1240.G(quantity = "ThermalConductance", unit = "W/K") = 3.7142968461083e-05 "Constant thermal conductance of material"; Real TC_1239_1247.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1239_1247.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1239_1247.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1239_1247.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1239_1247.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1239_1247.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1239_1247.G(quantity = "ThermalConductance", unit = "W/K") = 5.19998892028142e-06 "Constant thermal conductance of material"; Real TC_1239_1381.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1239_1381.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1239_1381.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1239_1381.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1239_1381.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1239_1381.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1239_1381.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260002923845081 "Constant thermal conductance of material"; Real TC_1240_1248.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1240_1248.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1240_1248.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1240_1248.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1240_1248.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1240_1248.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1240_1248.G(quantity = "ThermalConductance", unit = "W/K") = 1.29998914262966e-05 "Constant thermal conductance of material"; Real TC_1240_1382.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1240_1382.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1240_1382.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1240_1382.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1240_1382.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1240_1382.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1240_1382.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649999833209352 "Constant thermal conductance of material"; Real TC_1240_1524.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1240_1524.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1240_1524.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1240_1524.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1240_1524.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1240_1524.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1240_1524.G(quantity = "ThermalConductance", unit = "W/K") = 5.17305716556496e-05 "Constant thermal conductance of material"; Real TC_1240_1545.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1240_1545.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1240_1545.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1240_1545.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1240_1545.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1240_1545.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1240_1545.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129916007156069 "Constant thermal conductance of material"; Real TC_1241_1242.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1241_1242.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1241_1242.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1241_1242.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1241_1242.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1241_1242.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1241_1242.G(quantity = "ThermalConductance", unit = "W/K") = 2.60008208036414e-05 "Constant thermal conductance of material"; Real TC_1241_1252.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1241_1252.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1241_1252.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1241_1252.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1241_1252.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1241_1252.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1241_1252.G(quantity = "ThermalConductance", unit = "W/K") = 1.29999230641004e-05 "Constant thermal conductance of material"; Real TC_1241_1386.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1241_1386.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1241_1386.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1241_1386.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1241_1386.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1241_1386.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1241_1386.G(quantity = "ThermalConductance", unit = "W/K") = 0.00065000913213001 "Constant thermal conductance of material"; Real TC_1241_1526.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1241_1526.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1241_1526.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1241_1526.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1241_1526.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1241_1526.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1241_1526.G(quantity = "ThermalConductance", unit = "W/K") = 5.17313394566741e-05 "Constant thermal conductance of material"; Real TC_1241_1549.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1241_1549.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1241_1549.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1241_1549.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1241_1549.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1241_1549.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1241_1549.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012991551363208 "Constant thermal conductance of material"; Real TC_1242_1243.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1242_1243.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1242_1243.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1242_1243.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1242_1243.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1242_1243.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1242_1243.G(quantity = "ThermalConductance", unit = "W/K") = 2.59992976182874e-05 "Constant thermal conductance of material"; Real TC_1242_1253.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1242_1253.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1242_1253.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1242_1253.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1242_1253.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1242_1253.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1242_1253.G(quantity = "ThermalConductance", unit = "W/K") = 1.2999930948764e-05 "Constant thermal conductance of material"; Real TC_1242_1387.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1242_1387.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1242_1387.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1242_1387.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1242_1387.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1242_1387.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1242_1387.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649983284779599 "Constant thermal conductance of material"; Real TC_1242_1550.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1242_1550.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1242_1550.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1242_1550.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1242_1550.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1242_1550.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1242_1550.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129918190613054 "Constant thermal conductance of material"; Real TC_1243_1244.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1243_1244.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1243_1244.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1243_1244.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1243_1244.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1243_1244.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1243_1244.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003401071339e-05 "Constant thermal conductance of material"; Real TC_1243_1254.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1243_1254.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1243_1254.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1243_1254.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1243_1254.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1243_1254.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1243_1254.G(quantity = "ThermalConductance", unit = "W/K") = 1.30002012253933e-05 "Constant thermal conductance of material"; Real TC_1243_1388.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1243_1388.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1243_1388.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1243_1388.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1243_1388.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1243_1388.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1243_1388.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650013136001402 "Constant thermal conductance of material"; Real TC_1243_1551.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1243_1551.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1243_1551.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1243_1551.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1243_1551.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1243_1551.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1243_1551.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129915903369222 "Constant thermal conductance of material"; Real TC_1244_1245.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1244_1245.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1244_1245.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1244_1245.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1244_1245.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1244_1245.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1244_1245.G(quantity = "ThermalConductance", unit = "W/K") = 2.60008824262886e-05 "Constant thermal conductance of material"; Real TC_1244_1255.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1244_1255.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1244_1255.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1244_1255.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1244_1255.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1244_1255.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1244_1255.G(quantity = "ThermalConductance", unit = "W/K") = 1.29999257995103e-05 "Constant thermal conductance of material"; Real TC_1244_1389.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1244_1389.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1244_1389.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1244_1389.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1244_1389.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1244_1389.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1244_1389.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650031364601429 "Constant thermal conductance of material"; Real TC_1244_1552.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1244_1552.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1244_1552.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1244_1552.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1244_1552.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1244_1552.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1244_1552.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129918319719953 "Constant thermal conductance of material"; Real TC_1245_1246.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1245_1246.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1245_1246.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1245_1246.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1245_1246.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1245_1246.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1245_1246.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430044141915e-05 "Constant thermal conductance of material"; Real TC_1245_1256.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1245_1256.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1245_1256.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1245_1256.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1245_1256.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1245_1256.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1245_1256.G(quantity = "ThermalConductance", unit = "W/K") = 1.29998667022127e-05 "Constant thermal conductance of material"; Real TC_1245_1390.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1245_1390.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1245_1390.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1245_1390.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1245_1390.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1245_1390.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1245_1390.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650007417966962 "Constant thermal conductance of material"; Real TC_1245_1553.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1245_1553.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1245_1553.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1245_1553.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1245_1553.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1245_1553.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1245_1553.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129913845262341 "Constant thermal conductance of material"; Real TC_1246_1257.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1246_1257.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1246_1257.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1246_1257.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1246_1257.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1246_1257.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1246_1257.G(quantity = "ThermalConductance", unit = "W/K") = 5.20008797674765e-06 "Constant thermal conductance of material"; Real TC_1246_1391.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1246_1391.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1246_1391.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1246_1391.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1246_1391.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1246_1391.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1246_1391.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259871244635125 "Constant thermal conductance of material"; Real TC_1247_1248.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1247_1248.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1247_1248.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1247_1248.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1247_1248.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1247_1248.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1247_1248.G(quantity = "ThermalConductance", unit = "W/K") = 0.000111427662831983 "Constant thermal conductance of material"; Real TC_1247_1258.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1247_1258.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1247_1258.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1247_1258.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1247_1258.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1247_1258.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1247_1258.G(quantity = "ThermalConductance", unit = "W/K") = 5.19999197857859e-06 "Constant thermal conductance of material"; Real TC_1247_1392.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1247_1392.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1247_1392.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1247_1392.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1247_1392.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1247_1392.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1247_1392.G(quantity = "ThermalConductance", unit = "W/K") = 0.000779977347712613 "Constant thermal conductance of material"; Real TC_1248_1249.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1248_1249.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1248_1249.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1248_1249.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1248_1249.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1248_1249.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1248_1249.G(quantity = "ThermalConductance", unit = "W/K") = 7.79998239281631e-05 "Constant thermal conductance of material"; Real TC_1248_1259.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1248_1259.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1248_1259.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1248_1259.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1248_1259.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1248_1259.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1248_1259.G(quantity = "ThermalConductance", unit = "W/K") = 1.29998015263122e-05 "Constant thermal conductance of material"; Real TC_1248_1393.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1248_1393.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1248_1393.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1248_1393.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1248_1393.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1248_1393.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1248_1393.G(quantity = "ThermalConductance", unit = "W/K") = 0.00194995578859191 "Constant thermal conductance of material"; Real TC_1248_1554.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1248_1554.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1248_1554.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1248_1554.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1248_1554.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1248_1554.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1248_1554.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389746947197175 "Constant thermal conductance of material"; Real TC_1249_1250.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1249_1250.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1249_1250.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1249_1250.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1249_1250.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1249_1250.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1249_1250.G(quantity = "ThermalConductance", unit = "W/K") = 7.80022766078515e-05 "Constant thermal conductance of material"; Real TC_1249_1260.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1249_1260.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1249_1260.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1249_1260.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1249_1260.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1249_1260.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1249_1260.G(quantity = "ThermalConductance", unit = "W/K") = 1.29998335949341e-05 "Constant thermal conductance of material"; Real TC_1249_1394.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1249_1394.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1249_1394.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1249_1394.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1249_1394.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1249_1394.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1249_1394.G(quantity = "ThermalConductance", unit = "W/K") = 0.00194995658442934 "Constant thermal conductance of material"; Real TC_1249_1524.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1249_1524.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1249_1524.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1249_1524.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1249_1524.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1249_1524.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1249_1524.G(quantity = "ThermalConductance", unit = "W/K") = 1.73033422243181e-05 "Constant thermal conductance of material"; Real TC_1249_1555.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1249_1555.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1249_1555.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1249_1555.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1249_1555.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1249_1555.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1249_1555.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389733099248162 "Constant thermal conductance of material"; Real TC_1250_1251.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1250_1251.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1250_1251.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1250_1251.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1250_1251.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1250_1251.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1250_1251.G(quantity = "ThermalConductance", unit = "W/K") = 7.79982028063881e-05 "Constant thermal conductance of material"; Real TC_1250_1261.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1250_1261.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1250_1261.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1250_1261.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1250_1261.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1250_1261.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1250_1261.G(quantity = "ThermalConductance", unit = "W/K") = 1.29997880123961e-05 "Constant thermal conductance of material"; Real TC_1250_1395.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1250_1395.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1250_1395.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1250_1395.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1250_1395.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1250_1395.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1250_1395.G(quantity = "ThermalConductance", unit = "W/K") = 0.00195004429284608 "Constant thermal conductance of material"; Real TC_1250_1525.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1250_1525.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1250_1525.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1250_1525.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1250_1525.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1250_1525.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1250_1525.G(quantity = "ThermalConductance", unit = "W/K") = 1.73033542339953e-05 "Constant thermal conductance of material"; Real TC_1250_1556.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1250_1556.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1250_1556.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1250_1556.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1250_1556.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1250_1556.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1250_1556.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389736220075625 "Constant thermal conductance of material"; Real TC_1251_1252.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1251_1252.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1251_1252.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1251_1252.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1251_1252.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1251_1252.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1251_1252.G(quantity = "ThermalConductance", unit = "W/K") = 7.80011353390992e-05 "Constant thermal conductance of material"; Real TC_1251_1262.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1251_1262.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1251_1262.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1251_1262.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1251_1262.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1251_1262.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1251_1262.G(quantity = "ThermalConductance", unit = "W/K") = 1.29999083157605e-05 "Constant thermal conductance of material"; Real TC_1251_1396.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1251_1396.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1251_1396.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1251_1396.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1251_1396.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1251_1396.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1251_1396.G(quantity = "ThermalConductance", unit = "W/K") = 0.00194992274527532 "Constant thermal conductance of material"; Real TC_1251_1526.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1251_1526.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1251_1526.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1251_1526.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1251_1526.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1251_1526.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1251_1526.G(quantity = "ThermalConductance", unit = "W/K") = 1.73032867004704e-05 "Constant thermal conductance of material"; Real TC_1251_1557.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1251_1557.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1251_1557.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1251_1557.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1251_1557.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1251_1557.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1251_1557.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389730848861284 "Constant thermal conductance of material"; Real TC_1252_1253.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1252_1253.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1252_1253.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1252_1253.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1252_1253.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1252_1253.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1252_1253.G(quantity = "ThermalConductance", unit = "W/K") = 7.79985941593704e-05 "Constant thermal conductance of material"; Real TC_1252_1263.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1252_1263.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1252_1263.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1252_1263.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1252_1263.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1252_1263.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1252_1263.G(quantity = "ThermalConductance", unit = "W/K") = 1.30001735336177e-05 "Constant thermal conductance of material"; Real TC_1252_1397.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1252_1397.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1252_1397.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1252_1397.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1252_1397.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1252_1397.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1252_1397.G(quantity = "ThermalConductance", unit = "W/K") = 0.00194995191969818 "Constant thermal conductance of material"; Real TC_1252_1558.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1252_1558.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1252_1558.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1252_1558.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1252_1558.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1252_1558.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1252_1558.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389749817991499 "Constant thermal conductance of material"; Real TC_1253_1254.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1253_1254.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1253_1254.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1253_1254.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1253_1254.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1253_1254.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1253_1254.G(quantity = "ThermalConductance", unit = "W/K") = 7.8001738200294e-05 "Constant thermal conductance of material"; Real TC_1253_1264.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1253_1264.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1253_1264.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1253_1264.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1253_1264.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1253_1264.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1253_1264.G(quantity = "ThermalConductance", unit = "W/K") = 1.29998875077338e-05 "Constant thermal conductance of material"; Real TC_1253_1398.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1253_1398.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1253_1398.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1253_1398.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1253_1398.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1253_1398.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1253_1398.G(quantity = "ThermalConductance", unit = "W/K") = 0.00195005268301489 "Constant thermal conductance of material"; Real TC_1253_1559.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1253_1559.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1253_1559.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1253_1559.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1253_1559.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1253_1559.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1253_1559.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389734809107401 "Constant thermal conductance of material"; Real TC_1254_1255.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1254_1255.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1254_1255.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1254_1255.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1254_1255.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1254_1255.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1254_1255.G(quantity = "ThermalConductance", unit = "W/K") = 7.79969794223151e-05 "Constant thermal conductance of material"; Real TC_1254_1265.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1254_1265.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1254_1265.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1254_1265.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1254_1265.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1254_1265.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1254_1265.G(quantity = "ThermalConductance", unit = "W/K") = 1.30001900971193e-05 "Constant thermal conductance of material"; Real TC_1254_1399.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1254_1399.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1254_1399.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1254_1399.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1254_1399.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1254_1399.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1254_1399.G(quantity = "ThermalConductance", unit = "W/K") = 0.00194995929595069 "Constant thermal conductance of material"; Real TC_1254_1560.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1254_1560.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1254_1560.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1254_1560.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1254_1560.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1254_1560.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1254_1560.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389753035884841 "Constant thermal conductance of material"; Real TC_1255_1256.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1255_1256.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1255_1256.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1255_1256.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1255_1256.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1255_1256.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1255_1256.G(quantity = "ThermalConductance", unit = "W/K") = 7.80000699928839e-05 "Constant thermal conductance of material"; Real TC_1255_1266.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1255_1266.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1255_1266.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1255_1266.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1255_1266.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1255_1266.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1255_1266.G(quantity = "ThermalConductance", unit = "W/K") = 1.29998127860966e-05 "Constant thermal conductance of material"; Real TC_1255_1400.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1255_1400.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1255_1400.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1255_1400.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1255_1400.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1255_1400.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1255_1400.G(quantity = "ThermalConductance", unit = "W/K") = 0.00194995974971329 "Constant thermal conductance of material"; Real TC_1255_1561.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1255_1561.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1255_1561.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1255_1561.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1255_1561.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1255_1561.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1255_1561.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389731209507201 "Constant thermal conductance of material"; Real TC_1256_1257.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1256_1257.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1256_1257.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1256_1257.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1256_1257.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1256_1257.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1256_1257.G(quantity = "ThermalConductance", unit = "W/K") = 0.000111430304012609 "Constant thermal conductance of material"; Real TC_1256_1267.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1256_1267.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1256_1267.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1256_1267.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1256_1267.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1256_1267.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1256_1267.G(quantity = "ThermalConductance", unit = "W/K") = 1.29997711557108e-05 "Constant thermal conductance of material"; Real TC_1256_1401.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1256_1401.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1256_1401.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1256_1401.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1256_1401.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1256_1401.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1256_1401.G(quantity = "ThermalConductance", unit = "W/K") = 0.00195005794245416 "Constant thermal conductance of material"; Real TC_1256_1562.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1256_1562.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1256_1562.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1256_1562.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1256_1562.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1256_1562.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1256_1562.G(quantity = "ThermalConductance", unit = "W/K") = 0.00389737042268826 "Constant thermal conductance of material"; Real TC_1257_1268.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1257_1268.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1257_1268.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1257_1268.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1257_1268.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1257_1268.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1257_1268.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000272094447e-06 "Constant thermal conductance of material"; Real TC_1257_1402.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1257_1402.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1257_1402.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1257_1402.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1257_1402.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1257_1402.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1257_1402.G(quantity = "ThermalConductance", unit = "W/K") = 0.000779993389886525 "Constant thermal conductance of material"; Real TC_1258_1259.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1258_1259.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1258_1259.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1258_1259.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1258_1259.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1258_1259.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1258_1259.G(quantity = "ThermalConductance", unit = "W/K") = 3.71429369446296e-05 "Constant thermal conductance of material"; Real TC_1258_1403.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1258_1403.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1258_1403.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1258_1403.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1258_1403.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1258_1403.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1258_1403.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259991041934938 "Constant thermal conductance of material"; Real TC_1259_1260.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1259_1260.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1259_1260.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1259_1260.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1259_1260.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1259_1260.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1259_1260.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998432935224e-05 "Constant thermal conductance of material"; Real TC_1259_1404.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1259_1404.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1259_1404.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1259_1404.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1259_1404.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1259_1404.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1259_1404.G(quantity = "ThermalConductance", unit = "W/K") = 0.00065 "Constant thermal conductance of material"; Real TC_1260_1261.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1260_1261.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1260_1261.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1260_1261.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1260_1261.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1260_1261.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1260_1261.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004775549188e-05 "Constant thermal conductance of material"; Real TC_1260_1405.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1260_1405.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1260_1405.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1260_1405.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1260_1405.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1260_1405.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1260_1405.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649997203110141 "Constant thermal conductance of material"; Real TC_1261_1262.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1261_1262.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1261_1262.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1261_1262.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1261_1262.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1261_1262.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1261_1262.G(quantity = "ThermalConductance", unit = "W/K") = 2.59983079526223e-05 "Constant thermal conductance of material"; Real TC_1261_1406.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1261_1406.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1261_1406.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1261_1406.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1261_1406.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1261_1406.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1261_1406.G(quantity = "ThermalConductance", unit = "W/K") = 0.0006500028192839 "Constant thermal conductance of material"; Real TC_1262_1263.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1262_1263.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1262_1263.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1262_1263.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1262_1263.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1262_1263.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1262_1263.G(quantity = "ThermalConductance", unit = "W/K") = 2.59978660976223e-05 "Constant thermal conductance of material"; Real TC_1262_1407.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1262_1407.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1262_1407.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1262_1407.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1262_1407.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1262_1407.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1262_1407.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649999429594898 "Constant thermal conductance of material"; Real TC_1263_1264.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1263_1264.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1263_1264.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1263_1264.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1263_1264.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1263_1264.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1263_1264.G(quantity = "ThermalConductance", unit = "W/K") = 2.60014619883045e-05 "Constant thermal conductance of material"; Real TC_1263_1408.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1263_1408.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1263_1408.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1263_1408.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1263_1408.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1263_1408.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1263_1408.G(quantity = "ThermalConductance", unit = "W/K") = 0.00065000289368598 "Constant thermal conductance of material"; Real TC_1264_1265.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1264_1265.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1264_1265.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1264_1265.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1264_1265.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1264_1265.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1264_1265.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000000000006e-05 "Constant thermal conductance of material"; Real TC_1264_1409.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1264_1409.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1264_1409.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1264_1409.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1264_1409.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1264_1409.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1264_1409.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650002346536513 "Constant thermal conductance of material"; Real TC_1265_1266.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1265_1266.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1265_1266.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1265_1266.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1265_1266.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1265_1266.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1265_1266.G(quantity = "ThermalConductance", unit = "W/K") = 2.59996294237538e-05 "Constant thermal conductance of material"; Real TC_1265_1410.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1265_1410.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1265_1410.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1265_1410.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1265_1410.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1265_1410.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1265_1410.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650001185311616 "Constant thermal conductance of material"; Real TC_1266_1267.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1266_1267.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1266_1267.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1266_1267.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1266_1267.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1266_1267.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1266_1267.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003076959491e-05 "Constant thermal conductance of material"; Real TC_1266_1411.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1266_1411.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1266_1411.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1266_1411.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1266_1411.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1266_1411.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1266_1411.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649998805456673 "Constant thermal conductance of material"; Real TC_1267_1268.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1267_1268.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1267_1268.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1267_1268.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1267_1268.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1267_1268.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1267_1268.G(quantity = "ThermalConductance", unit = "W/K") = 3.71427251964801e-05 "Constant thermal conductance of material"; Real TC_1267_1412.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1267_1412.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1267_1412.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1267_1412.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1267_1412.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1267_1412.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1267_1412.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650004485971725 "Constant thermal conductance of material"; Real TC_1268_1413.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1268_1413.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1268_1413.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1268_1413.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1268_1413.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1268_1413.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1268_1413.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260008936550488 "Constant thermal conductance of material"; Real TC_1269_1270.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1269_1270.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1269_1270.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1269_1270.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1269_1270.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1269_1270.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1269_1270.G(quantity = "ThermalConductance", unit = "W/K") = 3.71426619428259e-05 "Constant thermal conductance of material"; Real TC_1269_1280.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1269_1280.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1269_1280.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1269_1280.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1269_1280.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1269_1280.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1269_1280.G(quantity = "ThermalConductance", unit = "W/K") = 6.93332175958837e-06 "Constant thermal conductance of material"; Real TC_1269_1477.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1269_1477.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1269_1477.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1269_1477.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1269_1477.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1269_1477.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1269_1477.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259993505439195 "Constant thermal conductance of material"; Real TC_1270_1271.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1270_1271.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1270_1271.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1270_1271.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1270_1271.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1270_1271.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1270_1271.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001008929022e-05 "Constant thermal conductance of material"; Real TC_1270_1281.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1270_1281.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1270_1281.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1270_1281.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1270_1281.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1270_1281.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1270_1281.G(quantity = "ThermalConductance", unit = "W/K") = 1.73336319829364e-05 "Constant thermal conductance of material"; Real TC_1270_1478.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1270_1478.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1270_1478.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1270_1478.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1270_1478.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1270_1478.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1270_1478.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650000000000001 "Constant thermal conductance of material"; Real TC_1271_1272.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1271_1272.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1271_1272.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1271_1272.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1271_1272.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1271_1272.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1271_1272.G(quantity = "ThermalConductance", unit = "W/K") = 2.59995306143737e-05 "Constant thermal conductance of material"; Real TC_1271_1282.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1271_1282.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1271_1282.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1271_1282.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1271_1282.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1271_1282.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1271_1282.G(quantity = "ThermalConductance", unit = "W/K") = 1.73334438077999e-05 "Constant thermal conductance of material"; Real TC_1271_1479.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1271_1479.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1271_1479.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1271_1479.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1271_1479.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1271_1479.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1271_1479.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650006296070284 "Constant thermal conductance of material"; Real TC_1272_1273.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1272_1273.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1272_1273.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1272_1273.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1272_1273.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1272_1273.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1272_1273.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001388599596e-05 "Constant thermal conductance of material"; Real TC_1272_1283.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1272_1283.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1272_1283.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1272_1283.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1272_1283.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1272_1283.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1272_1283.G(quantity = "ThermalConductance", unit = "W/K") = 1.7333618524567e-05 "Constant thermal conductance of material"; Real TC_1272_1480.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1272_1480.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1272_1480.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1272_1480.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1272_1480.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1272_1480.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1272_1480.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650004836993327 "Constant thermal conductance of material"; Real TC_1273_1274.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1273_1274.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1273_1274.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1273_1274.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1273_1274.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1273_1274.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1273_1274.G(quantity = "ThermalConductance", unit = "W/K") = 2.60044483985746e-05 "Constant thermal conductance of material"; Real TC_1273_1284.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1273_1284.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1273_1284.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1273_1284.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1273_1284.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1273_1284.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1273_1284.G(quantity = "ThermalConductance", unit = "W/K") = 1.7333307063043e-05 "Constant thermal conductance of material"; Real TC_1273_1481.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1273_1481.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1273_1481.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1273_1481.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1273_1481.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1273_1481.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1273_1481.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650004831384677 "Constant thermal conductance of material"; Real TC_1274_1275.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1274_1275.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1274_1275.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1274_1275.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1274_1275.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1274_1275.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1274_1275.G(quantity = "ThermalConductance", unit = "W/K") = 2.60012614317247e-05 "Constant thermal conductance of material"; Real TC_1274_1285.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1274_1285.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1274_1285.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1274_1285.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1274_1285.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1274_1285.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1274_1285.G(quantity = "ThermalConductance", unit = "W/K") = 1.73335102623057e-05 "Constant thermal conductance of material"; Real TC_1274_1482.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1274_1482.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1274_1482.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1274_1482.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1274_1482.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1274_1482.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1274_1482.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649997578575235 "Constant thermal conductance of material"; Real TC_1275_1276.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1275_1276.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1275_1276.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1275_1276.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1275_1276.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1275_1276.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1275_1276.G(quantity = "ThermalConductance", unit = "W/K") = 2.59996251405721e-05 "Constant thermal conductance of material"; Real TC_1275_1286.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1275_1286.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1275_1286.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1275_1286.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1275_1286.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1275_1286.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1275_1286.G(quantity = "ThermalConductance", unit = "W/K") = 1.73336314468658e-05 "Constant thermal conductance of material"; Real TC_1275_1483.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1275_1483.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1275_1483.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1275_1483.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1275_1483.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1275_1483.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1275_1483.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649999023761642 "Constant thermal conductance of material"; Real TC_1276_1277.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1276_1277.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1276_1277.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1276_1277.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1276_1277.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1276_1277.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1276_1277.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999438706783e-05 "Constant thermal conductance of material"; Real TC_1276_1287.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1276_1287.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1276_1287.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1276_1287.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1276_1287.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1276_1287.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1276_1287.G(quantity = "ThermalConductance", unit = "W/K") = 1.73335209856394e-05 "Constant thermal conductance of material"; Real TC_1276_1484.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1276_1484.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1276_1484.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1276_1484.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1276_1484.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1276_1484.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1276_1484.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649996545564012 "Constant thermal conductance of material"; Real TC_1277_1278.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1277_1278.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1277_1278.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1277_1278.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1277_1278.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1277_1278.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1277_1278.G(quantity = "ThermalConductance", unit = "W/K") = 2.59995099895316e-05 "Constant thermal conductance of material"; Real TC_1277_1288.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1277_1288.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1277_1288.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1277_1288.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1277_1288.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1277_1288.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1277_1288.G(quantity = "ThermalConductance", unit = "W/K") = 1.73334335990375e-05 "Constant thermal conductance of material"; Real TC_1277_1485.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1277_1485.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1277_1485.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1277_1485.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1277_1485.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1277_1485.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1277_1485.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649996990429566 "Constant thermal conductance of material"; Real TC_1278_1279.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1278_1279.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1278_1279.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1278_1279.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1278_1279.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1278_1279.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1278_1279.G(quantity = "ThermalConductance", unit = "W/K") = 3.71426293311805e-05 "Constant thermal conductance of material"; Real TC_1278_1289.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1278_1289.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1278_1289.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1278_1289.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1278_1289.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1278_1289.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1278_1289.G(quantity = "ThermalConductance", unit = "W/K") = 1.73331736694527e-05 "Constant thermal conductance of material"; Real TC_1278_1486.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1278_1486.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1278_1486.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1278_1486.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1278_1486.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1278_1486.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1278_1486.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650002218967735 "Constant thermal conductance of material"; Real TC_1279_1290.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1279_1290.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1279_1290.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1279_1290.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1279_1290.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1279_1290.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1279_1290.G(quantity = "ThermalConductance", unit = "W/K") = 6.93337376228065e-06 "Constant thermal conductance of material"; Real TC_1279_1487.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1279_1487.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1279_1487.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1279_1487.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1279_1487.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1279_1487.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1279_1487.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001799694054 "Constant thermal conductance of material"; Real TC_1280_1281.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1280_1281.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1280_1281.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1280_1281.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1280_1281.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1280_1281.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1280_1281.G(quantity = "ThermalConductance", unit = "W/K") = 7.42857086531125e-05 "Constant thermal conductance of material"; Real TC_1280_1291.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1280_1291.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1280_1291.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1280_1291.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1280_1291.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1280_1291.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1280_1291.G(quantity = "ThermalConductance", unit = "W/K") = 6.11782054867662e-06 "Constant thermal conductance of material"; Real TC_1280_1466.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1280_1466.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1280_1466.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1280_1466.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1280_1466.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1280_1466.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1280_1466.G(quantity = "ThermalConductance", unit = "W/K") = 0.000520000671539055 "Constant thermal conductance of material"; Real TC_1281_1282.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1281_1282.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1281_1282.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1281_1282.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1281_1282.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1281_1282.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1281_1282.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000840592198e-05 "Constant thermal conductance of material"; Real TC_1281_1292.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1281_1292.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1281_1292.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1281_1292.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1281_1292.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1281_1292.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1281_1292.G(quantity = "ThermalConductance", unit = "W/K") = 1.52940685104102e-05 "Constant thermal conductance of material"; Real TC_1281_1467.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1281_1467.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1281_1467.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1281_1467.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1281_1467.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1281_1467.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1281_1467.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130000778755549 "Constant thermal conductance of material"; Real TC_1282_1283.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1282_1283.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1282_1283.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1282_1283.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1282_1283.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1282_1283.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1282_1283.G(quantity = "ThermalConductance", unit = "W/K") = 5.19984858268946e-05 "Constant thermal conductance of material"; Real TC_1282_1293.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1282_1293.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1282_1293.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1282_1293.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1282_1293.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1282_1293.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1282_1293.G(quantity = "ThermalConductance", unit = "W/K") = 1.52937854844616e-05 "Constant thermal conductance of material"; Real TC_1282_1468.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1282_1468.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1282_1468.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1282_1468.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1282_1468.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1282_1468.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1282_1468.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129999950201766 "Constant thermal conductance of material"; Real TC_1283_1284.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1283_1284.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1283_1284.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1283_1284.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1283_1284.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1283_1284.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1283_1284.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001634120422e-05 "Constant thermal conductance of material"; Real TC_1283_1294.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1283_1294.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1283_1294.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1283_1294.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1283_1294.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1283_1294.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1283_1294.G(quantity = "ThermalConductance", unit = "W/K") = 1.52934722666501e-05 "Constant thermal conductance of material"; Real TC_1283_1469.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1283_1469.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1283_1469.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1283_1469.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1283_1469.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1283_1469.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1283_1469.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129999214403066 "Constant thermal conductance of material"; Real TC_1284_1285.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1284_1285.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1284_1285.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1284_1285.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1284_1285.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1284_1285.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1284_1285.G(quantity = "ThermalConductance", unit = "W/K") = 5.19863201094415e-05 "Constant thermal conductance of material"; Real TC_1284_1295.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1284_1295.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1284_1295.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1284_1295.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1284_1295.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1284_1295.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1284_1295.G(quantity = "ThermalConductance", unit = "W/K") = 1.52943908953664e-05 "Constant thermal conductance of material"; Real TC_1284_1470.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1284_1470.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1284_1470.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1284_1470.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1284_1470.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1284_1470.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1284_1470.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130000206584538 "Constant thermal conductance of material"; Real TC_1285_1286.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1285_1286.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1285_1286.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1285_1286.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1285_1286.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1285_1286.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1285_1286.G(quantity = "ThermalConductance", unit = "W/K") = 5.20014966612931e-05 "Constant thermal conductance of material"; Real TC_1285_1296.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1285_1296.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1285_1296.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1285_1296.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1285_1296.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1285_1296.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1285_1296.G(quantity = "ThermalConductance", unit = "W/K") = 1.52939204698647e-05 "Constant thermal conductance of material"; Real TC_1285_1471.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1285_1471.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1285_1471.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1285_1471.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1285_1471.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1285_1471.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1285_1471.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130000588661004 "Constant thermal conductance of material"; Real TC_1286_1287.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1286_1287.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1286_1287.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1286_1287.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1286_1287.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1286_1287.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1286_1287.G(quantity = "ThermalConductance", unit = "W/K") = 5.20003404834863e-05 "Constant thermal conductance of material"; Real TC_1286_1297.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1286_1297.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1286_1297.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1286_1297.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1286_1297.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1286_1297.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1286_1297.G(quantity = "ThermalConductance", unit = "W/K") = 1.5294170952176e-05 "Constant thermal conductance of material"; Real TC_1286_1472.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1286_1472.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1286_1472.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1286_1472.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1286_1472.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1286_1472.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1286_1472.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130000419542279 "Constant thermal conductance of material"; Real TC_1287_1288.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1287_1288.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1287_1288.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1287_1288.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1287_1288.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1287_1288.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1287_1288.G(quantity = "ThermalConductance", unit = "W/K") = 5.19986675549636e-05 "Constant thermal conductance of material"; Real TC_1287_1298.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1287_1298.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1287_1298.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1287_1298.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1287_1298.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1287_1298.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1287_1298.G(quantity = "ThermalConductance", unit = "W/K") = 1.52941022998552e-05 "Constant thermal conductance of material"; Real TC_1287_1473.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1287_1473.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1287_1473.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1287_1473.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1287_1473.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1287_1473.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1287_1473.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130000579090617 "Constant thermal conductance of material"; Real TC_1288_1289.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1288_1289.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1288_1289.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1288_1289.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1288_1289.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1288_1289.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1288_1289.G(quantity = "ThermalConductance", unit = "W/K") = 5.19999177552671e-05 "Constant thermal conductance of material"; Real TC_1288_1299.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1288_1299.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1288_1299.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1288_1299.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1288_1299.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1288_1299.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1288_1299.G(quantity = "ThermalConductance", unit = "W/K") = 1.52941615317253e-05 "Constant thermal conductance of material"; Real TC_1288_1474.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1288_1474.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1288_1474.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1288_1474.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1288_1474.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1288_1474.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1288_1474.G(quantity = "ThermalConductance", unit = "W/K") = 0.00130000832604804 "Constant thermal conductance of material"; Real TC_1289_1290.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1289_1290.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1289_1290.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1289_1290.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1289_1290.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1289_1290.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1289_1290.G(quantity = "ThermalConductance", unit = "W/K") = 7.42858473167779e-05 "Constant thermal conductance of material"; Real TC_1289_1300.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1289_1300.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1289_1300.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1289_1300.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1289_1300.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1289_1300.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1289_1300.G(quantity = "ThermalConductance", unit = "W/K") = 1.52934409265876e-05 "Constant thermal conductance of material"; Real TC_1289_1475.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1289_1475.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1289_1475.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1289_1475.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1289_1475.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1289_1475.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1289_1475.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129999424234316 "Constant thermal conductance of material"; Real TC_1290_1301.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1290_1301.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1290_1301.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1290_1301.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1290_1301.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1290_1301.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1290_1301.G(quantity = "ThermalConductance", unit = "W/K") = 6.11759299067499e-06 "Constant thermal conductance of material"; Real TC_1290_1476.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1290_1476.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1290_1476.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1290_1476.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1290_1476.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1290_1476.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1290_1476.G(quantity = "ThermalConductance", unit = "W/K") = 0.000520001750426667 "Constant thermal conductance of material"; Real TC_1291_1292.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1291_1292.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1291_1292.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1291_1292.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1291_1292.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1291_1292.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1291_1292.G(quantity = "ThermalConductance", unit = "W/K") = 5.19996633974597e-05 "Constant thermal conductance of material"; Real TC_1291_1302.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1291_1302.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1291_1302.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1291_1302.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1291_1302.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1291_1302.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1291_1302.G(quantity = "ThermalConductance", unit = "W/K") = 7.42858457150737e-06 "Constant thermal conductance of material"; Real TC_1291_1461.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1291_1461.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1291_1461.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1291_1461.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1291_1461.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1291_1461.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1291_1461.G(quantity = "ThermalConductance", unit = "W/K") = 0.000364003590664274 "Constant thermal conductance of material"; Real TC_1292_1293.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1292_1293.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1292_1293.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1292_1293.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1292_1293.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1292_1293.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1292_1293.G(quantity = "ThermalConductance", unit = "W/K") = 3.64004126231645e-05 "Constant thermal conductance of material"; Real TC_1292_1303.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1292_1303.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1292_1303.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1292_1303.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1292_1303.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1292_1303.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1292_1303.G(quantity = "ThermalConductance", unit = "W/K") = 1.85714915665307e-05 "Constant thermal conductance of material"; Real TC_1292_1462.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1292_1462.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1292_1462.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1292_1462.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1292_1462.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1292_1462.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1292_1462.G(quantity = "ThermalConductance", unit = "W/K") = 0.000909999382442272 "Constant thermal conductance of material"; Real TC_1293_1294.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1293_1294.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1293_1294.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1293_1294.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1293_1294.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1293_1294.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1293_1294.G(quantity = "ThermalConductance", unit = "W/K") = 3.64013177303565e-05 "Constant thermal conductance of material"; Real TC_1293_1304.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1293_1304.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1293_1304.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1293_1304.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1293_1304.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1293_1304.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1293_1304.G(quantity = "ThermalConductance", unit = "W/K") = 1.85713671908562e-05 "Constant thermal conductance of material"; Real TC_1293_1497.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1293_1497.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1293_1497.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1293_1497.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1293_1497.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1293_1497.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1293_1497.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181059060011354 "Constant thermal conductance of material"; Real TC_1294_1295.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1294_1295.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1294_1295.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1294_1295.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1294_1295.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1294_1295.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1294_1295.G(quantity = "ThermalConductance", unit = "W/K") = 3.63970300898798e-05 "Constant thermal conductance of material"; Real TC_1294_1305.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1294_1305.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1294_1305.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1294_1305.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1294_1305.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1294_1305.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1294_1305.G(quantity = "ThermalConductance", unit = "W/K") = 1.85707839356772e-05 "Constant thermal conductance of material"; Real TC_1294_1498.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1294_1498.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1294_1498.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1294_1498.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1294_1498.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1294_1498.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1294_1498.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181059681841791 "Constant thermal conductance of material"; Real TC_1295_1296.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1295_1296.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1295_1296.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1295_1296.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1295_1296.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1295_1296.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1295_1296.G(quantity = "ThermalConductance", unit = "W/K") = 3.63996865203799e-05 "Constant thermal conductance of material"; Real TC_1295_1306.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1295_1306.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1295_1306.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1295_1306.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1295_1306.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1295_1306.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1295_1306.G(quantity = "ThermalConductance", unit = "W/K") = 1.85717092337917e-05 "Constant thermal conductance of material"; Real TC_1295_1499.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1295_1499.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1295_1499.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1295_1499.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1295_1499.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1295_1499.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1295_1499.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181057904818034 "Constant thermal conductance of material"; Real TC_1296_1297.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1296_1297.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1296_1297.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1296_1297.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1296_1297.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1296_1297.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1296_1297.G(quantity = "ThermalConductance", unit = "W/K") = 3.64000345154887e-05 "Constant thermal conductance of material"; Real TC_1296_1307.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1296_1307.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1296_1307.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1296_1307.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1296_1307.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1296_1307.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1296_1307.G(quantity = "ThermalConductance", unit = "W/K") = 1.85720878360194e-05 "Constant thermal conductance of material"; Real TC_1296_1500.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1296_1500.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1296_1500.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1296_1500.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1296_1500.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1296_1500.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1296_1500.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181057233253913 "Constant thermal conductance of material"; Real TC_1297_1298.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1297_1298.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1297_1298.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1297_1298.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1297_1298.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1297_1298.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1297_1298.G(quantity = "ThermalConductance", unit = "W/K") = 3.63988184941835e-05 "Constant thermal conductance of material"; Real TC_1297_1308.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1297_1308.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1297_1308.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1297_1308.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1297_1308.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1297_1308.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1297_1308.G(quantity = "ThermalConductance", unit = "W/K") = 1.85718667835231e-05 "Constant thermal conductance of material"; Real TC_1298_1299.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1298_1299.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1298_1299.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1298_1299.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1298_1299.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1298_1299.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1298_1299.G(quantity = "ThermalConductance", unit = "W/K") = 3.64002810783187e-05 "Constant thermal conductance of material"; Real TC_1298_1309.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1298_1309.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1298_1309.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1298_1309.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1298_1309.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1298_1309.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1298_1309.G(quantity = "ThermalConductance", unit = "W/K") = 1.85709939588859e-05 "Constant thermal conductance of material"; Real TC_1299_1300.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1299_1300.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1299_1300.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1299_1300.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1299_1300.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1299_1300.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1299_1300.G(quantity = "ThermalConductance", unit = "W/K") = 3.64003903527116e-05 "Constant thermal conductance of material"; Real TC_1299_1310.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1299_1310.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1299_1310.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1299_1310.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1299_1310.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1299_1310.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1299_1310.G(quantity = "ThermalConductance", unit = "W/K") = 1.85718612096568e-05 "Constant thermal conductance of material"; Real TC_1300_1301.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1300_1301.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1300_1301.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1300_1301.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1300_1301.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1300_1301.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1300_1301.G(quantity = "ThermalConductance", unit = "W/K") = 5.2000096933056e-05 "Constant thermal conductance of material"; Real TC_1300_1311.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1300_1311.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1300_1311.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1300_1311.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1300_1311.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1300_1311.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1300_1311.G(quantity = "ThermalConductance", unit = "W/K") = 1.85716590698239e-05 "Constant thermal conductance of material"; Real TC_1301_1312.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1301_1312.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1301_1312.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1301_1312.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1301_1312.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1301_1312.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1301_1312.G(quantity = "ThermalConductance", unit = "W/K") = 7.42847421978907e-06 "Constant thermal conductance of material"; Real TC_1301_1463.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1301_1463.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1301_1463.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1301_1463.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1301_1463.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1301_1463.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1301_1463.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363995496097255 "Constant thermal conductance of material"; Real TC_1302_1303.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1302_1303.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1302_1303.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1302_1303.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1302_1303.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1302_1303.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1302_1303.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000216794726e-05 "Constant thermal conductance of material"; Real TC_1302_1313.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1302_1313.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1302_1313.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1302_1313.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1302_1313.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1302_1313.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1302_1313.G(quantity = "ThermalConductance", unit = "W/K") = 7.42853719899379e-06 "Constant thermal conductance of material"; Real TC_1302_1464.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1302_1464.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1302_1464.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1302_1464.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1302_1464.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1302_1464.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1302_1464.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363996838813867 "Constant thermal conductance of material"; Real TC_1303_1304.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1303_1304.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1303_1304.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1303_1304.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1303_1304.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1303_1304.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1303_1304.G(quantity = "ThermalConductance", unit = "W/K") = 3.64000060362072e-05 "Constant thermal conductance of material"; Real TC_1303_1314.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1303_1314.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1303_1314.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1303_1314.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1303_1314.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1303_1314.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1303_1314.G(quantity = "ThermalConductance", unit = "W/K") = 1.8572344840596e-05 "Constant thermal conductance of material"; Real TC_1303_1465.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1303_1465.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1303_1465.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1303_1465.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1303_1465.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1303_1465.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1303_1465.G(quantity = "ThermalConductance", unit = "W/K") = 0.000910003103538223 "Constant thermal conductance of material"; Real TC_1304_1305.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1304_1305.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1304_1305.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1304_1305.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1304_1305.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1304_1305.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1304_1305.G(quantity = "ThermalConductance", unit = "W/K") = 3.64003544610803e-05 "Constant thermal conductance of material"; Real TC_1304_1315.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1304_1315.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1304_1315.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1304_1315.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1304_1315.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1304_1315.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1304_1315.G(quantity = "ThermalConductance", unit = "W/K") = 1.85744400527024e-05 "Constant thermal conductance of material"; Real TC_1304_1501.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1304_1501.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1304_1501.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1304_1501.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1304_1501.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1304_1501.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1304_1501.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181059375563978 "Constant thermal conductance of material"; Real TC_1305_1306.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1305_1306.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1305_1306.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1305_1306.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1305_1306.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1305_1306.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1305_1306.G(quantity = "ThermalConductance", unit = "W/K") = 3.64002122203556e-05 "Constant thermal conductance of material"; Real TC_1305_1316.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1305_1316.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1305_1316.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1305_1316.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1305_1316.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1305_1316.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1305_1316.G(quantity = "ThermalConductance", unit = "W/K") = 1.85713121434379e-05 "Constant thermal conductance of material"; Real TC_1305_1502.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1305_1502.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1305_1502.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1305_1502.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1305_1502.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1305_1502.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1305_1502.G(quantity = "ThermalConductance", unit = "W/K") = 0.0018105866011578 "Constant thermal conductance of material"; Real TC_1306_1307.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1306_1307.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1306_1307.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1306_1307.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1306_1307.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1306_1307.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1306_1307.G(quantity = "ThermalConductance", unit = "W/K") = 3.63943710314054e-05 "Constant thermal conductance of material"; Real TC_1306_1317.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1306_1317.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1306_1317.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1306_1317.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1306_1317.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1306_1317.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1306_1317.G(quantity = "ThermalConductance", unit = "W/K") = 1.85744016649306e-05 "Constant thermal conductance of material"; Real TC_1306_1503.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1306_1503.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1306_1503.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1306_1503.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1306_1503.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1306_1503.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1306_1503.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181057982653851 "Constant thermal conductance of material"; Real TC_1307_1308.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1307_1308.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1307_1308.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1307_1308.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1307_1308.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1307_1308.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1307_1308.G(quantity = "ThermalConductance", unit = "W/K") = 3.64002530816076e-05 "Constant thermal conductance of material"; Real TC_1307_1318.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1307_1318.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1307_1318.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1307_1318.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1307_1318.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1307_1318.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1307_1318.G(quantity = "ThermalConductance", unit = "W/K") = 1.85695089176629e-05 "Constant thermal conductance of material"; Real TC_1307_1504.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1307_1504.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1307_1504.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1307_1504.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1307_1504.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1307_1504.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1307_1504.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181058886015957 "Constant thermal conductance of material"; Real TC_1308_1309.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1308_1309.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1308_1309.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1308_1309.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1308_1309.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1308_1309.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1308_1309.G(quantity = "ThermalConductance", unit = "W/K") = 3.64012195121948e-05 "Constant thermal conductance of material"; Real TC_1308_1319.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1308_1319.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1308_1319.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1308_1319.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1308_1319.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1308_1319.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1308_1319.G(quantity = "ThermalConductance", unit = "W/K") = 1.85709844559588e-05 "Constant thermal conductance of material"; Real TC_1309_1310.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1309_1310.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1309_1310.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1309_1310.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1309_1310.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1309_1310.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1309_1310.G(quantity = "ThermalConductance", unit = "W/K") = 3.63984822175059e-05 "Constant thermal conductance of material"; Real TC_1309_1320.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1309_1320.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1309_1320.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1309_1320.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1309_1320.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1309_1320.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1309_1320.G(quantity = "ThermalConductance", unit = "W/K") = 1.8571868673532e-05 "Constant thermal conductance of material"; Real TC_1310_1311.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1310_1311.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1310_1311.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1310_1311.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1310_1311.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1310_1311.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1310_1311.G(quantity = "ThermalConductance", unit = "W/K") = 3.6399023234448e-05 "Constant thermal conductance of material"; Real TC_1310_1321.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1310_1321.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1310_1321.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1310_1321.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1310_1321.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1310_1321.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1310_1321.G(quantity = "ThermalConductance", unit = "W/K") = 1.857097224995e-05 "Constant thermal conductance of material"; Real TC_1311_1312.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1311_1312.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1311_1312.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1311_1312.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1311_1312.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1311_1312.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1311_1312.G(quantity = "ThermalConductance", unit = "W/K") = 5.20003723354743e-05 "Constant thermal conductance of material"; Real TC_1311_1322.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1311_1322.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1311_1322.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1311_1322.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1311_1322.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1311_1322.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1311_1322.G(quantity = "ThermalConductance", unit = "W/K") = 1.85716485123743e-05 "Constant thermal conductance of material"; Real TC_1312_1323.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1312_1323.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1312_1323.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1312_1323.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1312_1323.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1312_1323.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1312_1323.G(quantity = "ThermalConductance", unit = "W/K") = 7.42859657615636e-06 "Constant thermal conductance of material"; Real TC_1312_1414.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1312_1414.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1312_1414.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1312_1414.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1312_1414.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1312_1414.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1312_1414.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363997107307756 "Constant thermal conductance of material"; Real TC_1313_1314.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1313_1314.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1313_1314.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1313_1314.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1313_1314.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1313_1314.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1313_1314.G(quantity = "ThermalConductance", unit = "W/K") = 5.20003768143247e-05 "Constant thermal conductance of material"; Real TC_1313_1324.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1313_1324.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1313_1324.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1313_1324.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1313_1324.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1313_1324.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1313_1324.G(quantity = "ThermalConductance", unit = "W/K") = 4.95217624932814e-06 "Constant thermal conductance of material"; Real TC_1313_1415.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1313_1415.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1313_1415.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1313_1415.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1313_1415.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1313_1415.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1313_1415.G(quantity = "ThermalConductance", unit = "W/K") = 0.00036399816636106 "Constant thermal conductance of material"; Real TC_1314_1315.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1314_1315.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1314_1315.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1314_1315.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1314_1315.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1314_1315.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1314_1315.G(quantity = "ThermalConductance", unit = "W/K") = 3.63992736576835e-05 "Constant thermal conductance of material"; Real TC_1314_1325.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1314_1325.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1314_1325.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1314_1325.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1314_1325.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1314_1325.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1314_1325.G(quantity = "ThermalConductance", unit = "W/K") = 1.23811266883854e-05 "Constant thermal conductance of material"; Real TC_1314_1416.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1314_1416.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1314_1416.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1314_1416.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1314_1416.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1314_1416.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1314_1416.G(quantity = "ThermalConductance", unit = "W/K") = 0.000909992466058825 "Constant thermal conductance of material"; Real TC_1315_1316.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1315_1316.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1315_1316.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1315_1316.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1315_1316.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1315_1316.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1315_1316.G(quantity = "ThermalConductance", unit = "W/K") = 3.63990302338845e-05 "Constant thermal conductance of material"; Real TC_1315_1326.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1315_1326.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1315_1326.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1315_1326.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1315_1326.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1315_1326.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1315_1326.G(quantity = "ThermalConductance", unit = "W/K") = 1.23812178332058e-05 "Constant thermal conductance of material"; Real TC_1315_1505.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1315_1505.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1315_1505.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1315_1505.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1315_1505.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1315_1505.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1315_1505.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181057441010137 "Constant thermal conductance of material"; Real TC_1316_1317.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1316_1317.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1316_1317.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1316_1317.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1316_1317.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1316_1317.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1316_1317.G(quantity = "ThermalConductance", unit = "W/K") = 3.6402564313306e-05 "Constant thermal conductance of material"; Real TC_1316_1327.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1316_1327.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1316_1327.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1316_1327.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1316_1327.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1316_1327.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1316_1327.G(quantity = "ThermalConductance", unit = "W/K") = 1.23812096049847e-05 "Constant thermal conductance of material"; Real TC_1316_1506.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1316_1506.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1316_1506.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1316_1506.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1316_1506.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1316_1506.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1316_1506.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181058700177602 "Constant thermal conductance of material"; Real TC_1317_1318.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1317_1318.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1317_1318.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1317_1318.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1317_1318.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1317_1318.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1317_1318.G(quantity = "ThermalConductance", unit = "W/K") = 3.64073965365426e-05 "Constant thermal conductance of material"; Real TC_1317_1328.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1317_1328.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1317_1328.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1317_1328.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1317_1328.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1317_1328.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1317_1328.G(quantity = "ThermalConductance", unit = "W/K") = 1.23812950086528e-05 "Constant thermal conductance of material"; Real TC_1317_1507.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1317_1507.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1317_1507.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1317_1507.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1317_1507.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1317_1507.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1317_1507.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181059421774208 "Constant thermal conductance of material"; Real TC_1318_1319.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1318_1319.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1318_1319.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1318_1319.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1318_1319.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1318_1319.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1318_1319.G(quantity = "ThermalConductance", unit = "W/K") = 3.63999662455395e-05 "Constant thermal conductance of material"; Real TC_1318_1329.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1318_1329.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1318_1329.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1318_1329.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1318_1329.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1318_1329.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1318_1329.G(quantity = "ThermalConductance", unit = "W/K") = 1.23808427666143e-05 "Constant thermal conductance of material"; Real TC_1318_1508.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1318_1508.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1318_1508.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1318_1508.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1318_1508.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1318_1508.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1318_1508.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181058733530626 "Constant thermal conductance of material"; Real TC_1319_1320.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1319_1320.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1319_1320.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1319_1320.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1319_1320.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1319_1320.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1319_1320.G(quantity = "ThermalConductance", unit = "W/K") = 3.63985205732788e-05 "Constant thermal conductance of material"; Real TC_1319_1330.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1319_1330.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1319_1330.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1319_1330.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1319_1330.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1319_1330.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1319_1330.G(quantity = "ThermalConductance", unit = "W/K") = 1.23812764670297e-05 "Constant thermal conductance of material"; Real TC_1320_1321.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1320_1321.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1320_1321.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1320_1321.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1320_1321.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1320_1321.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1320_1321.G(quantity = "ThermalConductance", unit = "W/K") = 3.64010282776343e-05 "Constant thermal conductance of material"; Real TC_1320_1331.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1320_1331.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1320_1331.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1320_1331.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1320_1331.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1320_1331.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1320_1331.G(quantity = "ThermalConductance", unit = "W/K") = 1.2380679648721e-05 "Constant thermal conductance of material"; Real TC_1321_1322.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1321_1322.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1321_1322.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1321_1322.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1321_1322.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1321_1322.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1321_1322.G(quantity = "ThermalConductance", unit = "W/K") = 3.64007421150281e-05 "Constant thermal conductance of material"; Real TC_1321_1332.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1321_1332.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1321_1332.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1321_1332.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1321_1332.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1321_1332.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1321_1332.G(quantity = "ThermalConductance", unit = "W/K") = 1.23809148264985e-05 "Constant thermal conductance of material"; Real TC_1322_1323.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1322_1323.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1322_1323.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1322_1323.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1322_1323.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1322_1323.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1322_1323.G(quantity = "ThermalConductance", unit = "W/K") = 5.19999851516113e-05 "Constant thermal conductance of material"; Real TC_1322_1333.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1322_1333.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1322_1333.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1322_1333.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1322_1333.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1322_1333.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1322_1333.G(quantity = "ThermalConductance", unit = "W/K") = 1.23808694305733e-05 "Constant thermal conductance of material"; Real TC_1323_1334.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1323_1334.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1323_1334.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1323_1334.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1323_1334.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1323_1334.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1323_1334.G(quantity = "ThermalConductance", unit = "W/K") = 4.95235208943661e-06 "Constant thermal conductance of material"; Real TC_1323_1417.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1323_1417.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1323_1417.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1323_1417.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1323_1417.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1323_1417.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1323_1417.G(quantity = "ThermalConductance", unit = "W/K") = 0.000363996743708631 "Constant thermal conductance of material"; Real TC_1324_1325.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1324_1325.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1324_1325.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1324_1325.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1324_1325.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1324_1325.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1324_1325.G(quantity = "ThermalConductance", unit = "W/K") = 0.000104001689854508 "Constant thermal conductance of material"; Real TC_1324_1335.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1324_1335.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1324_1335.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1324_1335.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1324_1335.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1324_1335.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1324_1335.G(quantity = "ThermalConductance", unit = "W/K") = 5.47345777071749e-06 "Constant thermal conductance of material"; Real TC_1324_1418.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1324_1418.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1324_1418.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1324_1418.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1324_1418.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1324_1418.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1324_1418.G(quantity = "ThermalConductance", unit = "W/K") = 0.000728025427437815 "Constant thermal conductance of material"; Real TC_1325_1326.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1325_1326.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1325_1326.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1325_1326.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1325_1326.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1325_1326.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1325_1326.G(quantity = "ThermalConductance", unit = "W/K") = 7.28009747410845e-05 "Constant thermal conductance of material"; Real TC_1325_1336.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1325_1336.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1325_1336.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1325_1336.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1325_1336.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1325_1336.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1325_1336.G(quantity = "ThermalConductance", unit = "W/K") = 1.36841311153861e-05 "Constant thermal conductance of material"; Real TC_1325_1419.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1325_1419.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1325_1419.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1325_1419.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1325_1419.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1325_1419.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1325_1419.G(quantity = "ThermalConductance", unit = "W/K") = 0.00181999788246904 "Constant thermal conductance of material"; Real TC_1326_1327.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1326_1327.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1326_1327.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1326_1327.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1326_1327.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1326_1327.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1326_1327.G(quantity = "ThermalConductance", unit = "W/K") = 7.28029314949362e-05 "Constant thermal conductance of material"; Real TC_1326_1337.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1326_1337.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1326_1337.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1326_1337.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1326_1337.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1326_1337.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1326_1337.G(quantity = "ThermalConductance", unit = "W/K") = 1.36844000360066e-05 "Constant thermal conductance of material"; Real TC_1327_1328.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1327_1328.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1327_1328.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1327_1328.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1327_1328.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1327_1328.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1327_1328.G(quantity = "ThermalConductance", unit = "W/K") = 7.28000393817106e-05 "Constant thermal conductance of material"; Real TC_1327_1338.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1327_1338.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1327_1338.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1327_1338.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1327_1338.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1327_1338.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1327_1338.G(quantity = "ThermalConductance", unit = "W/K") = 1.36844570578349e-05 "Constant thermal conductance of material"; Real TC_1328_1329.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1328_1329.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1328_1329.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1328_1329.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1328_1329.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1328_1329.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1328_1329.G(quantity = "ThermalConductance", unit = "W/K") = 7.28037198258782e-05 "Constant thermal conductance of material"; Real TC_1328_1339.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1328_1339.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1328_1339.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1328_1339.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1328_1339.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1328_1339.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1328_1339.G(quantity = "ThermalConductance", unit = "W/K") = 1.36843770480689e-05 "Constant thermal conductance of material"; Real TC_1329_1330.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1329_1330.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1329_1330.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1329_1330.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1329_1330.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1329_1330.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1329_1330.G(quantity = "ThermalConductance", unit = "W/K") = 7.28006789524762e-05 "Constant thermal conductance of material"; Real TC_1329_1340.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1329_1340.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1329_1340.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1329_1340.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1329_1340.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1329_1340.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1329_1340.G(quantity = "ThermalConductance", unit = "W/K") = 1.36841383304629e-05 "Constant thermal conductance of material"; Real TC_1330_1331.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1330_1331.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1330_1331.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1330_1331.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1330_1331.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1330_1331.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1330_1331.G(quantity = "ThermalConductance", unit = "W/K") = 7.27764326069417e-05 "Constant thermal conductance of material"; Real TC_1330_1488.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1330_1488.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1330_1488.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1330_1488.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1330_1488.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1330_1488.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1330_1488.G(quantity = "ThermalConductance", unit = "W/K") = 1.84002767726494e-05 "Constant thermal conductance of material"; Real TC_1331_1332.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1331_1332.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1331_1332.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1331_1332.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1331_1332.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1331_1332.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1331_1332.G(quantity = "ThermalConductance", unit = "W/K") = 7.27959183673465e-05 "Constant thermal conductance of material"; Real TC_1331_1489.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1331_1489.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1331_1489.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1331_1489.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1331_1489.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1331_1489.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1331_1489.G(quantity = "ThermalConductance", unit = "W/K") = 1.840072472416e-05 "Constant thermal conductance of material"; Real TC_1332_1333.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1332_1333.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1332_1333.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1332_1333.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1332_1333.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1332_1333.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1332_1333.G(quantity = "ThermalConductance", unit = "W/K") = 7.27981965095379e-05 "Constant thermal conductance of material"; Real TC_1332_1490.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1332_1490.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1332_1490.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1332_1490.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1332_1490.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1332_1490.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1332_1490.G(quantity = "ThermalConductance", unit = "W/K") = 1.84008146730178e-05 "Constant thermal conductance of material"; Real TC_1333_1334.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1333_1334.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1333_1334.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1333_1334.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1333_1334.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1333_1334.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1333_1334.G(quantity = "ThermalConductance", unit = "W/K") = 0.000103999265138555 "Constant thermal conductance of material"; Real TC_1333_1341.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1333_1341.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1333_1341.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1333_1341.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1333_1341.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1333_1341.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1333_1341.G(quantity = "ThermalConductance", unit = "W/K") = 1.36838529832042e-05 "Constant thermal conductance of material"; Real TC_1334_1342.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1334_1342.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1334_1342.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1334_1342.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1334_1342.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1334_1342.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1334_1342.G(quantity = "ThermalConductance", unit = "W/K") = 5.47381004129532e-06 "Constant thermal conductance of material"; Real TC_1334_1420.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1334_1420.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1334_1420.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1334_1420.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1334_1420.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1334_1420.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1334_1420.G(quantity = "ThermalConductance", unit = "W/K") = 0.000728000243891284 "Constant thermal conductance of material"; Real TC_1335_1336.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1335_1336.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1335_1336.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1335_1336.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1335_1336.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1335_1336.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1335_1336.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430918650504e-05 "Constant thermal conductance of material"; Real TC_1335_1343.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1335_1343.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1335_1343.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1335_1343.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1335_1343.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1335_1343.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1335_1343.G(quantity = "ThermalConductance", unit = "W/K") = 1.0400355871886e-05 "Constant thermal conductance of material"; Real TC_1335_1421.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1335_1421.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1335_1421.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1335_1421.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1335_1421.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1335_1421.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1335_1421.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259996450754215 "Constant thermal conductance of material"; Real TC_1336_1337.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1336_1337.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1336_1337.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1336_1337.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1336_1337.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1336_1337.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1336_1337.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997396456661e-05 "Constant thermal conductance of material"; Real TC_1336_1344.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1336_1344.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1336_1344.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1336_1344.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1336_1344.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1336_1344.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1336_1344.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001773757261e-05 "Constant thermal conductance of material"; Real TC_1336_1422.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1336_1422.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1336_1422.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1336_1422.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1336_1422.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1336_1422.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1336_1422.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649993471577623 "Constant thermal conductance of material"; Real TC_1337_1338.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1337_1338.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1337_1338.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1337_1338.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1337_1338.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1337_1338.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1337_1338.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998951067293e-05 "Constant thermal conductance of material"; Real TC_1337_1345.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1337_1345.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1337_1345.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1337_1345.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1337_1345.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1337_1345.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1337_1345.G(quantity = "ThermalConductance", unit = "W/K") = 2.59996073234182e-05 "Constant thermal conductance of material"; Real TC_1338_1339.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1338_1339.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1338_1339.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1338_1339.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1338_1339.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1338_1339.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1338_1339.G(quantity = "ThermalConductance", unit = "W/K") = 2.60006625075918e-05 "Constant thermal conductance of material"; Real TC_1338_1346.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1338_1346.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1338_1346.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1338_1346.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1338_1346.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1338_1346.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1338_1346.G(quantity = "ThermalConductance", unit = "W/K") = 2.59994279448922e-05 "Constant thermal conductance of material"; Real TC_1339_1340.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1339_1340.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1339_1340.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1339_1340.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1339_1340.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1339_1340.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1339_1340.G(quantity = "ThermalConductance", unit = "W/K") = 2.5999682237051e-05 "Constant thermal conductance of material"; Real TC_1339_1347.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1339_1347.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1339_1347.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1339_1347.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1339_1347.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1339_1347.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1339_1347.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997226203134e-05 "Constant thermal conductance of material"; Real TC_1340_1348.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1340_1348.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1340_1348.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1340_1348.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1340_1348.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1340_1348.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1340_1348.G(quantity = "ThermalConductance", unit = "W/K") = 2.60005114435491e-05 "Constant thermal conductance of material"; Real TC_1340_1488.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1340_1488.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1340_1488.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1340_1488.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1340_1488.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1340_1488.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1340_1488.G(quantity = "ThermalConductance", unit = "W/K") = 5.0682190744399e-05 "Constant thermal conductance of material"; Real TC_1341_1342.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1341_1342.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1341_1342.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1341_1342.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1341_1342.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1341_1342.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1341_1342.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430202081843e-05 "Constant thermal conductance of material"; Real TC_1341_1349.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1341_1349.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1341_1349.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1341_1349.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1341_1349.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1341_1349.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1341_1349.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004133085345e-05 "Constant thermal conductance of material"; Real TC_1341_1490.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1341_1490.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1341_1490.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1341_1490.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1341_1490.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1341_1490.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1341_1490.G(quantity = "ThermalConductance", unit = "W/K") = 5.06819625574529e-05 "Constant thermal conductance of material"; Real TC_1342_1350.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1342_1350.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1342_1350.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1342_1350.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1342_1350.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1342_1350.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1342_1350.G(quantity = "ThermalConductance", unit = "W/K") = 1.04000269832708e-05 "Constant thermal conductance of material"; Real TC_1342_1423.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1342_1423.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1342_1423.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1342_1423.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1342_1423.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1342_1423.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1342_1423.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259998922674999 "Constant thermal conductance of material"; Real TC_1343_1344.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1343_1344.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1343_1344.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1343_1344.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1343_1344.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1343_1344.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1343_1344.G(quantity = "ThermalConductance", unit = "W/K") = 3.71427511990066e-05 "Constant thermal conductance of material"; Real TC_1343_1351.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1343_1351.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1343_1351.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1343_1351.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1343_1351.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1343_1351.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1343_1351.G(quantity = "ThermalConductance", unit = "W/K") = 1.03999742367642e-05 "Constant thermal conductance of material"; Real TC_1343_1424.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1343_1424.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1343_1424.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1343_1424.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1343_1424.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1343_1424.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1343_1424.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001957056587 "Constant thermal conductance of material"; Real TC_1344_1345.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1344_1345.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1344_1345.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1344_1345.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1344_1345.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1344_1345.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1344_1345.G(quantity = "ThermalConductance", unit = "W/K") = 2.59989537983868e-05 "Constant thermal conductance of material"; Real TC_1344_1352.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1344_1352.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1344_1352.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1344_1352.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1344_1352.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1344_1352.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1344_1352.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997316156738e-05 "Constant thermal conductance of material"; Real TC_1344_1425.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1344_1425.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1344_1425.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1344_1425.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1344_1425.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1344_1425.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1344_1425.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650002439143373 "Constant thermal conductance of material"; Real TC_1345_1346.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1345_1346.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1345_1346.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1345_1346.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1345_1346.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1345_1346.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1345_1346.G(quantity = "ThermalConductance", unit = "W/K") = 2.5999694982462e-05 "Constant thermal conductance of material"; Real TC_1345_1353.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1345_1353.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1345_1353.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1345_1353.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1345_1353.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1345_1353.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1345_1353.G(quantity = "ThermalConductance", unit = "W/K") = 2.60005907546891e-05 "Constant thermal conductance of material"; Real TC_1346_1347.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1346_1347.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1346_1347.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1346_1347.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1346_1347.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1346_1347.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1346_1347.G(quantity = "ThermalConductance", unit = "W/K") = 2.60009591303888e-05 "Constant thermal conductance of material"; Real TC_1346_1354.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1346_1354.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1346_1354.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1346_1354.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1346_1354.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1346_1354.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1346_1354.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999999999996e-05 "Constant thermal conductance of material"; Real TC_1347_1348.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1347_1348.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1347_1348.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1347_1348.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1347_1348.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1347_1348.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1347_1348.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002402258119e-05 "Constant thermal conductance of material"; Real TC_1347_1355.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1347_1355.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1347_1355.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1347_1355.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1347_1355.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1347_1355.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1347_1355.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998213807263e-05 "Constant thermal conductance of material"; Real TC_1348_1356.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1348_1356.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1348_1356.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1348_1356.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1348_1356.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1348_1356.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1348_1356.G(quantity = "ThermalConductance", unit = "W/K") = 2.59989610389617e-05 "Constant thermal conductance of material"; Real TC_1348_1491.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1348_1491.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1348_1491.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1348_1491.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1348_1491.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1348_1491.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1348_1491.G(quantity = "ThermalConductance", unit = "W/K") = 5.06820777632997e-05 "Constant thermal conductance of material"; Real TC_1349_1350.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1349_1350.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1349_1350.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1349_1350.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1349_1350.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1349_1350.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1349_1350.G(quantity = "ThermalConductance", unit = "W/K") = 3.71429616482592e-05 "Constant thermal conductance of material"; Real TC_1349_1357.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1349_1357.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1349_1357.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1349_1357.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1349_1357.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1349_1357.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1349_1357.G(quantity = "ThermalConductance", unit = "W/K") = 2.5956028368796e-05 "Constant thermal conductance of material"; Real TC_1349_1493.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1349_1493.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1349_1493.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1349_1493.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1349_1493.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1349_1493.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1349_1493.G(quantity = "ThermalConductance", unit = "W/K") = 5.06821440468086e-05 "Constant thermal conductance of material"; Real TC_1350_1358.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1350_1358.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1350_1358.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1350_1358.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1350_1358.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1350_1358.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1350_1358.G(quantity = "ThermalConductance", unit = "W/K") = 1.03840909090648e-05 "Constant thermal conductance of material"; Real TC_1350_1426.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1350_1426.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1350_1426.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1350_1426.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1350_1426.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1350_1426.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1350_1426.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260006074291221 "Constant thermal conductance of material"; Real TC_1351_1352.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1351_1352.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1351_1352.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1351_1352.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1351_1352.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1351_1352.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1351_1352.G(quantity = "ThermalConductance", unit = "W/K") = 3.71432219423584e-05 "Constant thermal conductance of material"; Real TC_1351_1359.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1351_1359.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1351_1359.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1351_1359.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1351_1359.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1351_1359.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1351_1359.G(quantity = "ThermalConductance", unit = "W/K") = 1.0399776738994e-05 "Constant thermal conductance of material"; Real TC_1351_1427.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1351_1427.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1351_1427.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1351_1427.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1351_1427.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1351_1427.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1351_1427.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259998772947585 "Constant thermal conductance of material"; Real TC_1352_1353.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1352_1353.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1352_1353.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1352_1353.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1352_1353.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1352_1353.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1352_1353.G(quantity = "ThermalConductance", unit = "W/K") = 2.60006958410767e-05 "Constant thermal conductance of material"; Real TC_1352_1360.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1352_1360.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1352_1360.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1352_1360.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1352_1360.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1352_1360.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1352_1360.G(quantity = "ThermalConductance", unit = "W/K") = 2.6e-05 "Constant thermal conductance of material"; Real TC_1352_1428.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1352_1428.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1352_1428.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1352_1428.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1352_1428.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1352_1428.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1352_1428.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649995991096416 "Constant thermal conductance of material"; Real TC_1353_1354.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1353_1354.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1353_1354.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1353_1354.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1353_1354.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1353_1354.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1353_1354.G(quantity = "ThermalConductance", unit = "W/K") = 2.59988619904821e-05 "Constant thermal conductance of material"; Real TC_1353_1361.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1353_1361.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1353_1361.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1353_1361.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1353_1361.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1353_1361.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1353_1361.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998580683097e-05 "Constant thermal conductance of material"; Real TC_1354_1355.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1354_1355.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1354_1355.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1354_1355.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1354_1355.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1354_1355.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1354_1355.G(quantity = "ThermalConductance", unit = "W/K") = 2.60009711431744e-05 "Constant thermal conductance of material"; Real TC_1354_1362.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1354_1362.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1354_1362.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1354_1362.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1354_1362.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1354_1362.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1354_1362.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001332656754e-05 "Constant thermal conductance of material"; Real TC_1355_1356.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1355_1356.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1355_1356.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1355_1356.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1355_1356.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1355_1356.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1355_1356.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000974041791e-05 "Constant thermal conductance of material"; Real TC_1355_1363.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1355_1363.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1355_1363.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1355_1363.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1355_1363.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1355_1363.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1355_1363.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997156263331e-05 "Constant thermal conductance of material"; Real TC_1356_1364.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1356_1364.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1356_1364.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1356_1364.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1356_1364.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1356_1364.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1356_1364.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997136311572e-05 "Constant thermal conductance of material"; Real TC_1356_1494.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1356_1494.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1356_1494.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1356_1494.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1356_1494.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1356_1494.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1356_1494.G(quantity = "ThermalConductance", unit = "W/K") = 5.06821592997958e-05 "Constant thermal conductance of material"; Real TC_1357_1358.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1357_1358.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1357_1358.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1357_1358.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1357_1358.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1357_1358.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1357_1358.G(quantity = "ThermalConductance", unit = "W/K") = 3.71429990216586e-05 "Constant thermal conductance of material"; Real TC_1357_1368.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1357_1368.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1357_1368.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1357_1368.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1357_1368.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1357_1368.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1357_1368.G(quantity = "ThermalConductance", unit = "W/K") = 2.60008722197997e-05 "Constant thermal conductance of material"; Real TC_1357_1496.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1357_1496.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1357_1496.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1357_1496.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1357_1496.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1357_1496.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1357_1496.G(quantity = "ThermalConductance", unit = "W/K") = 5.0682384847557e-05 "Constant thermal conductance of material"; Real TC_1358_1369.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1358_1369.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1358_1369.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1358_1369.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1358_1369.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1358_1369.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1358_1369.G(quantity = "ThermalConductance", unit = "W/K") = 1.03996003996002e-05 "Constant thermal conductance of material"; Real TC_1358_1429.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1358_1429.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1358_1429.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1358_1429.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1358_1429.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1358_1429.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1358_1429.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001854034513 "Constant thermal conductance of material"; Real TC_1359_1360.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1359_1360.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1359_1360.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1359_1360.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1359_1360.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1359_1360.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1359_1360.G(quantity = "ThermalConductance", unit = "W/K") = 3.71426747727275e-05 "Constant thermal conductance of material"; Real TC_1359_1370.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1359_1370.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1359_1370.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1359_1370.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1359_1370.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1359_1370.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1359_1370.G(quantity = "ThermalConductance", unit = "W/K") = 1.04008373732935e-05 "Constant thermal conductance of material"; Real TC_1359_1430.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1359_1430.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1359_1430.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1359_1430.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1359_1430.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1359_1430.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1359_1430.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260002111960296 "Constant thermal conductance of material"; Real TC_1360_1361.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1360_1361.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1360_1361.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1360_1361.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1360_1361.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1360_1361.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1360_1361.G(quantity = "ThermalConductance", unit = "W/K") = 2.60007769946165e-05 "Constant thermal conductance of material"; Real TC_1360_1371.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1360_1371.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1360_1371.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1360_1371.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1360_1371.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1360_1371.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1360_1371.G(quantity = "ThermalConductance", unit = "W/K") = 2.59972144846777e-05 "Constant thermal conductance of material"; Real TC_1360_1431.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1360_1431.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1360_1431.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1360_1431.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1360_1431.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1360_1431.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1360_1431.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649991890536993 "Constant thermal conductance of material"; Real TC_1361_1362.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1361_1362.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1361_1362.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1361_1362.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1361_1362.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1361_1362.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1361_1362.G(quantity = "ThermalConductance", unit = "W/K") = 2.60006995860787e-05 "Constant thermal conductance of material"; Real TC_1361_1372.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1361_1372.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1361_1372.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1361_1372.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1361_1372.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1361_1372.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1361_1372.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998159565666e-05 "Constant thermal conductance of material"; Real TC_1361_1518.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1361_1518.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1361_1518.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1361_1518.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1361_1518.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1361_1518.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1361_1518.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129327323848143 "Constant thermal conductance of material"; Real TC_1362_1363.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1362_1363.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1362_1363.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1362_1363.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1362_1363.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1362_1363.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1362_1363.G(quantity = "ThermalConductance", unit = "W/K") = 2.60045286125971e-05 "Constant thermal conductance of material"; Real TC_1362_1373.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1362_1373.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1362_1373.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1362_1373.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1362_1373.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1362_1373.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1362_1373.G(quantity = "ThermalConductance", unit = "W/K") = 2.5999184339314e-05 "Constant thermal conductance of material"; Real TC_1362_1519.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1362_1519.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1362_1519.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1362_1519.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1362_1519.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1362_1519.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1362_1519.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129326298607998 "Constant thermal conductance of material"; Real TC_1363_1364.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1363_1364.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1363_1364.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1363_1364.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1363_1364.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1363_1364.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1363_1364.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001007658202e-05 "Constant thermal conductance of material"; Real TC_1363_1374.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1363_1374.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1363_1374.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1363_1374.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1363_1374.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1363_1374.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1363_1374.G(quantity = "ThermalConductance", unit = "W/K") = 2.60053165780547e-05 "Constant thermal conductance of material"; Real TC_1363_1520.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1363_1520.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1363_1520.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1363_1520.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1363_1520.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1363_1520.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1363_1520.G(quantity = "ThermalConductance", unit = "W/K") = 0.0012932736304399 "Constant thermal conductance of material"; Real TC_1364_1365.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1364_1365.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1364_1365.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1364_1365.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1364_1365.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1364_1365.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1364_1365.G(quantity = "ThermalConductance", unit = "W/K") = 2.60008347245414e-05 "Constant thermal conductance of material"; Real TC_1364_1375.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1364_1375.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1364_1375.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1364_1375.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1364_1375.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1364_1375.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1364_1375.G(quantity = "ThermalConductance", unit = "W/K") = 2.60013446508117e-05 "Constant thermal conductance of material"; Real TC_1365_1366.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1365_1366.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1365_1366.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1365_1366.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1365_1366.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1365_1366.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1365_1366.G(quantity = "ThermalConductance", unit = "W/K") = 2.599564744287e-05 "Constant thermal conductance of material"; Real TC_1365_1376.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1365_1376.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1365_1376.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1365_1376.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1365_1376.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1365_1376.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1365_1376.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001305866609e-05 "Constant thermal conductance of material"; Real TC_1365_1494.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1365_1494.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1365_1494.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1365_1494.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1365_1494.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1365_1494.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1365_1494.G(quantity = "ThermalConductance", unit = "W/K") = 5.06820700052675e-05 "Constant thermal conductance of material"; Real TC_1366_1367.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1366_1367.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1366_1367.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1366_1367.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1366_1367.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1366_1367.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1366_1367.G(quantity = "ThermalConductance", unit = "W/K") = 2.59968847352012e-05 "Constant thermal conductance of material"; Real TC_1366_1377.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1366_1377.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1366_1377.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1366_1377.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1366_1377.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1366_1377.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1366_1377.G(quantity = "ThermalConductance", unit = "W/K") = 2.59993581858049e-05 "Constant thermal conductance of material"; Real TC_1366_1495.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1366_1495.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1366_1495.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1366_1495.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1366_1495.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1366_1495.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1366_1495.G(quantity = "ThermalConductance", unit = "W/K") = 5.0682556112925e-05 "Constant thermal conductance of material"; Real TC_1367_1368.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1367_1368.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1367_1368.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1367_1368.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1367_1368.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1367_1368.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1367_1368.G(quantity = "ThermalConductance", unit = "W/K") = 2.60012822446826e-05 "Constant thermal conductance of material"; Real TC_1367_1378.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1367_1378.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1367_1378.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1367_1378.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1367_1378.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1367_1378.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1367_1378.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001649983503e-05 "Constant thermal conductance of material"; Real TC_1367_1496.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1367_1496.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1367_1496.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1367_1496.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1367_1496.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1367_1496.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1367_1496.G(quantity = "ThermalConductance", unit = "W/K") = 5.06826266265534e-05 "Constant thermal conductance of material"; Real TC_1368_1369.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1368_1369.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1368_1369.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1368_1369.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1368_1369.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1368_1369.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1368_1369.G(quantity = "ThermalConductance", unit = "W/K") = 3.71431359122685e-05 "Constant thermal conductance of material"; Real TC_1368_1379.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1368_1379.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1368_1379.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1368_1379.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1368_1379.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1368_1379.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1368_1379.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000795450027e-05 "Constant thermal conductance of material"; Real TC_1369_1380.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1369_1380.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1369_1380.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1369_1380.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1369_1380.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1369_1380.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1369_1380.G(quantity = "ThermalConductance", unit = "W/K") = 1.03998456735996e-05 "Constant thermal conductance of material"; Real TC_1369_1432.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1369_1432.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1369_1432.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1369_1432.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1369_1432.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1369_1432.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1369_1432.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001597061408 "Constant thermal conductance of material"; Real TC_1370_1371.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1370_1371.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1370_1371.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1370_1371.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1370_1371.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1370_1371.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1370_1371.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430583215907e-05 "Constant thermal conductance of material"; Real TC_1370_1381.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1370_1381.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1370_1381.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1370_1381.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1370_1381.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1370_1381.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1370_1381.G(quantity = "ThermalConductance", unit = "W/K") = 1.03997158044313e-05 "Constant thermal conductance of material"; Real TC_1370_1433.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1370_1433.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1370_1433.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1370_1433.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1370_1433.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1370_1433.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1370_1433.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260001169157621 "Constant thermal conductance of material"; Real TC_1371_1372.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1371_1372.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1371_1372.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1371_1372.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1371_1372.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1371_1372.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1371_1372.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999249235158e-05 "Constant thermal conductance of material"; Real TC_1371_1382.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1371_1382.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1371_1382.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1371_1382.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1371_1382.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1371_1382.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1371_1382.G(quantity = "ThermalConductance", unit = "W/K") = 2.60007204286549e-05 "Constant thermal conductance of material"; Real TC_1371_1434.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1371_1434.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1371_1434.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1371_1434.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1371_1434.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1371_1434.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1371_1434.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649990531820367 "Constant thermal conductance of material"; Real TC_1372_1373.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1372_1373.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1372_1373.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1372_1373.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1372_1373.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1372_1373.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1372_1373.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003728097422e-05 "Constant thermal conductance of material"; Real TC_1372_1383.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1372_1383.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1372_1383.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1372_1383.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1372_1383.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1372_1383.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1372_1383.G(quantity = "ThermalConductance", unit = "W/K") = 2.59991072757028e-05 "Constant thermal conductance of material"; Real TC_1372_1521.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1372_1521.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1372_1521.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1372_1521.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1372_1521.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1372_1521.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1372_1521.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129327144625874 "Constant thermal conductance of material"; Real TC_1373_1374.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1373_1374.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1373_1374.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1373_1374.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1373_1374.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1373_1374.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1373_1374.G(quantity = "ThermalConductance", unit = "W/K") = 2.59982902735561e-05 "Constant thermal conductance of material"; Real TC_1373_1384.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1373_1384.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1373_1384.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1373_1384.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1373_1384.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1373_1384.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1373_1384.G(quantity = "ThermalConductance", unit = "W/K") = 2.59989679598436e-05 "Constant thermal conductance of material"; Real TC_1373_1522.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1373_1522.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1373_1522.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1373_1522.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1373_1522.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1373_1522.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1373_1522.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129328868699784 "Constant thermal conductance of material"; Real TC_1374_1375.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1374_1375.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1374_1375.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1374_1375.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1374_1375.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1374_1375.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1374_1375.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003088873762e-05 "Constant thermal conductance of material"; Real TC_1374_1385.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1374_1385.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1374_1385.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1374_1385.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1374_1385.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1374_1385.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1374_1385.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999999999995e-05 "Constant thermal conductance of material"; Real TC_1374_1523.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1374_1523.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1374_1523.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1374_1523.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1374_1523.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1374_1523.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1374_1523.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129326731067784 "Constant thermal conductance of material"; Real TC_1375_1376.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1375_1376.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1375_1376.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1375_1376.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1375_1376.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1375_1376.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1375_1376.G(quantity = "ThermalConductance", unit = "W/K") = 2.59967417061604e-05 "Constant thermal conductance of material"; Real TC_1375_1386.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1375_1386.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1375_1386.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1375_1386.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1375_1386.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1375_1386.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1375_1386.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999032507735e-05 "Constant thermal conductance of material"; Real TC_1376_1377.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1376_1377.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1376_1377.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1376_1377.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1376_1377.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1376_1377.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1376_1377.G(quantity = "ThermalConductance", unit = "W/K") = 2.59986162361582e-05 "Constant thermal conductance of material"; Real TC_1376_1387.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1376_1387.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1376_1387.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1376_1387.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1376_1387.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1376_1387.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1376_1387.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004788889776e-05 "Constant thermal conductance of material"; Real TC_1377_1378.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1377_1378.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1377_1378.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1377_1378.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1377_1378.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1377_1378.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1377_1378.G(quantity = "ThermalConductance", unit = "W/K") = 2.60008990110894e-05 "Constant thermal conductance of material"; Real TC_1377_1388.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1377_1388.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1377_1388.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1377_1388.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1377_1388.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1377_1388.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1377_1388.G(quantity = "ThermalConductance", unit = "W/K") = 2.60005086100418e-05 "Constant thermal conductance of material"; Real TC_1378_1379.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1378_1379.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1378_1379.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1378_1379.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1378_1379.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1378_1379.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1378_1379.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003348401139e-05 "Constant thermal conductance of material"; Real TC_1378_1389.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1378_1389.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1378_1389.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1378_1389.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1378_1389.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1378_1389.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1378_1389.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002913116307e-05 "Constant thermal conductance of material"; Real TC_1379_1380.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1379_1380.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1379_1380.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1379_1380.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1379_1380.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1379_1380.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1379_1380.G(quantity = "ThermalConductance", unit = "W/K") = 3.71430499526301e-05 "Constant thermal conductance of material"; Real TC_1379_1390.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1379_1390.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1379_1390.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1379_1390.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1379_1390.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1379_1390.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1379_1390.G(quantity = "ThermalConductance", unit = "W/K") = 2.59995558352148e-05 "Constant thermal conductance of material"; Real TC_1380_1391.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1380_1391.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1380_1391.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1380_1391.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1380_1391.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1380_1391.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1380_1391.G(quantity = "ThermalConductance", unit = "W/K") = 1.0400017474371e-05 "Constant thermal conductance of material"; Real TC_1380_1435.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1380_1435.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1380_1435.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1380_1435.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1380_1435.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1380_1435.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1380_1435.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260000780548724 "Constant thermal conductance of material"; Real TC_1381_1382.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1381_1382.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1381_1382.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1381_1382.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1381_1382.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1381_1382.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1381_1382.G(quantity = "ThermalConductance", unit = "W/K") = 3.71424550263255e-05 "Constant thermal conductance of material"; Real TC_1381_1392.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1381_1392.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1381_1392.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1381_1392.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1381_1392.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1381_1392.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1381_1392.G(quantity = "ThermalConductance", unit = "W/K") = 5.19996889156768e-06 "Constant thermal conductance of material"; Real TC_1381_1436.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1381_1436.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1381_1436.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1381_1436.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1381_1436.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1381_1436.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1381_1436.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260000509093685 "Constant thermal conductance of material"; Real TC_1382_1383.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1382_1383.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1382_1383.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1382_1383.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1382_1383.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1382_1383.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1382_1383.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004852298739e-05 "Constant thermal conductance of material"; Real TC_1382_1393.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1382_1393.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1382_1393.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1382_1393.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1382_1393.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1382_1393.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1382_1393.G(quantity = "ThermalConductance", unit = "W/K") = 1.29999062274076e-05 "Constant thermal conductance of material"; Real TC_1382_1437.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1382_1437.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1382_1437.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1382_1437.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1382_1437.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1382_1437.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1382_1437.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649996851923474 "Constant thermal conductance of material"; Real TC_1383_1384.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1383_1384.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1383_1384.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1383_1384.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1383_1384.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1383_1384.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1383_1384.G(quantity = "ThermalConductance", unit = "W/K") = 2.60006693440428e-05 "Constant thermal conductance of material"; Real TC_1383_1394.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1383_1394.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1383_1394.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1383_1394.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1383_1394.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1383_1394.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1383_1394.G(quantity = "ThermalConductance", unit = "W/K") = 1.29994646420402e-05 "Constant thermal conductance of material"; Real TC_1383_1524.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1383_1524.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1383_1524.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1383_1524.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1383_1524.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1383_1524.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1383_1524.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129328518530204 "Constant thermal conductance of material"; Real TC_1384_1385.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1384_1385.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1384_1385.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1384_1385.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1384_1385.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1384_1385.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1384_1385.G(quantity = "ThermalConductance", unit = "W/K") = 2.60011483881553e-05 "Constant thermal conductance of material"; Real TC_1384_1395.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1384_1395.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1384_1395.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1384_1395.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1384_1395.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1384_1395.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1384_1395.G(quantity = "ThermalConductance", unit = "W/K") = 1.29998818870716e-05 "Constant thermal conductance of material"; Real TC_1384_1525.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1384_1525.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1384_1525.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1384_1525.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1384_1525.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1384_1525.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1384_1525.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129327477273722 "Constant thermal conductance of material"; Real TC_1385_1386.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1385_1386.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1385_1386.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1385_1386.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1385_1386.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1385_1386.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1385_1386.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003593932051e-05 "Constant thermal conductance of material"; Real TC_1385_1396.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1385_1396.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1385_1396.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1385_1396.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1385_1396.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1385_1396.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1385_1396.G(quantity = "ThermalConductance", unit = "W/K") = 1.30006285355123e-05 "Constant thermal conductance of material"; Real TC_1385_1526.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1385_1526.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1385_1526.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1385_1526.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1385_1526.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1385_1526.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1385_1526.G(quantity = "ThermalConductance", unit = "W/K") = 0.00129328168593065 "Constant thermal conductance of material"; Real TC_1386_1387.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1386_1387.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1386_1387.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1386_1387.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1386_1387.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1386_1387.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1386_1387.G(quantity = "ThermalConductance", unit = "W/K") = 2.59992817381943e-05 "Constant thermal conductance of material"; Real TC_1386_1397.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1386_1397.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1386_1397.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1386_1397.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1386_1397.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1386_1397.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1386_1397.G(quantity = "ThermalConductance", unit = "W/K") = 1.29999114203972e-05 "Constant thermal conductance of material"; Real TC_1387_1388.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1387_1388.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1387_1388.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1387_1388.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1387_1388.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1387_1388.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1387_1388.G(quantity = "ThermalConductance", unit = "W/K") = 2.60008628127697e-05 "Constant thermal conductance of material"; Real TC_1387_1398.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1387_1398.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1387_1398.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1387_1398.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1387_1398.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1387_1398.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1387_1398.G(quantity = "ThermalConductance", unit = "W/K") = 1.30000289485432e-05 "Constant thermal conductance of material"; Real TC_1388_1389.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1388_1389.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1388_1389.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1388_1389.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1388_1389.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1388_1389.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1388_1389.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000000000005e-05 "Constant thermal conductance of material"; Real TC_1388_1399.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1388_1399.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1388_1399.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1388_1399.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1388_1399.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1388_1399.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1388_1399.G(quantity = "ThermalConductance", unit = "W/K") = 1.30000309195018e-05 "Constant thermal conductance of material"; Real TC_1389_1390.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1389_1390.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1389_1390.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1389_1390.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1389_1390.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1389_1390.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1389_1390.G(quantity = "ThermalConductance", unit = "W/K") = 2.59996132089155e-05 "Constant thermal conductance of material"; Real TC_1389_1400.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1389_1400.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1389_1400.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1389_1400.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1389_1400.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1389_1400.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1389_1400.G(quantity = "ThermalConductance", unit = "W/K") = 1.30000237499494e-05 "Constant thermal conductance of material"; Real TC_1390_1391.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1390_1391.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1390_1391.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1390_1391.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1390_1391.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1390_1391.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1390_1391.G(quantity = "ThermalConductance", unit = "W/K") = 3.71428861328039e-05 "Constant thermal conductance of material"; Real TC_1390_1401.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1390_1401.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1390_1401.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1390_1401.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1390_1401.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1390_1401.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1390_1401.G(quantity = "ThermalConductance", unit = "W/K") = 1.30001815906119e-05 "Constant thermal conductance of material"; Real TC_1391_1402.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1391_1402.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1391_1402.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1391_1402.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1391_1402.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1391_1402.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1391_1402.G(quantity = "ThermalConductance", unit = "W/K") = 5.19997158485472e-06 "Constant thermal conductance of material"; Real TC_1391_1438.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1391_1438.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1391_1438.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1391_1438.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1391_1438.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1391_1438.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1391_1438.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259996826404317 "Constant thermal conductance of material"; Real TC_1392_1393.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1392_1393.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1392_1393.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1392_1393.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1392_1393.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1392_1393.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1392_1393.G(quantity = "ThermalConductance", unit = "W/K") = 0.000111432530134669 "Constant thermal conductance of material"; Real TC_1392_1403.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1392_1403.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1392_1403.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1392_1403.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1392_1403.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1392_1403.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1392_1403.G(quantity = "ThermalConductance", unit = "W/K") = 5.1999727125079e-06 "Constant thermal conductance of material"; Real TC_1392_1439.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1392_1439.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1392_1439.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1392_1439.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1392_1439.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1392_1439.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1392_1439.G(quantity = "ThermalConductance", unit = "W/K") = 0.000780005014006516 "Constant thermal conductance of material"; Real TC_1393_1394.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1393_1394.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1393_1394.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1393_1394.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1393_1394.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1393_1394.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1393_1394.G(quantity = "ThermalConductance", unit = "W/K") = 7.79989553711336e-05 "Constant thermal conductance of material"; Real TC_1393_1404.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1393_1404.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1393_1404.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1393_1404.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1393_1404.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1393_1404.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1393_1404.G(quantity = "ThermalConductance", unit = "W/K") = 1.30000300506353e-05 "Constant thermal conductance of material"; Real TC_1393_1440.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1393_1440.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1393_1440.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1393_1440.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1393_1440.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1393_1440.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1393_1440.G(quantity = "ThermalConductance", unit = "W/K") = 0.00194992507396347 "Constant thermal conductance of material"; Real TC_1394_1395.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1394_1395.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1394_1395.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1394_1395.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1394_1395.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1394_1395.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1394_1395.G(quantity = "ThermalConductance", unit = "W/K") = 7.80003076449766e-05 "Constant thermal conductance of material"; Real TC_1394_1405.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1394_1405.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1394_1405.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1394_1405.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1394_1405.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1394_1405.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1394_1405.G(quantity = "ThermalConductance", unit = "W/K") = 1.30000830752068e-05 "Constant thermal conductance of material"; Real TC_1394_1441.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1394_1441.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1394_1441.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1394_1441.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1394_1441.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1394_1441.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1394_1441.G(quantity = "ThermalConductance", unit = "W/K") = 0.00195000219046676 "Constant thermal conductance of material"; Real TC_1395_1396.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1395_1396.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1395_1396.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1395_1396.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1395_1396.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1395_1396.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1395_1396.G(quantity = "ThermalConductance", unit = "W/K") = 7.80183649289079e-05 "Constant thermal conductance of material"; Real TC_1395_1406.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1395_1406.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1395_1406.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1395_1406.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1395_1406.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1395_1406.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1395_1406.G(quantity = "ThermalConductance", unit = "W/K") = 1.29999484505235e-05 "Constant thermal conductance of material"; Real TC_1395_1442.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1395_1442.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1395_1442.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1395_1442.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1395_1442.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1395_1442.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1395_1442.G(quantity = "ThermalConductance", unit = "W/K") = 0.00195002086793863 "Constant thermal conductance of material"; Real TC_1396_1397.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1396_1397.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1396_1397.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1396_1397.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1396_1397.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1396_1397.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1396_1397.G(quantity = "ThermalConductance", unit = "W/K") = 7.79972685591659e-05 "Constant thermal conductance of material"; Real TC_1396_1407.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1396_1407.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1396_1407.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1396_1407.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1396_1407.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1396_1407.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1396_1407.G(quantity = "ThermalConductance", unit = "W/K") = 1.30001378106482e-05 "Constant thermal conductance of material"; Real TC_1396_1443.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1396_1443.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1396_1443.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1396_1443.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1396_1443.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1396_1443.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1396_1443.G(quantity = "ThermalConductance", unit = "W/K") = 0.00195006549682068 "Constant thermal conductance of material"; Real TC_1397_1398.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1397_1398.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1397_1398.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1397_1398.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1397_1398.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1397_1398.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1397_1398.G(quantity = "ThermalConductance", unit = "W/K") = 7.80038355707495e-05 "Constant thermal conductance of material"; Real TC_1397_1408.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1397_1408.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1397_1408.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1397_1408.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1397_1408.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1397_1408.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1397_1408.G(quantity = "ThermalConductance", unit = "W/K") = 1.30002569053877e-05 "Constant thermal conductance of material"; Real TC_1397_1444.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1397_1444.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1397_1444.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1397_1444.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1397_1444.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1397_1444.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1397_1444.G(quantity = "ThermalConductance", unit = "W/K") = 0.00195006704331189 "Constant thermal conductance of material"; Real TC_1398_1399.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1398_1399.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1398_1399.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1398_1399.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1398_1399.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1398_1399.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1398_1399.G(quantity = "ThermalConductance", unit = "W/K") = 7.80001455498129e-05 "Constant thermal conductance of material"; Real TC_1398_1409.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1398_1409.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1398_1409.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1398_1409.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1398_1409.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1398_1409.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1398_1409.G(quantity = "ThermalConductance", unit = "W/K") = 1.29999239022905e-05 "Constant thermal conductance of material"; Real TC_1398_1445.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1398_1445.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1398_1445.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1398_1445.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1398_1445.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1398_1445.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1398_1445.G(quantity = "ThermalConductance", unit = "W/K") = 0.00195003635571698 "Constant thermal conductance of material"; Real TC_1399_1400.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1399_1400.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1399_1400.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1399_1400.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1399_1400.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1399_1400.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1399_1400.G(quantity = "ThermalConductance", unit = "W/K") = 7.79999074459724e-05 "Constant thermal conductance of material"; Real TC_1399_1410.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1399_1410.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1399_1410.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1399_1410.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1399_1410.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1399_1410.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1399_1410.G(quantity = "ThermalConductance", unit = "W/K") = 1.30000821742069e-05 "Constant thermal conductance of material"; Real TC_1399_1446.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1399_1446.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1399_1446.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1399_1446.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1399_1446.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1399_1446.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1399_1446.G(quantity = "ThermalConductance", unit = "W/K") = 0.00194995411872662 "Constant thermal conductance of material"; Real TC_1400_1401.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1400_1401.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1400_1401.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1400_1401.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1400_1401.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1400_1401.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1400_1401.G(quantity = "ThermalConductance", unit = "W/K") = 7.80003011594637e-05 "Constant thermal conductance of material"; Real TC_1400_1411.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1400_1411.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1400_1411.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1400_1411.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1400_1411.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1400_1411.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1400_1411.G(quantity = "ThermalConductance", unit = "W/K") = 1.30002952086038e-05 "Constant thermal conductance of material"; Real TC_1400_1447.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1400_1447.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1400_1447.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1400_1447.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1400_1447.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1400_1447.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1400_1447.G(quantity = "ThermalConductance", unit = "W/K") = 0.00195008261587964 "Constant thermal conductance of material"; Real TC_1401_1402.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1401_1402.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1401_1402.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1401_1402.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1401_1402.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1401_1402.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1401_1402.G(quantity = "ThermalConductance", unit = "W/K") = 0.000111425795381721 "Constant thermal conductance of material"; Real TC_1401_1412.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1401_1412.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1401_1412.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1401_1412.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1401_1412.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1401_1412.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1401_1412.G(quantity = "ThermalConductance", unit = "W/K") = 1.30002100653522e-05 "Constant thermal conductance of material"; Real TC_1401_1448.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1401_1448.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1401_1448.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1401_1448.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1401_1448.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1401_1448.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1401_1448.G(quantity = "ThermalConductance", unit = "W/K") = 0.00194991821068319 "Constant thermal conductance of material"; Real TC_1402_1413.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1402_1413.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1402_1413.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1402_1413.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1402_1413.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1402_1413.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1402_1413.G(quantity = "ThermalConductance", unit = "W/K") = 5.19996054059386e-06 "Constant thermal conductance of material"; Real TC_1402_1449.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1402_1449.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1402_1449.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1402_1449.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1402_1449.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1402_1449.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1402_1449.G(quantity = "ThermalConductance", unit = "W/K") = 0.000779982131273941 "Constant thermal conductance of material"; Real TC_1403_1404.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1403_1404.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1403_1404.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1403_1404.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1403_1404.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1403_1404.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1403_1404.G(quantity = "ThermalConductance", unit = "W/K") = 3.714260875235e-05 "Constant thermal conductance of material"; Real TC_1403_1450.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1403_1450.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1403_1450.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1403_1450.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1403_1450.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1403_1450.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1403_1450.G(quantity = "ThermalConductance", unit = "W/K") = 0.000260007892313765 "Constant thermal conductance of material"; Real TC_1404_1405.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1404_1405.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1404_1405.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1404_1405.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1404_1405.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1404_1405.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1404_1405.G(quantity = "ThermalConductance", unit = "W/K") = 2.5999478635922e-05 "Constant thermal conductance of material"; Real TC_1404_1451.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1404_1451.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1404_1451.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1404_1451.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1404_1451.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1404_1451.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1404_1451.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649996653354455 "Constant thermal conductance of material"; Real TC_1405_1406.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1405_1406.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1405_1406.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1405_1406.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1405_1406.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1405_1406.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1405_1406.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004662625726e-05 "Constant thermal conductance of material"; Real TC_1405_1452.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1405_1452.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1405_1452.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1405_1452.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1405_1452.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1405_1452.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1405_1452.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649994909905325 "Constant thermal conductance of material"; Real TC_1406_1407.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1406_1407.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1406_1407.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1406_1407.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1406_1407.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1406_1407.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1406_1407.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999999999991e-05 "Constant thermal conductance of material"; Real TC_1406_1453.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1406_1453.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1406_1453.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1406_1453.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1406_1453.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1406_1453.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1406_1453.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650004581225122 "Constant thermal conductance of material"; Real TC_1407_1408.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1407_1408.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1407_1408.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1407_1408.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1407_1408.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1407_1408.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1407_1408.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000000000001e-05 "Constant thermal conductance of material"; Real TC_1407_1454.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1407_1454.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1407_1454.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1407_1454.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1407_1454.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1407_1454.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1407_1454.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650001540215014 "Constant thermal conductance of material"; Real TC_1408_1409.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1408_1409.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1408_1409.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1408_1409.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1408_1409.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1408_1409.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1408_1409.G(quantity = "ThermalConductance", unit = "W/K") = 2.600142636396e-05 "Constant thermal conductance of material"; Real TC_1408_1455.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1408_1455.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1408_1455.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1408_1455.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1408_1455.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1408_1455.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1408_1455.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650001560403207 "Constant thermal conductance of material"; Real TC_1409_1410.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1409_1410.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1409_1410.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1409_1410.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1409_1410.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1409_1410.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1409_1410.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997425831777e-05 "Constant thermal conductance of material"; Real TC_1409_1456.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1409_1456.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1409_1456.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1409_1456.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1409_1456.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1409_1456.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1409_1456.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650002635601707 "Constant thermal conductance of material"; Real TC_1410_1411.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1410_1411.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1410_1411.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1410_1411.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1410_1411.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1410_1411.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1410_1411.G(quantity = "ThermalConductance", unit = "W/K") = 2.6e-05 "Constant thermal conductance of material"; Real TC_1410_1457.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1410_1457.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1410_1457.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1410_1457.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1410_1457.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1410_1457.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1410_1457.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649997332622033 "Constant thermal conductance of material"; Real TC_1411_1412.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1411_1412.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1411_1412.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1411_1412.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1411_1412.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1411_1412.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1411_1412.G(quantity = "ThermalConductance", unit = "W/K") = 2.60005583331219e-05 "Constant thermal conductance of material"; Real TC_1411_1458.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1411_1458.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1411_1458.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1411_1458.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1411_1458.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1411_1458.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1411_1458.G(quantity = "ThermalConductance", unit = "W/K") = 0.000650005956700205 "Constant thermal conductance of material"; Real TC_1412_1413.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1412_1413.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1412_1413.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1412_1413.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1412_1413.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1412_1413.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1412_1413.G(quantity = "ThermalConductance", unit = "W/K") = 3.71429221381165e-05 "Constant thermal conductance of material"; Real TC_1412_1459.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1412_1459.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1412_1459.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1412_1459.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1412_1459.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1412_1459.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1412_1459.G(quantity = "ThermalConductance", unit = "W/K") = 0.000649990376750227 "Constant thermal conductance of material"; Real TC_1413_1460.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1413_1460.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1413_1460.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1413_1460.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1413_1460.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1413_1460.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1413_1460.G(quantity = "ThermalConductance", unit = "W/K") = 0.000259994138335289 "Constant thermal conductance of material"; Real TC_1414_1417.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1414_1417.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1414_1417.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1414_1417.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1414_1417.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1414_1417.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1414_1417.G(quantity = "ThermalConductance", unit = "W/K") = 7.42845849802371e-06 "Constant thermal conductance of material"; Real TC_1414_1463.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1414_1463.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1414_1463.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1414_1463.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1414_1463.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1414_1463.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1414_1463.G(quantity = "ThermalConductance", unit = "W/K") = 7.42854121343967e-06 "Constant thermal conductance of material"; Real TC_1415_1416.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1415_1416.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1415_1416.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1415_1416.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1415_1416.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1415_1416.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1415_1416.G(quantity = "ThermalConductance", unit = "W/K") = 5.19998460811153e-05 "Constant thermal conductance of material"; Real TC_1415_1418.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1415_1418.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1415_1418.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1415_1418.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1415_1418.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1415_1418.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1415_1418.G(quantity = "ThermalConductance", unit = "W/K") = 4.95254833040432e-06 "Constant thermal conductance of material"; Real TC_1415_1464.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1415_1464.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1415_1464.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1415_1464.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1415_1464.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1415_1464.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1415_1464.G(quantity = "ThermalConductance", unit = "W/K") = 7.42838357272897e-06 "Constant thermal conductance of material"; Real TC_1416_1419.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1416_1419.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1416_1419.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1416_1419.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1416_1419.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1416_1419.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1416_1419.G(quantity = "ThermalConductance", unit = "W/K") = 1.23798418972337e-05 "Constant thermal conductance of material"; Real TC_1416_1465.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1416_1465.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1416_1465.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1416_1465.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1416_1465.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1416_1465.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1416_1465.G(quantity = "ThermalConductance", unit = "W/K") = 1.85710082385252e-05 "Constant thermal conductance of material"; Real TC_1417_1420.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1417_1420.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1417_1420.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1417_1420.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1417_1420.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1417_1420.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1417_1420.G(quantity = "ThermalConductance", unit = "W/K") = 4.95256998504923e-06 "Constant thermal conductance of material"; Real TC_1418_1419.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1418_1419.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1418_1419.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1418_1419.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1418_1419.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1418_1419.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1418_1419.G(quantity = "ThermalConductance", unit = "W/K") = 0.000104000354123813 "Constant thermal conductance of material"; Real TC_1418_1421.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1418_1421.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1418_1421.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1418_1421.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1418_1421.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1418_1421.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1418_1421.G(quantity = "ThermalConductance", unit = "W/K") = 5.47369581190305e-06 "Constant thermal conductance of material"; Real TC_1419_1422.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1419_1422.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1419_1422.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1419_1422.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1419_1422.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1419_1422.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1419_1422.G(quantity = "ThermalConductance", unit = "W/K") = 1.36836017027575e-05 "Constant thermal conductance of material"; Real TC_1420_1423.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1420_1423.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1420_1423.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1420_1423.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1420_1423.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1420_1423.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1420_1423.G(quantity = "ThermalConductance", unit = "W/K") = 5.47370346656911e-06 "Constant thermal conductance of material"; Real TC_1421_1422.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1421_1422.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1421_1422.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1421_1422.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1421_1422.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1421_1422.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1421_1422.G(quantity = "ThermalConductance", unit = "W/K") = 3.71425874214852e-05 "Constant thermal conductance of material"; Real TC_1421_1424.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1421_1424.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1421_1424.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1421_1424.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1421_1424.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1421_1424.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1421_1424.G(quantity = "ThermalConductance", unit = "W/K") = 1.0400314743779e-05 "Constant thermal conductance of material"; Real TC_1422_1425.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1422_1425.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1422_1425.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1422_1425.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1422_1425.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1422_1425.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1422_1425.G(quantity = "ThermalConductance", unit = "W/K") = 2.60007713073659e-05 "Constant thermal conductance of material"; Real TC_1423_1426.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1423_1426.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1423_1426.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1423_1426.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1423_1426.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1423_1426.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1423_1426.G(quantity = "ThermalConductance", unit = "W/K") = 1.04001227370358e-05 "Constant thermal conductance of material"; Real TC_1424_1425.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1424_1425.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1424_1425.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1424_1425.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1424_1425.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1424_1425.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1424_1425.G(quantity = "ThermalConductance", unit = "W/K") = 3.7142267324366e-05 "Constant thermal conductance of material"; Real TC_1424_1427.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1424_1427.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1424_1427.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1424_1427.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1424_1427.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1424_1427.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1424_1427.G(quantity = "ThermalConductance", unit = "W/K") = 1.03998320033598e-05 "Constant thermal conductance of material"; Real TC_1425_1428.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1425_1428.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1425_1428.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1425_1428.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1425_1428.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1425_1428.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1425_1428.G(quantity = "ThermalConductance", unit = "W/K") = 2.5999783186081e-05 "Constant thermal conductance of material"; Real TC_1426_1429.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1426_1429.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1426_1429.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1426_1429.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1426_1429.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1426_1429.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1426_1429.G(quantity = "ThermalConductance", unit = "W/K") = 1.0349347826159e-05 "Constant thermal conductance of material"; Real TC_1427_1428.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1427_1428.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1427_1428.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1427_1428.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1427_1428.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1427_1428.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1427_1428.G(quantity = "ThermalConductance", unit = "W/K") = 3.71435340742655e-05 "Constant thermal conductance of material"; Real TC_1427_1430.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1427_1430.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1427_1430.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1427_1430.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1427_1430.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1427_1430.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1427_1430.G(quantity = "ThermalConductance", unit = "W/K") = 1.04006100126206e-05 "Constant thermal conductance of material"; Real TC_1428_1431.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1428_1431.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1428_1431.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1428_1431.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1428_1431.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1428_1431.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1428_1431.G(quantity = "ThermalConductance", unit = "W/K") = 2.59995849115346e-05 "Constant thermal conductance of material"; Real TC_1429_1432.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1429_1432.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1429_1432.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1429_1432.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1429_1432.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1429_1432.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1429_1432.G(quantity = "ThermalConductance", unit = "W/K") = 1.0400311931375e-05 "Constant thermal conductance of material"; Real TC_1430_1431.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1430_1431.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1430_1431.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1430_1431.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1430_1431.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1430_1431.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1430_1431.G(quantity = "ThermalConductance", unit = "W/K") = 3.7142595198329e-05 "Constant thermal conductance of material"; Real TC_1430_1433.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1430_1433.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1430_1433.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1430_1433.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1430_1433.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1430_1433.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1430_1433.G(quantity = "ThermalConductance", unit = "W/K") = 1.04001719936928e-05 "Constant thermal conductance of material"; Real TC_1431_1434.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1431_1434.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1431_1434.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1431_1434.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1431_1434.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1431_1434.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1431_1434.G(quantity = "ThermalConductance", unit = "W/K") = 2.60004466279613e-05 "Constant thermal conductance of material"; Real TC_1432_1435.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1432_1435.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1432_1435.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1432_1435.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1432_1435.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1432_1435.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1432_1435.G(quantity = "ThermalConductance", unit = "W/K") = 1.03999253174013e-05 "Constant thermal conductance of material"; Real TC_1433_1434.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1433_1434.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1433_1434.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1433_1434.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1433_1434.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1433_1434.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1433_1434.G(quantity = "ThermalConductance", unit = "W/K") = 3.71428344404538e-05 "Constant thermal conductance of material"; Real TC_1433_1436.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1433_1436.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1433_1436.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1433_1436.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1433_1436.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1433_1436.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1433_1436.G(quantity = "ThermalConductance", unit = "W/K") = 1.04001262534295e-05 "Constant thermal conductance of material"; Real TC_1434_1437.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1434_1437.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1434_1437.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1434_1437.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1434_1437.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1434_1437.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1434_1437.G(quantity = "ThermalConductance", unit = "W/K") = 2.59994129732901e-05 "Constant thermal conductance of material"; Real TC_1435_1438.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1435_1438.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1435_1438.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1435_1438.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1435_1438.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1435_1438.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1435_1438.G(quantity = "ThermalConductance", unit = "W/K") = 1.03999027418224e-05 "Constant thermal conductance of material"; Real TC_1436_1437.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1436_1437.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1436_1437.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1436_1437.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1436_1437.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1436_1437.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1436_1437.G(quantity = "ThermalConductance", unit = "W/K") = 3.71433479067196e-05 "Constant thermal conductance of material"; Real TC_1436_1439.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1436_1439.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1436_1439.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1436_1439.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1436_1439.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1436_1439.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1436_1439.G(quantity = "ThermalConductance", unit = "W/K") = 5.20002068287975e-06 "Constant thermal conductance of material"; Real TC_1437_1440.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1437_1440.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1437_1440.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1437_1440.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1437_1440.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1437_1440.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1437_1440.G(quantity = "ThermalConductance", unit = "W/K") = 1.30000306604497e-05 "Constant thermal conductance of material"; Real TC_1438_1449.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1438_1449.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1438_1449.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1438_1449.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1438_1449.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1438_1449.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1438_1449.G(quantity = "ThermalConductance", unit = "W/K") = 5.19998247170305e-06 "Constant thermal conductance of material"; Real TC_1439_1440.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1439_1440.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1439_1440.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1439_1440.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1439_1440.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1439_1440.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1439_1440.G(quantity = "ThermalConductance", unit = "W/K") = 0.00011142821510616 "Constant thermal conductance of material"; Real TC_1439_1450.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1439_1450.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1439_1450.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1439_1450.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1439_1450.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1439_1450.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1439_1450.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001662303121e-06 "Constant thermal conductance of material"; Real TC_1440_1441.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1440_1441.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1440_1441.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1440_1441.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1440_1441.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1440_1441.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1440_1441.G(quantity = "ThermalConductance", unit = "W/K") = 7.79991232769957e-05 "Constant thermal conductance of material"; Real TC_1440_1451.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1440_1451.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1440_1451.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1440_1451.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1440_1451.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1440_1451.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1440_1451.G(quantity = "ThermalConductance", unit = "W/K") = 1.29997041360242e-05 "Constant thermal conductance of material"; Real TC_1441_1442.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1441_1442.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1441_1442.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1441_1442.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1441_1442.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1441_1442.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1441_1442.G(quantity = "ThermalConductance", unit = "W/K") = 7.79993486964349e-05 "Constant thermal conductance of material"; Real TC_1441_1452.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1441_1452.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1441_1452.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1441_1452.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1441_1452.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1441_1452.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1441_1452.G(quantity = "ThermalConductance", unit = "W/K") = 1.30001208078188e-05 "Constant thermal conductance of material"; Real TC_1442_1443.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1442_1443.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1442_1443.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1442_1443.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1442_1443.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1442_1443.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1442_1443.G(quantity = "ThermalConductance", unit = "W/K") = 7.79999999999962e-05 "Constant thermal conductance of material"; Real TC_1442_1453.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1442_1453.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1442_1453.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1442_1453.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1442_1453.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1442_1453.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1442_1453.G(quantity = "ThermalConductance", unit = "W/K") = 1.29998982609346e-05 "Constant thermal conductance of material"; Real TC_1443_1444.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1443_1444.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1443_1444.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1443_1444.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1443_1444.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1443_1444.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1443_1444.G(quantity = "ThermalConductance", unit = "W/K") = 7.80003735873726e-05 "Constant thermal conductance of material"; Real TC_1443_1454.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1443_1454.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1443_1454.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1443_1454.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1443_1454.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1443_1454.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1443_1454.G(quantity = "ThermalConductance", unit = "W/K") = 1.29999309365509e-05 "Constant thermal conductance of material"; Real TC_1444_1445.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1444_1445.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1444_1445.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1444_1445.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1444_1445.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1444_1445.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1444_1445.G(quantity = "ThermalConductance", unit = "W/K") = 7.79984585284849e-05 "Constant thermal conductance of material"; Real TC_1444_1455.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1444_1455.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1444_1455.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1444_1455.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1444_1455.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1444_1455.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1444_1455.G(quantity = "ThermalConductance", unit = "W/K") = 1.30001341445399e-05 "Constant thermal conductance of material"; Real TC_1445_1446.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1445_1446.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1445_1446.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1445_1446.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1445_1446.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1445_1446.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1445_1446.G(quantity = "ThermalConductance", unit = "W/K") = 7.80014523156382e-05 "Constant thermal conductance of material"; Real TC_1445_1456.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1445_1456.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1445_1456.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1445_1456.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1445_1456.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1445_1456.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1445_1456.G(quantity = "ThermalConductance", unit = "W/K") = 1.29996763992309e-05 "Constant thermal conductance of material"; Real TC_1446_1447.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1446_1447.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1446_1447.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1446_1447.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1446_1447.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1446_1447.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1446_1447.G(quantity = "ThermalConductance", unit = "W/K") = 7.8000699192044e-05 "Constant thermal conductance of material"; Real TC_1446_1457.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1446_1457.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1446_1457.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1446_1457.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1446_1457.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1446_1457.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1446_1457.G(quantity = "ThermalConductance", unit = "W/K") = 1.29996104435674e-05 "Constant thermal conductance of material"; Real TC_1447_1448.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1447_1448.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1447_1448.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1447_1448.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1447_1448.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1447_1448.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1447_1448.G(quantity = "ThermalConductance", unit = "W/K") = 7.80012938603247e-05 "Constant thermal conductance of material"; Real TC_1447_1458.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1447_1458.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1447_1458.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1447_1458.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1447_1458.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1447_1458.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1447_1458.G(quantity = "ThermalConductance", unit = "W/K") = 1.30004390375663e-05 "Constant thermal conductance of material"; Real TC_1448_1449.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1448_1449.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1448_1449.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1448_1449.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1448_1449.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1448_1449.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1448_1449.G(quantity = "ThermalConductance", unit = "W/K") = 0.000111427941473465 "Constant thermal conductance of material"; Real TC_1448_1459.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1448_1459.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1448_1459.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1448_1459.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1448_1459.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1448_1459.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1448_1459.G(quantity = "ThermalConductance", unit = "W/K") = 1.29996158551247e-05 "Constant thermal conductance of material"; Real TC_1449_1460.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1449_1460.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1449_1460.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1449_1460.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1449_1460.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1449_1460.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1449_1460.G(quantity = "ThermalConductance", unit = "W/K") = 5.1999488120674e-06 "Constant thermal conductance of material"; Real TC_1450_1451.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1450_1451.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1450_1451.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1450_1451.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1450_1451.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1450_1451.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1450_1451.G(quantity = "ThermalConductance", unit = "W/K") = 3.7142832765961e-05 "Constant thermal conductance of material"; Real TC_1451_1452.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1451_1452.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1451_1452.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1451_1452.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1451_1452.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1451_1452.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1451_1452.G(quantity = "ThermalConductance", unit = "W/K") = 2.59992612721948e-05 "Constant thermal conductance of material"; Real TC_1452_1453.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1452_1453.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1452_1453.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1452_1453.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1452_1453.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1452_1453.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1452_1453.G(quantity = "ThermalConductance", unit = "W/K") = 2.59998667954314e-05 "Constant thermal conductance of material"; Real TC_1453_1454.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1453_1454.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1453_1454.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1453_1454.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1453_1454.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1453_1454.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1453_1454.G(quantity = "ThermalConductance", unit = "W/K") = 2.60013410818055e-05 "Constant thermal conductance of material"; Real TC_1454_1455.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1454_1455.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1454_1455.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1454_1455.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1454_1455.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1454_1455.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1454_1455.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999999999981e-05 "Constant thermal conductance of material"; Real TC_1455_1456.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1455_1456.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1455_1456.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1455_1456.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1455_1456.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1455_1456.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1455_1456.G(quantity = "ThermalConductance", unit = "W/K") = 2.59994396974363e-05 "Constant thermal conductance of material"; Real TC_1456_1457.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1456_1457.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1456_1457.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1456_1457.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1456_1457.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1456_1457.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1456_1457.G(quantity = "ThermalConductance", unit = "W/K") = 2.59997223957252e-05 "Constant thermal conductance of material"; Real TC_1457_1458.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1457_1458.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1457_1458.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1457_1458.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1457_1458.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1457_1458.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1457_1458.G(quantity = "ThermalConductance", unit = "W/K") = 2.60003955435427e-05 "Constant thermal conductance of material"; Real TC_1458_1459.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1458_1459.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1458_1459.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1458_1459.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1458_1459.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1458_1459.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1458_1459.G(quantity = "ThermalConductance", unit = "W/K") = 2.59995689964802e-05 "Constant thermal conductance of material"; Real TC_1459_1460.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1459_1460.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1459_1460.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1459_1460.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1459_1460.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1459_1460.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1459_1460.G(quantity = "ThermalConductance", unit = "W/K") = 3.71427056734142e-05 "Constant thermal conductance of material"; Real TC_1461_1462.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1461_1462.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1461_1462.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1461_1462.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1461_1462.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1461_1462.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1461_1462.G(quantity = "ThermalConductance", unit = "W/K") = 5.20002110894158e-05 "Constant thermal conductance of material"; Real TC_1461_1464.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1461_1464.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1461_1464.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1461_1464.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1461_1464.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1461_1464.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1461_1464.G(quantity = "ThermalConductance", unit = "W/K") = 7.42860771819899e-06 "Constant thermal conductance of material"; Real TC_1461_1466.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1461_1466.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1461_1466.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1461_1466.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1461_1466.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1461_1466.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1461_1466.G(quantity = "ThermalConductance", unit = "W/K") = 6.1174930221654e-06 "Constant thermal conductance of material"; Real TC_1462_1465.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1462_1465.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1462_1465.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1462_1465.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1462_1465.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1462_1465.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1462_1465.G(quantity = "ThermalConductance", unit = "W/K") = 1.85723982315496e-05 "Constant thermal conductance of material"; Real TC_1462_1467.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1462_1467.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1462_1467.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1462_1467.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1462_1467.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1462_1467.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1462_1467.G(quantity = "ThermalConductance", unit = "W/K") = 1.52941384958519e-05 "Constant thermal conductance of material"; Real TC_1463_1476.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1463_1476.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1463_1476.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1463_1476.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1463_1476.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1463_1476.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1463_1476.G(quantity = "ThermalConductance", unit = "W/K") = 6.117683354965e-06 "Constant thermal conductance of material"; Real TC_1464_1465.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1464_1465.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1464_1465.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1464_1465.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1464_1465.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1464_1465.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1464_1465.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000109988919e-05 "Constant thermal conductance of material"; Real TC_1466_1467.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1466_1467.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1466_1467.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1466_1467.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1466_1467.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1466_1467.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1466_1467.G(quantity = "ThermalConductance", unit = "W/K") = 7.42852166213671e-05 "Constant thermal conductance of material"; Real TC_1466_1477.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1466_1477.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1466_1477.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1466_1477.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1466_1477.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1466_1477.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1466_1477.G(quantity = "ThermalConductance", unit = "W/K") = 6.93338727653607e-06 "Constant thermal conductance of material"; Real TC_1467_1468.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1467_1468.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1467_1468.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1467_1468.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1467_1468.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1467_1468.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1467_1468.G(quantity = "ThermalConductance", unit = "W/K") = 5.20001217597766e-05 "Constant thermal conductance of material"; Real TC_1467_1478.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1467_1478.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1467_1478.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1467_1478.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1467_1478.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1467_1478.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1467_1478.G(quantity = "ThermalConductance", unit = "W/K") = 1.73332202337939e-05 "Constant thermal conductance of material"; Real TC_1468_1469.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1468_1469.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1468_1469.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1468_1469.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1468_1469.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1468_1469.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1468_1469.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000647270136e-05 "Constant thermal conductance of material"; Real TC_1468_1479.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1468_1479.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1468_1479.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1468_1479.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1468_1479.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1468_1479.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1468_1479.G(quantity = "ThermalConductance", unit = "W/K") = 1.73331787870233e-05 "Constant thermal conductance of material"; Real TC_1469_1470.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1469_1470.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1469_1470.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1469_1470.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1469_1470.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1469_1470.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1469_1470.G(quantity = "ThermalConductance", unit = "W/K") = 5.20005915409646e-05 "Constant thermal conductance of material"; Real TC_1469_1480.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1469_1480.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1469_1480.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1469_1480.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1469_1480.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1469_1480.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1469_1480.G(quantity = "ThermalConductance", unit = "W/K") = 1.73334223540053e-05 "Constant thermal conductance of material"; Real TC_1470_1471.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1470_1471.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1470_1471.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1470_1471.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1470_1471.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1470_1471.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1470_1471.G(quantity = "ThermalConductance", unit = "W/K") = 5.19252077562055e-05 "Constant thermal conductance of material"; Real TC_1470_1481.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1470_1481.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1470_1481.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1470_1481.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1470_1481.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1470_1481.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1470_1481.G(quantity = "ThermalConductance", unit = "W/K") = 1.73330133822871e-05 "Constant thermal conductance of material"; Real TC_1471_1472.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1471_1472.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1471_1472.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1471_1472.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1471_1472.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1471_1472.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1471_1472.G(quantity = "ThermalConductance", unit = "W/K") = 5.19996622192195e-05 "Constant thermal conductance of material"; Real TC_1471_1482.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1471_1482.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1471_1482.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1471_1482.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1471_1482.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1471_1482.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1471_1482.G(quantity = "ThermalConductance", unit = "W/K") = 1.73334418884194e-05 "Constant thermal conductance of material"; Real TC_1472_1473.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1472_1473.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1472_1473.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1472_1473.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1472_1473.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1472_1473.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1472_1473.G(quantity = "ThermalConductance", unit = "W/K") = 5.20020654367939e-05 "Constant thermal conductance of material"; Real TC_1472_1483.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1472_1483.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1472_1483.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1472_1483.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1472_1483.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1472_1483.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1472_1483.G(quantity = "ThermalConductance", unit = "W/K") = 1.73328818699417e-05 "Constant thermal conductance of material"; Real TC_1473_1474.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1473_1474.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1473_1474.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1473_1474.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1473_1474.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1473_1474.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1473_1474.G(quantity = "ThermalConductance", unit = "W/K") = 5.20000821810859e-05 "Constant thermal conductance of material"; Real TC_1473_1484.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1473_1484.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1473_1484.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1473_1484.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1473_1484.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1473_1484.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1473_1484.G(quantity = "ThermalConductance", unit = "W/K") = 1.73330100034801e-05 "Constant thermal conductance of material"; Real TC_1474_1475.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1474_1475.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1474_1475.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1474_1475.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1474_1475.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1474_1475.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1474_1475.G(quantity = "ThermalConductance", unit = "W/K") = 5.19997498749374e-05 "Constant thermal conductance of material"; Real TC_1474_1485.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1474_1485.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1474_1485.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1474_1485.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1474_1485.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1474_1485.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1474_1485.G(quantity = "ThermalConductance", unit = "W/K") = 1.73333983894849e-05 "Constant thermal conductance of material"; Real TC_1475_1476.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1475_1476.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1475_1476.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1475_1476.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1475_1476.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1475_1476.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1475_1476.G(quantity = "ThermalConductance", unit = "W/K") = 7.42863703966832e-05 "Constant thermal conductance of material"; Real TC_1475_1486.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1475_1486.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1475_1486.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1475_1486.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1475_1486.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1475_1486.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1475_1486.G(quantity = "ThermalConductance", unit = "W/K") = 1.73334550285477e-05 "Constant thermal conductance of material"; Real TC_1476_1487.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1476_1487.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1476_1487.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1476_1487.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1476_1487.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1476_1487.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1476_1487.G(quantity = "ThermalConductance", unit = "W/K") = 6.93331718421043e-06 "Constant thermal conductance of material"; Real TC_1477_1478.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1477_1478.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1477_1478.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1477_1478.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1477_1478.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1477_1478.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1477_1478.G(quantity = "ThermalConductance", unit = "W/K") = 3.71429211402631e-05 "Constant thermal conductance of material"; Real TC_1478_1479.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1478_1479.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1478_1479.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1478_1479.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1478_1479.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1478_1479.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1478_1479.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000437177582e-05 "Constant thermal conductance of material"; Real TC_1479_1480.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1479_1480.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1479_1480.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1479_1480.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1479_1480.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1479_1480.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1479_1480.G(quantity = "ThermalConductance", unit = "W/K") = 2.59999476672684e-05 "Constant thermal conductance of material"; Real TC_1480_1481.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1480_1481.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1480_1481.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1480_1481.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1480_1481.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1480_1481.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1480_1481.G(quantity = "ThermalConductance", unit = "W/K") = 2.60001400266051e-05 "Constant thermal conductance of material"; Real TC_1481_1482.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1481_1482.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1481_1482.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1481_1482.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1481_1482.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1481_1482.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1481_1482.G(quantity = "ThermalConductance", unit = "W/K") = 2.60028078620124e-05 "Constant thermal conductance of material"; Real TC_1482_1483.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1482_1483.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1482_1483.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1482_1483.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1482_1483.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1482_1483.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1482_1483.G(quantity = "ThermalConductance", unit = "W/K") = 2.5998915205206e-05 "Constant thermal conductance of material"; Real TC_1483_1484.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1483_1484.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1483_1484.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1483_1484.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1483_1484.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1483_1484.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1483_1484.G(quantity = "ThermalConductance", unit = "W/K") = 2.60002686186286e-05 "Constant thermal conductance of material"; Real TC_1484_1485.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1484_1485.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1484_1485.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1484_1485.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1484_1485.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1484_1485.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1484_1485.G(quantity = "ThermalConductance", unit = "W/K") = 2.60000000000001e-05 "Constant thermal conductance of material"; Real TC_1485_1486.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1485_1486.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1485_1486.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1485_1486.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1485_1486.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1485_1486.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1485_1486.G(quantity = "ThermalConductance", unit = "W/K") = 2.59994516723992e-05 "Constant thermal conductance of material"; Real TC_1486_1487.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1486_1487.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1486_1487.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1486_1487.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1486_1487.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1486_1487.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1486_1487.G(quantity = "ThermalConductance", unit = "W/K") = 3.71426849752563e-05 "Constant thermal conductance of material"; Real TC_1488_1489.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1488_1489.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1488_1489.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1488_1489.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1488_1489.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1488_1489.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1488_1489.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000005 "Constant thermal conductance of material"; Real TC_1488_1491.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1488_1491.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1488_1491.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1488_1491.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1488_1491.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1488_1491.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1488_1491.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000001 "Constant thermal conductance of material"; Real TC_1488_1509.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1488_1509.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1488_1509.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1488_1509.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1488_1509.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1488_1509.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1488_1509.G(quantity = "ThermalConductance", unit = "W/K") = 0.0416667901691986 "Constant thermal conductance of material"; Real TC_1489_1490.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1489_1490.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1489_1490.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1489_1490.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1489_1490.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1489_1490.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1489_1490.G(quantity = "ThermalConductance", unit = "W/K") = 0.0010000773309766 "Constant thermal conductance of material"; Real TC_1489_1492.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1489_1492.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1489_1492.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1489_1492.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1489_1492.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1489_1492.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1489_1492.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999989 "Constant thermal conductance of material"; Real TC_1489_1510.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1489_1510.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1489_1510.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1489_1510.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1489_1510.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1489_1510.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1489_1510.G(quantity = "ThermalConductance", unit = "W/K") = 0.0416668434675604 "Constant thermal conductance of material"; Real TC_1490_1493.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1490_1493.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1490_1493.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1490_1493.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1490_1493.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1490_1493.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1490_1493.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999999999999991 "Constant thermal conductance of material"; Real TC_1490_1511.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1490_1511.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1490_1511.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1490_1511.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1490_1511.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1490_1511.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1490_1511.G(quantity = "ThermalConductance", unit = "W/K") = 0.0416666216033528 "Constant thermal conductance of material"; Real TC_1491_1492.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1491_1492.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1491_1492.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1491_1492.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1491_1492.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1491_1492.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1491_1492.G(quantity = "ThermalConductance", unit = "W/K") = 0.001 "Constant thermal conductance of material"; Real TC_1491_1494.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1491_1494.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1491_1494.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1491_1494.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1491_1494.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1491_1494.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1491_1494.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100007706139223 "Constant thermal conductance of material"; Real TC_1491_1512.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1491_1512.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1491_1512.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1491_1512.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1491_1512.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1491_1512.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1491_1512.G(quantity = "ThermalConductance", unit = "W/K") = 0.0416666666666667 "Constant thermal conductance of material"; Real TC_1492_1493.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1492_1493.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1492_1493.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1492_1493.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1492_1493.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1492_1493.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1492_1493.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100000000000001 "Constant thermal conductance of material"; Real TC_1492_1495.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1492_1495.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1492_1495.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1492_1495.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1492_1495.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1492_1495.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1492_1495.G(quantity = "ThermalConductance", unit = "W/K") = 0.00100059523809362 "Constant thermal conductance of material"; Real TC_1492_1513.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1492_1513.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1492_1513.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1492_1513.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1492_1513.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1492_1513.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1492_1513.G(quantity = "ThermalConductance", unit = "W/K") = 0.0416664464050664 "Constant thermal conductance of material"; Real TC_1493_1496.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1493_1496.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1493_1496.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1493_1496.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1493_1496.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1493_1496.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1493_1496.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999158091674101 "Constant thermal conductance of material"; Real TC_1493_1514.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1493_1514.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1493_1514.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1493_1514.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1493_1514.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1493_1514.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1493_1514.G(quantity = "ThermalConductance", unit = "W/K") = 0.0416665311939483 "Constant thermal conductance of material"; Real TC_1494_1495.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1494_1495.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1494_1495.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1494_1495.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1494_1495.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1494_1495.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1494_1495.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999986702127723 "Constant thermal conductance of material"; Real TC_1494_1515.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1494_1515.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1494_1515.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1494_1515.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1494_1515.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1494_1515.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1494_1515.G(quantity = "ThermalConductance", unit = "W/K") = 0.0416665109499963 "Constant thermal conductance of material"; Real TC_1495_1496.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1495_1496.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1495_1496.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1495_1496.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1495_1496.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1495_1496.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1495_1496.G(quantity = "ThermalConductance", unit = "W/K") = 0.000999912111091594 "Constant thermal conductance of material"; Real TC_1495_1516.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1495_1516.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1495_1516.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1495_1516.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1495_1516.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1495_1516.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1495_1516.G(quantity = "ThermalConductance", unit = "W/K") = 0.0416664548176997 "Constant thermal conductance of material"; Real TC_1496_1517.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1496_1517.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1496_1517.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1496_1517.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1496_1517.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1496_1517.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1496_1517.G(quantity = "ThermalConductance", unit = "W/K") = 0.0416664024100206 "Constant thermal conductance of material"; Real TC_1497_1498.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1497_1498.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1497_1498.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1497_1498.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1497_1498.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1497_1498.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1497_1498.G(quantity = "ThermalConductance", unit = "W/K") = 0.00700027302156881 "Constant thermal conductance of material"; Real TC_1497_1501.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1497_1501.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1497_1501.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1497_1501.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1497_1501.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1497_1501.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1497_1501.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357140466548416 "Constant thermal conductance of material"; Real TC_1497_1618.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1497_1618.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1497_1618.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1497_1618.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1497_1618.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1497_1618.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1497_1618.G(quantity = "ThermalConductance", unit = "W/K") = 0.311104610344003 "Constant thermal conductance of material"; Real TC_1498_1499.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1498_1499.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1498_1499.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1498_1499.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1498_1499.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1498_1499.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1498_1499.G(quantity = "ThermalConductance", unit = "W/K") = 0.00699999999999999 "Constant thermal conductance of material"; Real TC_1498_1502.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1498_1502.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1498_1502.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1498_1502.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1498_1502.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1498_1502.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1498_1502.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357134014237074 "Constant thermal conductance of material"; Real TC_1498_1619.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1498_1619.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1498_1619.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1498_1619.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1498_1619.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1498_1619.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1498_1619.G(quantity = "ThermalConductance", unit = "W/K") = 0.311116744834575 "Constant thermal conductance of material"; Real TC_1499_1500.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1499_1500.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1499_1500.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1499_1500.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1499_1500.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1499_1500.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1499_1500.G(quantity = "ThermalConductance", unit = "W/K") = 0.00700019262255596 "Constant thermal conductance of material"; Real TC_1499_1503.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1499_1503.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1499_1503.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1499_1503.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1499_1503.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1499_1503.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1499_1503.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357136459981493 "Constant thermal conductance of material"; Real TC_1499_1620.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1499_1620.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1499_1620.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1499_1620.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1499_1620.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1499_1620.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1499_1620.G(quantity = "ThermalConductance", unit = "W/K") = 0.31111563517914 "Constant thermal conductance of material"; Real TC_1500_1504.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1500_1504.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1500_1504.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1500_1504.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1500_1504.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1500_1504.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1500_1504.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357164295575959 "Constant thermal conductance of material"; Real TC_1500_1621.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1500_1621.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1500_1621.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1500_1621.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1500_1621.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1500_1621.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1500_1621.G(quantity = "ThermalConductance", unit = "W/K") = 0.311088145896676 "Constant thermal conductance of material"; Real TC_1501_1502.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1501_1502.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1501_1502.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1501_1502.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1501_1502.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1501_1502.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1501_1502.G(quantity = "ThermalConductance", unit = "W/K") = 0.00699999999999992 "Constant thermal conductance of material"; Real TC_1501_1505.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1501_1505.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1501_1505.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1501_1505.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1501_1505.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1501_1505.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1501_1505.G(quantity = "ThermalConductance", unit = "W/K") = 0.0035720892821237 "Constant thermal conductance of material"; Real TC_1501_1627.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1501_1627.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1501_1627.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1501_1627.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1501_1627.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1501_1627.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1501_1627.G(quantity = "ThermalConductance", unit = "W/K") = 0.311140819964362 "Constant thermal conductance of material"; Real TC_1502_1503.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1502_1503.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1502_1503.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1502_1503.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1502_1503.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1502_1503.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1502_1503.G(quantity = "ThermalConductance", unit = "W/K") = 0.00699954121425312 "Constant thermal conductance of material"; Real TC_1502_1506.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1502_1506.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1502_1506.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1502_1506.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1502_1506.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1502_1506.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1502_1506.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357155025553638 "Constant thermal conductance of material"; Real TC_1502_1628.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1502_1628.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1502_1628.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1502_1628.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1502_1628.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1502_1628.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1502_1628.G(quantity = "ThermalConductance", unit = "W/K") = 0.311128504340398 "Constant thermal conductance of material"; Real TC_1503_1504.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1503_1504.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1503_1504.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1503_1504.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1503_1504.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1503_1504.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1503_1504.G(quantity = "ThermalConductance", unit = "W/K") = 0.00699933724673392 "Constant thermal conductance of material"; Real TC_1503_1507.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1503_1507.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1503_1507.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1503_1507.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1503_1507.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1503_1507.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1503_1507.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357098405289785 "Constant thermal conductance of material"; Real TC_1503_1629.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1503_1629.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1503_1629.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1503_1629.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1503_1629.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1503_1629.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1503_1629.G(quantity = "ThermalConductance", unit = "W/K") = 0.311066460587351 "Constant thermal conductance of material"; Real TC_1504_1508.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1504_1508.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1504_1508.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1504_1508.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1504_1508.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1504_1508.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1504_1508.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357169781686812 "Constant thermal conductance of material"; Real TC_1504_1630.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1504_1630.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1504_1630.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1504_1630.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1504_1630.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1504_1630.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1504_1630.G(quantity = "ThermalConductance", unit = "W/K") = 0.311148740178793 "Constant thermal conductance of material"; Real TC_1505_1506.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1505_1506.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1505_1506.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1505_1506.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1505_1506.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1505_1506.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1505_1506.G(quantity = "ThermalConductance", unit = "W/K") = 0.0070002692411248 "Constant thermal conductance of material"; Real TC_1505_1564.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1505_1564.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1505_1564.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1505_1564.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1505_1564.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1505_1564.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1505_1564.G(quantity = "ThermalConductance", unit = "W/K") = 0.311101756074091 "Constant thermal conductance of material"; Real TC_1506_1507.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1506_1507.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1506_1507.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1506_1507.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1506_1507.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1506_1507.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1506_1507.G(quantity = "ThermalConductance", unit = "W/K") = 0.00700021110407419 "Constant thermal conductance of material"; Real TC_1506_1565.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1506_1565.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1506_1565.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1506_1565.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1506_1565.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1506_1565.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1506_1565.G(quantity = "ThermalConductance", unit = "W/K") = 0.311100941422608 "Constant thermal conductance of material"; Real TC_1507_1508.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1507_1508.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1507_1508.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1507_1508.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1507_1508.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1507_1508.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1507_1508.G(quantity = "ThermalConductance", unit = "W/K") = 0.0070002170138889 "Constant thermal conductance of material"; Real TC_1507_1566.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1507_1566.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1507_1566.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1507_1566.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1507_1566.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1507_1566.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1507_1566.G(quantity = "ThermalConductance", unit = "W/K") = 0.311120448179254 "Constant thermal conductance of material"; Real TC_1508_1567.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1508_1567.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1508_1567.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1508_1567.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1508_1567.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1508_1567.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1508_1567.G(quantity = "ThermalConductance", unit = "W/K") = 0.31109993714643 "Constant thermal conductance of material"; Real TC_1509_1510.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1509_1510.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1509_1510.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1509_1510.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1509_1510.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1509_1510.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1509_1510.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499911321312523 "Constant thermal conductance of material"; Real TC_1509_1512.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1509_1512.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1509_1512.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1509_1512.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1509_1512.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1509_1512.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1509_1512.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499983711763365 "Constant thermal conductance of material"; Real TC_1509_1586.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1509_1586.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1509_1586.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1509_1586.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1509_1586.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1509_1586.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1509_1586.G(quantity = "ThermalConductance", unit = "W/K") = 0.222254545454518 "Constant thermal conductance of material"; Real TC_1510_1511.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1510_1511.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1510_1511.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1510_1511.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1510_1511.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1510_1511.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1510_1511.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500023691068444 "Constant thermal conductance of material"; Real TC_1510_1513.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1510_1513.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1510_1513.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1510_1513.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1510_1513.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1510_1513.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1510_1513.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500000000000009 "Constant thermal conductance of material"; Real TC_1510_1587.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1510_1587.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1510_1587.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1510_1587.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1510_1587.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1510_1587.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1510_1587.G(quantity = "ThermalConductance", unit = "W/K") = 0.222282900626681 "Constant thermal conductance of material"; Real TC_1511_1514.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1511_1514.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1511_1514.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1511_1514.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1511_1514.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1511_1514.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1511_1514.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500000000000001 "Constant thermal conductance of material"; Real TC_1511_1588.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1511_1588.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1511_1588.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1511_1588.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1511_1588.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1511_1588.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1511_1588.G(quantity = "ThermalConductance", unit = "W/K") = 0.222147406733402 "Constant thermal conductance of material"; Real TC_1512_1513.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1512_1513.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1512_1513.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1512_1513.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1512_1513.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1512_1513.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1512_1513.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499971048060223 "Constant thermal conductance of material"; Real TC_1512_1515.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1512_1515.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1512_1515.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1512_1515.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1512_1515.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1512_1515.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1512_1515.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499992684175867 "Constant thermal conductance of material"; Real TC_1512_1595.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1512_1595.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1512_1595.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1512_1595.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1512_1595.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1512_1595.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1512_1595.G(quantity = "ThermalConductance", unit = "W/K") = 0.222248117604882 "Constant thermal conductance of material"; Real TC_1513_1514.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1513_1514.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1513_1514.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1513_1514.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1513_1514.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1513_1514.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1513_1514.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500006582845103 "Constant thermal conductance of material"; Real TC_1513_1516.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1513_1516.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1513_1516.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1513_1516.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1513_1516.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1513_1516.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1513_1516.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499986225895308 "Constant thermal conductance of material"; Real TC_1513_1596.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1513_1596.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1513_1596.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1513_1596.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1513_1596.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1513_1596.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1513_1596.G(quantity = "ThermalConductance", unit = "W/K") = 0.222239382238955 "Constant thermal conductance of material"; Real TC_1514_1517.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1514_1517.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1514_1517.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1514_1517.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1514_1517.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1514_1517.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1514_1517.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499972237645744 "Constant thermal conductance of material"; Real TC_1514_1597.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1514_1597.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1514_1597.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1514_1597.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1514_1597.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1514_1597.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1514_1597.G(quantity = "ThermalConductance", unit = "W/K") = 0.222209705372683 "Constant thermal conductance of material"; Real TC_1515_1516.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1515_1516.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1515_1516.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1515_1516.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1515_1516.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1515_1516.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1515_1516.G(quantity = "ThermalConductance", unit = "W/K") = 0.005 "Constant thermal conductance of material"; Real TC_1515_1604.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1515_1604.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1515_1604.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1515_1604.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1515_1604.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1515_1604.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1515_1604.G(quantity = "ThermalConductance", unit = "W/K") = 0.222245807684127 "Constant thermal conductance of material"; Real TC_1516_1517.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1516_1517.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1516_1517.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1516_1517.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1516_1517.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1516_1517.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1516_1517.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500005305321233 "Constant thermal conductance of material"; Real TC_1516_1605.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1516_1605.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1516_1605.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1516_1605.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1516_1605.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1516_1605.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1516_1605.G(quantity = "ThermalConductance", unit = "W/K") = 0.222287066246002 "Constant thermal conductance of material"; Real TC_1517_1606.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1517_1606.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1517_1606.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1517_1606.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1517_1606.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1517_1606.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1517_1606.G(quantity = "ThermalConductance", unit = "W/K") = 0.222263681592204 "Constant thermal conductance of material"; Real TC_1518_1519.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1518_1519.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1518_1519.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1518_1519.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1518_1519.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1518_1519.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1518_1519.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500017768301342 "Constant thermal conductance of material"; Real TC_1518_1521.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1518_1521.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1518_1521.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1518_1521.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1518_1521.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1518_1521.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1518_1521.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500005811250578 "Constant thermal conductance of material"; Real TC_1518_1528.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1518_1528.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1518_1528.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1518_1528.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1518_1528.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1518_1528.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1518_1528.G(quantity = "ThermalConductance", unit = "W/K") = 0.222212908633692 "Constant thermal conductance of material"; Real TC_1519_1520.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1519_1520.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1519_1520.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1519_1520.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1519_1520.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1519_1520.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1519_1520.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500019144618448 "Constant thermal conductance of material"; Real TC_1519_1522.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1519_1522.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1519_1522.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1519_1522.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1519_1522.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1519_1522.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1519_1522.G(quantity = "ThermalConductance", unit = "W/K") = 0.0050000591470989 "Constant thermal conductance of material"; Real TC_1519_1529.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1519_1529.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1519_1529.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1519_1529.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1519_1529.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1519_1529.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1519_1529.G(quantity = "ThermalConductance", unit = "W/K") = 0.22221410970155 "Constant thermal conductance of material"; Real TC_1520_1523.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1520_1523.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1520_1523.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1520_1523.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1520_1523.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1520_1523.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1520_1523.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500038365624418 "Constant thermal conductance of material"; Real TC_1520_1530.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1520_1530.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1520_1530.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1520_1530.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1520_1530.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1520_1530.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1520_1530.G(quantity = "ThermalConductance", unit = "W/K") = 0.222205082406427 "Constant thermal conductance of material"; Real TC_1521_1522.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1521_1522.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1521_1522.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1521_1522.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1521_1522.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1521_1522.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1521_1522.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500018256503885 "Constant thermal conductance of material"; Real TC_1521_1524.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1521_1524.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1521_1524.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1521_1524.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1521_1524.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1521_1524.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1521_1524.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500000000000002 "Constant thermal conductance of material"; Real TC_1521_1537.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1521_1537.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1521_1537.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1521_1537.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1521_1537.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1521_1537.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1521_1537.G(quantity = "ThermalConductance", unit = "W/K") = 0.222211593648364 "Constant thermal conductance of material"; Real TC_1522_1523.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1522_1523.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1522_1523.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1522_1523.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1522_1523.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1522_1523.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1522_1523.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499999999999998 "Constant thermal conductance of material"; Real TC_1522_1525.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1522_1525.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1522_1525.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1522_1525.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1522_1525.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1522_1525.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1522_1525.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500014819644923 "Constant thermal conductance of material"; Real TC_1522_1538.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1522_1538.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1522_1538.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1522_1538.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1522_1538.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1522_1538.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1522_1538.G(quantity = "ThermalConductance", unit = "W/K") = 0.222224608116818 "Constant thermal conductance of material"; Real TC_1523_1526.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1523_1526.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1523_1526.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1523_1526.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1523_1526.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1523_1526.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1523_1526.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500014349261014 "Constant thermal conductance of material"; Real TC_1523_1539.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1523_1539.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1523_1539.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1523_1539.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1523_1539.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1523_1539.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1523_1539.G(quantity = "ThermalConductance", unit = "W/K") = 0.222228163992867 "Constant thermal conductance of material"; Real TC_1524_1525.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1524_1525.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1524_1525.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1524_1525.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1524_1525.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1524_1525.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1524_1525.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499977673587866 "Constant thermal conductance of material"; Real TC_1524_1546.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1524_1546.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1524_1546.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1524_1546.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1524_1546.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1524_1546.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1524_1546.G(quantity = "ThermalConductance", unit = "W/K") = 0.222214058290474 "Constant thermal conductance of material"; Real TC_1525_1526.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1525_1526.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1525_1526.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1525_1526.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1525_1526.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1525_1526.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1525_1526.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499999999999997 "Constant thermal conductance of material"; Real TC_1525_1547.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1525_1547.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1525_1547.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1525_1547.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1525_1547.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1525_1547.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1525_1547.G(quantity = "ThermalConductance", unit = "W/K") = 0.222223208736565 "Constant thermal conductance of material"; Real TC_1526_1548.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1526_1548.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1526_1548.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1526_1548.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1526_1548.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1526_1548.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1526_1548.G(quantity = "ThermalConductance", unit = "W/K") = 0.222223921688586 "Constant thermal conductance of material"; Real TC_1527_1528.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1527_1528.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1527_1528.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1527_1528.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1527_1528.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1527_1528.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1527_1528.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400002995491789 "Constant thermal conductance of material"; Real TC_1527_1536.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1527_1536.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1527_1536.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1527_1536.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1527_1536.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1527_1536.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1527_1536.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399992198470921 "Constant thermal conductance of material"; Real TC_1527_1599.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1527_1599.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1527_1599.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1527_1599.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1527_1599.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1527_1599.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1527_1599.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400007770158702 "Constant thermal conductance of material"; Real TC_1528_1529.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1528_1529.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1528_1529.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1528_1529.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1528_1529.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1528_1529.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1528_1529.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400016354567014 "Constant thermal conductance of material"; Real TC_1528_1537.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1528_1537.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1528_1537.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1528_1537.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1528_1537.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1528_1537.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1528_1537.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400010704345957 "Constant thermal conductance of material"; Real TC_1528_1600.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1528_1600.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1528_1600.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1528_1600.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1528_1600.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1528_1600.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1528_1600.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399993520798237 "Constant thermal conductance of material"; Real TC_1528_1656.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1528_1656.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1528_1656.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1528_1656.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1528_1656.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1528_1656.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1528_1656.G(quantity = "ThermalConductance", unit = "W/K") = 0.222228178325737 "Constant thermal conductance of material"; Real TC_1529_1530.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1529_1530.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1529_1530.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1529_1530.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1529_1530.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1529_1530.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1529_1530.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400007278815014 "Constant thermal conductance of material"; Real TC_1529_1538.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1529_1538.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1529_1538.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1529_1538.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1529_1538.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1529_1538.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1529_1538.G(quantity = "ThermalConductance", unit = "W/K") = 0.039999460916441 "Constant thermal conductance of material"; Real TC_1529_1601.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1529_1601.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1529_1601.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1529_1601.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1529_1601.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1529_1601.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1529_1601.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400000000000001 "Constant thermal conductance of material"; Real TC_1529_1657.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1529_1657.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1529_1657.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1529_1657.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1529_1657.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1529_1657.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1529_1657.G(quantity = "ThermalConductance", unit = "W/K") = 0.222221148269851 "Constant thermal conductance of material"; Real TC_1530_1531.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1530_1531.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1530_1531.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1530_1531.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1530_1531.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1530_1531.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1530_1531.G(quantity = "ThermalConductance", unit = "W/K") = 0.04 "Constant thermal conductance of material"; Real TC_1530_1539.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1530_1539.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1530_1539.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1530_1539.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1530_1539.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1530_1539.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1530_1539.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399991321704428 "Constant thermal conductance of material"; Real TC_1530_1602.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1530_1602.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1530_1602.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1530_1602.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1530_1602.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1530_1602.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1530_1602.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400004777317296 "Constant thermal conductance of material"; Real TC_1530_1658.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1530_1658.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1530_1658.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1530_1658.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1530_1658.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1530_1658.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1530_1658.G(quantity = "ThermalConductance", unit = "W/K") = 0.222220297887084 "Constant thermal conductance of material"; Real TC_1531_1532.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1531_1532.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1531_1532.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1531_1532.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1531_1532.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1531_1532.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1531_1532.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399994904848036 "Constant thermal conductance of material"; Real TC_1531_1540.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1531_1540.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1531_1540.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1531_1540.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1531_1540.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1531_1540.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1531_1540.G(quantity = "ThermalConductance", unit = "W/K") = 0.039997477931906 "Constant thermal conductance of material"; Real TC_1531_1603.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1531_1603.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1531_1603.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1531_1603.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1531_1603.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1531_1603.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1531_1603.G(quantity = "ThermalConductance", unit = "W/K") = 0.040000715128545 "Constant thermal conductance of material"; Real TC_1532_1533.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1532_1533.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1532_1533.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1532_1533.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1532_1533.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1532_1533.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1532_1533.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399986362551569 "Constant thermal conductance of material"; Real TC_1532_1541.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1532_1541.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1532_1541.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1532_1541.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1532_1541.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1532_1541.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1532_1541.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400000000000001 "Constant thermal conductance of material"; Real TC_1532_1604.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1532_1604.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1532_1604.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1532_1604.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1532_1604.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1532_1604.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1532_1604.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399961810196706 "Constant thermal conductance of material"; Real TC_1532_1653.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1532_1653.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1532_1653.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1532_1653.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1532_1653.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1532_1653.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1532_1653.G(quantity = "ThermalConductance", unit = "W/K") = 0.222228126106973 "Constant thermal conductance of material"; Real TC_1533_1534.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1533_1534.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1533_1534.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1533_1534.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1533_1534.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1533_1534.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1533_1534.G(quantity = "ThermalConductance", unit = "W/K") = 0.040001384370457 "Constant thermal conductance of material"; Real TC_1533_1542.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1533_1542.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1533_1542.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1533_1542.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1533_1542.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1533_1542.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1533_1542.G(quantity = "ThermalConductance", unit = "W/K") = 0.040000881464995 "Constant thermal conductance of material"; Real TC_1533_1605.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1533_1605.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1533_1605.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1533_1605.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1533_1605.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1533_1605.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1533_1605.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399999999999994 "Constant thermal conductance of material"; Real TC_1533_1654.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1533_1654.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1533_1654.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1533_1654.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1533_1654.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1533_1654.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1533_1654.G(quantity = "ThermalConductance", unit = "W/K") = 0.222217261904763 "Constant thermal conductance of material"; Real TC_1534_1535.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1534_1535.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1534_1535.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1534_1535.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1534_1535.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1534_1535.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1534_1535.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399989244709742 "Constant thermal conductance of material"; Real TC_1534_1543.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1534_1543.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1534_1543.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1534_1543.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1534_1543.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1534_1543.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1534_1543.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399995844414895 "Constant thermal conductance of material"; Real TC_1534_1606.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1534_1606.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1534_1606.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1534_1606.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1534_1606.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1534_1606.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1534_1606.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399984009381149 "Constant thermal conductance of material"; Real TC_1534_1655.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1534_1655.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1534_1655.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1534_1655.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1534_1655.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1534_1655.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1534_1655.G(quantity = "ThermalConductance", unit = "W/K") = 0.222203992343444 "Constant thermal conductance of material"; Real TC_1535_1544.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1535_1544.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1535_1544.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1535_1544.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1535_1544.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1535_1544.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1535_1544.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400011354281988 "Constant thermal conductance of material"; Real TC_1535_1607.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1535_1607.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1535_1607.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1535_1607.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1535_1607.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1535_1607.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1535_1607.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399977471134883 "Constant thermal conductance of material"; Real TC_1536_1537.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1536_1537.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1536_1537.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1536_1537.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1536_1537.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1536_1537.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1536_1537.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399997246430683 "Constant thermal conductance of material"; Real TC_1536_1545.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1536_1545.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1536_1545.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1536_1545.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1536_1545.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1536_1545.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1536_1545.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399987326130351 "Constant thermal conductance of material"; Real TC_1537_1538.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1537_1538.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1537_1538.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1537_1538.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1537_1538.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1537_1538.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1537_1538.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399991732120709 "Constant thermal conductance of material"; Real TC_1537_1546.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1537_1546.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1537_1546.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1537_1546.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1537_1546.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1537_1546.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1537_1546.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400005963562635 "Constant thermal conductance of material"; Real TC_1537_1659.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1537_1659.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1537_1659.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1537_1659.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1537_1659.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1537_1659.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1537_1659.G(quantity = "ThermalConductance", unit = "W/K") = 0.222218835720816 "Constant thermal conductance of material"; Real TC_1538_1539.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1538_1539.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1538_1539.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1538_1539.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1538_1539.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1538_1539.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1538_1539.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400011592858794 "Constant thermal conductance of material"; Real TC_1538_1547.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1538_1547.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1538_1547.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1538_1547.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1538_1547.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1538_1547.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1538_1547.G(quantity = "ThermalConductance", unit = "W/K") = 0.039999439587536 "Constant thermal conductance of material"; Real TC_1538_1660.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1538_1660.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1538_1660.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1538_1660.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1538_1660.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1538_1660.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1538_1660.G(quantity = "ThermalConductance", unit = "W/K") = 0.222213420844184 "Constant thermal conductance of material"; Real TC_1539_1540.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1539_1540.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1539_1540.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1539_1540.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1539_1540.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1539_1540.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1539_1540.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399998136032361 "Constant thermal conductance of material"; Real TC_1539_1548.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1539_1548.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1539_1548.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1539_1548.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1539_1548.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1539_1548.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1539_1548.G(quantity = "ThermalConductance", unit = "W/K") = 0.039998910111441 "Constant thermal conductance of material"; Real TC_1539_1661.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1539_1661.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1539_1661.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1539_1661.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1539_1661.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1539_1661.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1539_1661.G(quantity = "ThermalConductance", unit = "W/K") = 0.222219066553052 "Constant thermal conductance of material"; Real TC_1540_1541.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1540_1541.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1540_1541.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1540_1541.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1540_1541.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1540_1541.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1540_1541.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399996866824368 "Constant thermal conductance of material"; Real TC_1540_1549.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1540_1549.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1540_1549.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1540_1549.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1540_1549.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1540_1549.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1540_1549.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399994768916901 "Constant thermal conductance of material"; Real TC_1541_1542.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1541_1542.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1541_1542.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1541_1542.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1541_1542.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1541_1542.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1541_1542.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400000000000003 "Constant thermal conductance of material"; Real TC_1541_1550.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1541_1550.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1541_1550.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1541_1550.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1541_1550.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1541_1550.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1541_1550.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399999999999999 "Constant thermal conductance of material"; Real TC_1542_1543.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1542_1543.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1542_1543.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1542_1543.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1542_1543.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1542_1543.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1542_1543.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399993679486769 "Constant thermal conductance of material"; Real TC_1542_1551.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1542_1551.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1542_1551.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1542_1551.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1542_1551.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1542_1551.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1542_1551.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400009156670631 "Constant thermal conductance of material"; Real TC_1543_1544.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1543_1544.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1543_1544.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1543_1544.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1543_1544.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1543_1544.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1543_1544.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400000000000003 "Constant thermal conductance of material"; Real TC_1543_1552.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1543_1552.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1543_1552.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1543_1552.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1543_1552.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1543_1552.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1543_1552.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399995371227551 "Constant thermal conductance of material"; Real TC_1544_1553.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1544_1553.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1544_1553.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1544_1553.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1544_1553.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1544_1553.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1544_1553.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399994923600184 "Constant thermal conductance of material"; Real TC_1545_1546.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1545_1546.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1545_1546.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1545_1546.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1545_1546.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1545_1546.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1545_1546.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400002830575877 "Constant thermal conductance of material"; Real TC_1545_1554.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1545_1554.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1545_1554.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1545_1554.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1545_1554.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1545_1554.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1545_1554.G(quantity = "ThermalConductance", unit = "W/K") = 0.0199997290009621 "Constant thermal conductance of material"; Real TC_1546_1547.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1546_1547.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1546_1547.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1546_1547.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1546_1547.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1546_1547.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1546_1547.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399979887369291 "Constant thermal conductance of material"; Real TC_1546_1555.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1546_1555.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1546_1555.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1546_1555.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1546_1555.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1546_1555.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1546_1555.G(quantity = "ThermalConductance", unit = "W/K") = 0.0200002857932191 "Constant thermal conductance of material"; Real TC_1546_1662.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1546_1662.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1546_1662.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1546_1662.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1546_1662.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1546_1662.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1546_1662.G(quantity = "ThermalConductance", unit = "W/K") = 0.222220296386173 "Constant thermal conductance of material"; Real TC_1547_1548.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1547_1548.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1547_1548.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1547_1548.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1547_1548.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1547_1548.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1547_1548.G(quantity = "ThermalConductance", unit = "W/K") = 0.040000563110623 "Constant thermal conductance of material"; Real TC_1547_1556.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1547_1556.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1547_1556.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1547_1556.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1547_1556.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1547_1556.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1547_1556.G(quantity = "ThermalConductance", unit = "W/K") = 0.02 "Constant thermal conductance of material"; Real TC_1547_1663.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1547_1663.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1547_1663.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1547_1663.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1547_1663.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1547_1663.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1547_1663.G(quantity = "ThermalConductance", unit = "W/K") = 0.222218059198199 "Constant thermal conductance of material"; Real TC_1548_1549.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1548_1549.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1548_1549.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1548_1549.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1548_1549.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1548_1549.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1548_1549.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400000000000001 "Constant thermal conductance of material"; Real TC_1548_1557.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1548_1557.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1548_1557.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1548_1557.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1548_1557.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1548_1557.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1548_1557.G(quantity = "ThermalConductance", unit = "W/K") = 0.0199998084814012 "Constant thermal conductance of material"; Real TC_1548_1664.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1548_1664.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1548_1664.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1548_1664.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1548_1664.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1548_1664.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1548_1664.G(quantity = "ThermalConductance", unit = "W/K") = 0.222215904475665 "Constant thermal conductance of material"; Real TC_1549_1550.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1549_1550.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1549_1550.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1549_1550.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1549_1550.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1549_1550.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1549_1550.G(quantity = "ThermalConductance", unit = "W/K") = 0.04 "Constant thermal conductance of material"; Real TC_1549_1558.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1549_1558.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1549_1558.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1549_1558.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1549_1558.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1549_1558.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1549_1558.G(quantity = "ThermalConductance", unit = "W/K") = 0.019999850507527 "Constant thermal conductance of material"; Real TC_1550_1551.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1550_1551.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1550_1551.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1550_1551.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1550_1551.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1550_1551.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1550_1551.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400009000090001 "Constant thermal conductance of material"; Real TC_1550_1559.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1550_1559.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1550_1559.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1550_1559.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1550_1559.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1550_1559.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1550_1559.G(quantity = "ThermalConductance", unit = "W/K") = 0.0200003931088027 "Constant thermal conductance of material"; Real TC_1551_1552.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1551_1552.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1551_1552.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1551_1552.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1551_1552.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1551_1552.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1551_1552.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400006417043669 "Constant thermal conductance of material"; Real TC_1551_1560.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1551_1560.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1551_1560.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1551_1560.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1551_1560.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1551_1560.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1551_1560.G(quantity = "ThermalConductance", unit = "W/K") = 0.0200002261957272 "Constant thermal conductance of material"; Real TC_1552_1553.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1552_1553.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1552_1553.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1552_1553.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1552_1553.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1552_1553.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1552_1553.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399995117664295 "Constant thermal conductance of material"; Real TC_1552_1561.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1552_1561.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1552_1561.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1552_1561.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1552_1561.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1552_1561.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1552_1561.G(quantity = "ThermalConductance", unit = "W/K") = 0.02 "Constant thermal conductance of material"; Real TC_1553_1562.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1553_1562.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1553_1562.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1553_1562.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1553_1562.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1553_1562.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1553_1562.G(quantity = "ThermalConductance", unit = "W/K") = 0.0199999999999999 "Constant thermal conductance of material"; Real TC_1554_1555.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1554_1555.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1554_1555.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1554_1555.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1554_1555.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1554_1555.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1554_1555.G(quantity = "ThermalConductance", unit = "W/K") = 0.119997595286758 "Constant thermal conductance of material"; Real TC_1555_1556.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1555_1556.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1555_1556.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1555_1556.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1555_1556.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1555_1556.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1555_1556.G(quantity = "ThermalConductance", unit = "W/K") = 0.120009240009243 "Constant thermal conductance of material"; Real TC_1556_1557.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1556_1557.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1556_1557.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1556_1557.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1556_1557.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1556_1557.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1556_1557.G(quantity = "ThermalConductance", unit = "W/K") = 0.119996031549182 "Constant thermal conductance of material"; Real TC_1557_1558.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1557_1558.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1557_1558.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1557_1558.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1557_1558.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1557_1558.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1557_1558.G(quantity = "ThermalConductance", unit = "W/K") = 0.12000059243461 "Constant thermal conductance of material"; Real TC_1558_1559.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1558_1559.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1558_1559.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1558_1559.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1558_1559.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1558_1559.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1558_1559.G(quantity = "ThermalConductance", unit = "W/K") = 0.119998857371382 "Constant thermal conductance of material"; Real TC_1559_1560.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1559_1560.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1559_1560.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1559_1560.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1559_1560.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1559_1560.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1559_1560.G(quantity = "ThermalConductance", unit = "W/K") = 0.120000000000001 "Constant thermal conductance of material"; Real TC_1560_1561.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1560_1561.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1560_1561.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1560_1561.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1560_1561.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1560_1561.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1560_1561.G(quantity = "ThermalConductance", unit = "W/K") = 0.120001597252725 "Constant thermal conductance of material"; Real TC_1561_1562.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1561_1562.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1561_1562.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1561_1562.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1561_1562.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1561_1562.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1561_1562.G(quantity = "ThermalConductance", unit = "W/K") = 0.119997714546907 "Constant thermal conductance of material"; Real TC_1563_1564.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1563_1564.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1563_1564.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1563_1564.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1563_1564.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1563_1564.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1563_1564.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560004862630678 "Constant thermal conductance of material"; Real TC_1563_1572.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1563_1572.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1563_1572.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1563_1572.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1563_1572.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1563_1572.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1563_1572.G(quantity = "ThermalConductance", unit = "W/K") = 0.0190471791792715 "Constant thermal conductance of material"; Real TC_1563_1626.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1563_1626.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1563_1626.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1563_1626.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1563_1626.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1563_1626.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1563_1626.G(quantity = "ThermalConductance", unit = "W/K") = 0.028580272822664 "Constant thermal conductance of material"; Real TC_1564_1565.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1564_1565.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1564_1565.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1564_1565.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1564_1565.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1564_1565.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1564_1565.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560022501406341 "Constant thermal conductance of material"; Real TC_1564_1573.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1564_1573.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1564_1573.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1564_1573.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1564_1573.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1564_1573.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1564_1573.G(quantity = "ThermalConductance", unit = "W/K") = 0.0190471478051882 "Constant thermal conductance of material"; Real TC_1564_1627.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1564_1627.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1564_1627.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1564_1627.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1564_1627.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1564_1627.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1564_1627.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285716915148167 "Constant thermal conductance of material"; Real TC_1565_1566.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1565_1566.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1565_1566.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1565_1566.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1565_1566.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1565_1566.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1565_1566.G(quantity = "ThermalConductance", unit = "W/K") = 0.0559981496710539 "Constant thermal conductance of material"; Real TC_1565_1574.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1565_1574.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1565_1574.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1565_1574.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1565_1574.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1565_1574.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1565_1574.G(quantity = "ThermalConductance", unit = "W/K") = 0.0190481098475739 "Constant thermal conductance of material"; Real TC_1565_1628.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1565_1628.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1565_1628.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1565_1628.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1565_1628.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1565_1628.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1565_1628.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285701239399867 "Constant thermal conductance of material"; Real TC_1566_1567.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1566_1567.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1566_1567.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1566_1567.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1566_1567.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1566_1567.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1566_1567.G(quantity = "ThermalConductance", unit = "W/K") = 0.0559984049446713 "Constant thermal conductance of material"; Real TC_1566_1575.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1566_1575.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1566_1575.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1566_1575.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1566_1575.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1566_1575.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1566_1575.G(quantity = "ThermalConductance", unit = "W/K") = 0.0190480814986745 "Constant thermal conductance of material"; Real TC_1566_1629.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1566_1629.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1566_1629.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1566_1629.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1566_1629.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1566_1629.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1566_1629.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285733031134418 "Constant thermal conductance of material"; Real TC_1566_1643.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1566_1643.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1566_1643.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1566_1643.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1566_1643.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1566_1643.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1566_1643.G(quantity = "ThermalConductance", unit = "W/K") = 0.311102106969161 "Constant thermal conductance of material"; Real TC_1567_1568.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1567_1568.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1567_1568.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1567_1568.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1567_1568.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1567_1568.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1567_1568.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560010155564792 "Constant thermal conductance of material"; Real TC_1567_1576.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1567_1576.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1567_1576.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1567_1576.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1567_1576.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1567_1576.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1567_1576.G(quantity = "ThermalConductance", unit = "W/K") = 0.0190477166516358 "Constant thermal conductance of material"; Real TC_1567_1630.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1567_1630.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1567_1630.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1567_1630.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1567_1630.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1567_1630.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1567_1630.G(quantity = "ThermalConductance", unit = "W/K") = 0.028569164265129 "Constant thermal conductance of material"; Real TC_1567_1644.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1567_1644.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1567_1644.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1567_1644.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1567_1644.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1567_1644.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1567_1644.G(quantity = "ThermalConductance", unit = "W/K") = 0.311111111111067 "Constant thermal conductance of material"; Real TC_1568_1569.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1568_1569.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1568_1569.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1568_1569.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1568_1569.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1568_1569.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1568_1569.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560000984833563 "Constant thermal conductance of material"; Real TC_1568_1577.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1568_1577.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1568_1577.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1568_1577.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1568_1577.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1568_1577.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1568_1577.G(quantity = "ThermalConductance", unit = "W/K") = 0.0190483351881372 "Constant thermal conductance of material"; Real TC_1568_1631.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1568_1631.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1568_1631.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1568_1631.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1568_1631.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1568_1631.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1568_1631.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285690247252758 "Constant thermal conductance of material"; Real TC_1568_1645.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1568_1645.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1568_1645.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1568_1645.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1568_1645.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1568_1645.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1568_1645.G(quantity = "ThermalConductance", unit = "W/K") = 0.311151252408489 "Constant thermal conductance of material"; Real TC_1569_1570.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1569_1570.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1569_1570.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1569_1570.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1569_1570.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1569_1570.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1569_1570.G(quantity = "ThermalConductance", unit = "W/K") = 0.0559989045020747 "Constant thermal conductance of material"; Real TC_1569_1578.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1569_1578.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1569_1578.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1569_1578.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1569_1578.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1569_1578.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1569_1578.G(quantity = "ThermalConductance", unit = "W/K") = 0.0190476532395106 "Constant thermal conductance of material"; Real TC_1569_1632.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1569_1632.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1569_1632.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1569_1632.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1569_1632.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1569_1632.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1569_1632.G(quantity = "ThermalConductance", unit = "W/K") = 0.028559541604389 "Constant thermal conductance of material"; Real TC_1569_1646.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1569_1646.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1569_1646.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1569_1646.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1569_1646.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1569_1646.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1569_1646.G(quantity = "ThermalConductance", unit = "W/K") = 0.311183110367888 "Constant thermal conductance of material"; Real TC_1570_1571.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1570_1571.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1570_1571.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1570_1571.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1570_1571.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1570_1571.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1570_1571.G(quantity = "ThermalConductance", unit = "W/K") = 0.0559996966019431 "Constant thermal conductance of material"; Real TC_1570_1579.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1570_1579.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1570_1579.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1570_1579.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1570_1579.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1570_1579.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1570_1579.G(quantity = "ThermalConductance", unit = "W/K") = 0.0190480259784658 "Constant thermal conductance of material"; Real TC_1570_1633.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1570_1633.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1570_1633.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1570_1633.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1570_1633.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1570_1633.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1570_1633.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285686627022563 "Constant thermal conductance of material"; Real TC_1571_1580.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1571_1580.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1571_1580.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1571_1580.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1571_1580.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1571_1580.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1571_1580.G(quantity = "ThermalConductance", unit = "W/K") = 0.0190472160356475 "Constant thermal conductance of material"; Real TC_1571_1634.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1571_1634.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1571_1634.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1571_1634.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1571_1634.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1571_1634.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1571_1634.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285719956336199 "Constant thermal conductance of material"; Real TC_1572_1573.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1572_1573.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1572_1573.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1572_1573.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1572_1573.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1572_1573.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1572_1573.G(quantity = "ThermalConductance", unit = "W/K") = 0.111994451744779 "Constant thermal conductance of material"; Real TC_1572_1581.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1572_1581.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1572_1581.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1572_1581.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1572_1581.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1572_1581.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1572_1581.G(quantity = "ThermalConductance", unit = "W/K") = 0.0210524205098826 "Constant thermal conductance of material"; Real TC_1573_1574.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1573_1574.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1573_1574.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1573_1574.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1573_1574.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1573_1574.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1573_1574.G(quantity = "ThermalConductance", unit = "W/K") = 0.112005159241984 "Constant thermal conductance of material"; Real TC_1573_1582.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1573_1582.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1573_1582.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1573_1582.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1573_1582.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1573_1582.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1573_1582.G(quantity = "ThermalConductance", unit = "W/K") = 0.0210525835866261 "Constant thermal conductance of material"; Real TC_1574_1575.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1574_1575.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1574_1575.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1574_1575.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1574_1575.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1574_1575.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1574_1575.G(quantity = "ThermalConductance", unit = "W/K") = 0.111986337362055 "Constant thermal conductance of material"; Real TC_1574_1583.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1574_1583.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1574_1583.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1574_1583.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1574_1583.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1574_1583.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1574_1583.G(quantity = "ThermalConductance", unit = "W/K") = 0.0210528460806954 "Constant thermal conductance of material"; Real TC_1575_1576.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1575_1576.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1575_1576.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1575_1576.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1575_1576.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1575_1576.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1575_1576.G(quantity = "ThermalConductance", unit = "W/K") = 0.112008196721312 "Constant thermal conductance of material"; Real TC_1575_1584.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1575_1584.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1575_1584.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1575_1584.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1575_1584.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1575_1584.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1575_1584.G(quantity = "ThermalConductance", unit = "W/K") = 0.0210529223726275 "Constant thermal conductance of material"; Real TC_1576_1577.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1576_1577.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1576_1577.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1576_1577.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1576_1577.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1576_1577.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1576_1577.G(quantity = "ThermalConductance", unit = "W/K") = 0.111997713165628 "Constant thermal conductance of material"; Real TC_1576_1585.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1576_1585.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1576_1585.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1576_1585.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1576_1585.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1576_1585.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1576_1585.G(quantity = "ThermalConductance", unit = "W/K") = 0.0210528889251083 "Constant thermal conductance of material"; Real TC_1577_1578.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1577_1578.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1577_1578.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1577_1578.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1577_1578.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1577_1578.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1577_1578.G(quantity = "ThermalConductance", unit = "W/K") = 0.112004024397911 "Constant thermal conductance of material"; Real TC_1577_1586.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1577_1586.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1577_1586.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1577_1586.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1577_1586.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1577_1586.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1577_1586.G(quantity = "ThermalConductance", unit = "W/K") = 0.0210528224742811 "Constant thermal conductance of material"; Real TC_1578_1579.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1578_1579.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1578_1579.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1578_1579.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1578_1579.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1578_1579.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1578_1579.G(quantity = "ThermalConductance", unit = "W/K") = 0.111996779388086 "Constant thermal conductance of material"; Real TC_1578_1587.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1578_1587.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1578_1587.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1578_1587.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1578_1587.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1578_1587.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1578_1587.G(quantity = "ThermalConductance", unit = "W/K") = 0.0210531271682027 "Constant thermal conductance of material"; Real TC_1579_1580.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1579_1580.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1579_1580.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1579_1580.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1579_1580.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1579_1580.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1579_1580.G(quantity = "ThermalConductance", unit = "W/K") = 0.111992684813955 "Constant thermal conductance of material"; Real TC_1579_1588.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1579_1588.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1579_1588.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1579_1588.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1579_1588.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1579_1588.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1579_1588.G(quantity = "ThermalConductance", unit = "W/K") = 0.0210531818181819 "Constant thermal conductance of material"; Real TC_1580_1589.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1580_1589.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1580_1589.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1580_1589.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1580_1589.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1580_1589.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1580_1589.G(quantity = "ThermalConductance", unit = "W/K") = 0.0210523368149871 "Constant thermal conductance of material"; Real TC_1581_1582.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1581_1582.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1581_1582.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1581_1582.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1581_1582.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1581_1582.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1581_1582.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399982888432574 "Constant thermal conductance of material"; Real TC_1581_1590.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1581_1590.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1581_1590.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1581_1590.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1581_1590.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1581_1590.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1581_1590.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399982648428236 "Constant thermal conductance of material"; Real TC_1582_1583.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1582_1583.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1582_1583.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1582_1583.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1582_1583.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1582_1583.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1582_1583.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400045296693314 "Constant thermal conductance of material"; Real TC_1582_1591.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1582_1591.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1582_1591.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1582_1591.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1582_1591.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1582_1591.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1582_1591.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400005394907209 "Constant thermal conductance of material"; Real TC_1583_1584.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1583_1584.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1583_1584.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1583_1584.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1583_1584.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1583_1584.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1583_1584.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400100334447619 "Constant thermal conductance of material"; Real TC_1583_1592.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1583_1592.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1583_1592.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1583_1592.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1583_1592.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1583_1592.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1583_1592.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400010941218307 "Constant thermal conductance of material"; Real TC_1584_1585.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1584_1585.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1584_1585.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1584_1585.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1584_1585.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1584_1585.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1584_1585.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400055218111539 "Constant thermal conductance of material"; Real TC_1584_1593.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1584_1593.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1584_1593.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1584_1593.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1584_1593.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1584_1593.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1584_1593.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399987603049651 "Constant thermal conductance of material"; Real TC_1585_1586.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1585_1586.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1585_1586.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1585_1586.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1585_1586.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1585_1586.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1585_1586.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399969030659651 "Constant thermal conductance of material"; Real TC_1585_1594.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1585_1594.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1585_1594.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1585_1594.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1585_1594.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1585_1594.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1585_1594.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400022139404444 "Constant thermal conductance of material"; Real TC_1586_1587.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1586_1587.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1586_1587.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1586_1587.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1586_1587.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1586_1587.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1586_1587.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400000000000025 "Constant thermal conductance of material"; Real TC_1586_1595.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1586_1595.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1586_1595.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1586_1595.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1586_1595.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1586_1595.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1586_1595.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399987543209495 "Constant thermal conductance of material"; Real TC_1587_1588.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1587_1588.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1587_1588.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1587_1588.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1587_1588.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1587_1588.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1587_1588.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399985448195561 "Constant thermal conductance of material"; Real TC_1587_1596.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1587_1596.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1587_1596.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1587_1596.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1587_1596.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1587_1596.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1587_1596.G(quantity = "ThermalConductance", unit = "W/K") = 0.04000062496094 "Constant thermal conductance of material"; Real TC_1588_1589.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1588_1589.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1588_1589.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1588_1589.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1588_1589.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1588_1589.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1588_1589.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400013329778727 "Constant thermal conductance of material"; Real TC_1588_1597.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1588_1597.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1588_1597.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1588_1597.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1588_1597.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1588_1597.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1588_1597.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399972548212199 "Constant thermal conductance of material"; Real TC_1589_1598.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1589_1598.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1589_1598.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1589_1598.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1589_1598.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1589_1598.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1589_1598.G(quantity = "ThermalConductance", unit = "W/K") = 0.039999393571861 "Constant thermal conductance of material"; Real TC_1590_1591.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1590_1591.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1590_1591.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1590_1591.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1590_1591.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1590_1591.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1590_1591.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399992948311122 "Constant thermal conductance of material"; Real TC_1590_1599.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1590_1599.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1590_1599.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1590_1599.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1590_1599.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1590_1599.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1590_1599.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399991766328399 "Constant thermal conductance of material"; Real TC_1591_1592.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1591_1592.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1591_1592.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1591_1592.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1591_1592.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1591_1592.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1591_1592.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400049099836313 "Constant thermal conductance of material"; Real TC_1591_1600.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1591_1600.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1591_1600.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1591_1600.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1591_1600.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1591_1600.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1591_1600.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400003331001632 "Constant thermal conductance of material"; Real TC_1592_1593.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1592_1593.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1592_1593.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1592_1593.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1592_1593.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1592_1593.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1592_1593.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400043554006948 "Constant thermal conductance of material"; Real TC_1592_1601.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1592_1601.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1592_1601.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1592_1601.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1592_1601.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1592_1601.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1592_1601.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400000000000001 "Constant thermal conductance of material"; Real TC_1593_1594.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1593_1594.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1593_1594.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1593_1594.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1593_1594.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1593_1594.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1593_1594.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399981128514832 "Constant thermal conductance of material"; Real TC_1593_1602.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1593_1602.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1593_1602.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1593_1602.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1593_1602.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1593_1602.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1593_1602.G(quantity = "ThermalConductance", unit = "W/K") = 0.039999232996491 "Constant thermal conductance of material"; Real TC_1594_1595.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1594_1595.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1594_1595.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1594_1595.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1594_1595.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1594_1595.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1594_1595.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400013812154529 "Constant thermal conductance of material"; Real TC_1594_1603.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1594_1603.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1594_1603.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1594_1603.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1594_1603.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1594_1603.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1594_1603.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399986956238178 "Constant thermal conductance of material"; Real TC_1595_1596.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1595_1596.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1595_1596.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1595_1596.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1595_1596.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1595_1596.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1595_1596.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400000000000039 "Constant thermal conductance of material"; Real TC_1595_1604.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1595_1604.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1595_1604.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1595_1604.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1595_1604.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1595_1604.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1595_1604.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399999999999985 "Constant thermal conductance of material"; Real TC_1595_1647.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1595_1647.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1595_1647.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1595_1647.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1595_1647.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1595_1647.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1595_1647.G(quantity = "ThermalConductance", unit = "W/K") = 0.222222222222199 "Constant thermal conductance of material"; Real TC_1596_1597.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1596_1597.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1596_1597.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1596_1597.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1596_1597.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1596_1597.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1596_1597.G(quantity = "ThermalConductance", unit = "W/K") = 0.040000602264514 "Constant thermal conductance of material"; Real TC_1596_1605.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1596_1605.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1596_1605.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1596_1605.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1596_1605.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1596_1605.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1596_1605.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400000000000003 "Constant thermal conductance of material"; Real TC_1596_1648.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1596_1648.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1596_1648.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1596_1648.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1596_1648.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1596_1648.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1596_1648.G(quantity = "ThermalConductance", unit = "W/K") = 0.222210150551005 "Constant thermal conductance of material"; Real TC_1597_1598.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1597_1598.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1597_1598.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1597_1598.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1597_1598.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1597_1598.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1597_1598.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399994311394279 "Constant thermal conductance of material"; Real TC_1597_1606.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1597_1606.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1597_1606.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1597_1606.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1597_1606.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1597_1606.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1597_1606.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399974696356244 "Constant thermal conductance of material"; Real TC_1597_1649.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1597_1649.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1597_1649.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1597_1649.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1597_1649.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1597_1649.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1597_1649.G(quantity = "ThermalConductance", unit = "W/K") = 0.222202380952382 "Constant thermal conductance of material"; Real TC_1598_1607.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1598_1607.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1598_1607.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1598_1607.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1598_1607.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1598_1607.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1598_1607.G(quantity = "ThermalConductance", unit = "W/K") = 0.039993428258493 "Constant thermal conductance of material"; Real TC_1599_1600.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1599_1600.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1599_1600.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1599_1600.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1599_1600.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1599_1600.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1599_1600.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400007799703614 "Constant thermal conductance of material"; Real TC_1600_1601.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1600_1601.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1600_1601.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1600_1601.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1600_1601.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1600_1601.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1600_1601.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399986916132398 "Constant thermal conductance of material"; Real TC_1601_1602.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1601_1602.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1601_1602.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1601_1602.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1601_1602.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1601_1602.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1601_1602.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400007134703192 "Constant thermal conductance of material"; Real TC_1602_1603.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1602_1603.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1602_1603.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1602_1603.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1602_1603.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1602_1603.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1602_1603.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399993766169007 "Constant thermal conductance of material"; Real TC_1603_1604.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1603_1604.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1603_1604.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1603_1604.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1603_1604.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1603_1604.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1603_1604.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399987895660592 "Constant thermal conductance of material"; Real TC_1604_1605.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1604_1605.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1604_1605.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1604_1605.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1604_1605.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1604_1605.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1604_1605.G(quantity = "ThermalConductance", unit = "W/K") = 0.0399999999999999 "Constant thermal conductance of material"; Real TC_1604_1650.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1604_1650.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1604_1650.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1604_1650.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1604_1650.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1604_1650.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1604_1650.G(quantity = "ThermalConductance", unit = "W/K") = 0.222214809873261 "Constant thermal conductance of material"; Real TC_1605_1606.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1605_1606.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1605_1606.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1605_1606.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1605_1606.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1605_1606.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1605_1606.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400014339658718 "Constant thermal conductance of material"; Real TC_1605_1651.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1605_1651.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1605_1651.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1605_1651.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1605_1651.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1605_1651.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1605_1651.G(quantity = "ThermalConductance", unit = "W/K") = 0.222227714615254 "Constant thermal conductance of material"; Real TC_1606_1607.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1606_1607.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1606_1607.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1606_1607.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1606_1607.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1606_1607.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1606_1607.G(quantity = "ThermalConductance", unit = "W/K") = 0.0400005236013297 "Constant thermal conductance of material"; Real TC_1606_1652.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1606_1652.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1606_1652.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1606_1652.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1606_1652.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1606_1652.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1606_1652.G(quantity = "ThermalConductance", unit = "W/K") = 0.222243078366967 "Constant thermal conductance of material"; Real TC_1608_1609.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1608_1609.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1608_1609.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1608_1609.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1608_1609.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1608_1609.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1608_1609.G(quantity = "ThermalConductance", unit = "W/K") = 0.0800052913552485 "Constant thermal conductance of material"; Real TC_1608_1617.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1608_1617.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1608_1617.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1608_1617.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1608_1617.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1608_1617.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1608_1617.G(quantity = "ThermalConductance", unit = "W/K") = 0.0235299619629606 "Constant thermal conductance of material"; Real TC_1609_1610.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1609_1610.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1609_1610.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1609_1610.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1609_1610.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1609_1610.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1609_1610.G(quantity = "ThermalConductance", unit = "W/K") = 0.0799975056123736 "Constant thermal conductance of material"; Real TC_1609_1618.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1609_1618.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1609_1618.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1609_1618.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1609_1618.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1609_1618.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1609_1618.G(quantity = "ThermalConductance", unit = "W/K") = 0.0235293464378922 "Constant thermal conductance of material"; Real TC_1610_1611.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1610_1611.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1610_1611.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1610_1611.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1610_1611.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1610_1611.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1610_1611.G(quantity = "ThermalConductance", unit = "W/K") = 0.0800125062531268 "Constant thermal conductance of material"; Real TC_1610_1619.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1610_1619.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1610_1619.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1610_1619.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1610_1619.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1610_1619.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1610_1619.G(quantity = "ThermalConductance", unit = "W/K") = 0.0235289606380735 "Constant thermal conductance of material"; Real TC_1611_1612.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1611_1612.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1611_1612.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1611_1612.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1611_1612.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1611_1612.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1611_1612.G(quantity = "ThermalConductance", unit = "W/K") = 0.0800056727932874 "Constant thermal conductance of material"; Real TC_1611_1620.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1611_1620.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1611_1620.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1611_1620.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1611_1620.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1611_1620.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1611_1620.G(quantity = "ThermalConductance", unit = "W/K") = 0.0235295597273345 "Constant thermal conductance of material"; Real TC_1612_1613.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1612_1613.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1612_1613.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1612_1613.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1612_1613.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1612_1613.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1612_1613.G(quantity = "ThermalConductance", unit = "W/K") = 0.0799990509632718 "Constant thermal conductance of material"; Real TC_1612_1621.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1612_1621.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1612_1621.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1612_1621.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1612_1621.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1612_1621.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1612_1621.G(quantity = "ThermalConductance", unit = "W/K") = 0.0235294117647059 "Constant thermal conductance of material"; Real TC_1613_1614.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1613_1614.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1613_1614.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1613_1614.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1613_1614.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1613_1614.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1613_1614.G(quantity = "ThermalConductance", unit = "W/K") = 0.0800015251458418 "Constant thermal conductance of material"; Real TC_1613_1622.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1613_1622.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1613_1622.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1613_1622.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1613_1622.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1613_1622.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1613_1622.G(quantity = "ThermalConductance", unit = "W/K") = 0.0235290303056504 "Constant thermal conductance of material"; Real TC_1614_1615.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1614_1615.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1614_1615.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1614_1615.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1614_1615.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1614_1615.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1614_1615.G(quantity = "ThermalConductance", unit = "W/K") = 0.079998490736899 "Constant thermal conductance of material"; Real TC_1614_1623.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1614_1623.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1614_1623.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1614_1623.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1614_1623.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1614_1623.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1614_1623.G(quantity = "ThermalConductance", unit = "W/K") = 0.0235301863190466 "Constant thermal conductance of material"; Real TC_1615_1616.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1615_1616.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1615_1616.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1615_1616.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1615_1616.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1615_1616.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1615_1616.G(quantity = "ThermalConductance", unit = "W/K") = 0.079997927783246 "Constant thermal conductance of material"; Real TC_1615_1624.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1615_1624.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1615_1624.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1615_1624.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1615_1624.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1615_1624.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1615_1624.G(quantity = "ThermalConductance", unit = "W/K") = 0.023529411764706 "Constant thermal conductance of material"; Real TC_1616_1625.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1616_1625.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1616_1625.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1616_1625.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1616_1625.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1616_1625.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1616_1625.G(quantity = "ThermalConductance", unit = "W/K") = 0.0235284813701789 "Constant thermal conductance of material"; Real TC_1617_1618.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1617_1618.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1617_1618.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1617_1618.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1617_1618.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1617_1618.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1617_1618.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560000975229182 "Constant thermal conductance of material"; Real TC_1617_1626.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1617_1626.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1617_1626.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1617_1626.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1617_1626.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1617_1626.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1617_1626.G(quantity = "ThermalConductance", unit = "W/K") = 0.028571531040419 "Constant thermal conductance of material"; Real TC_1618_1619.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1618_1619.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1618_1619.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1618_1619.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1618_1619.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1618_1619.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1618_1619.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560009126863402 "Constant thermal conductance of material"; Real TC_1618_1627.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1618_1627.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1618_1627.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1618_1627.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1618_1627.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1618_1627.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1618_1627.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285711949232929 "Constant thermal conductance of material"; Real TC_1619_1620.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1619_1620.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1619_1620.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1619_1620.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1619_1620.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1619_1620.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1619_1620.G(quantity = "ThermalConductance", unit = "W/K") = 0.0559970450108178 "Constant thermal conductance of material"; Real TC_1619_1628.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1619_1628.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1619_1628.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1619_1628.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1619_1628.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1619_1628.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1619_1628.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285713855058479 "Constant thermal conductance of material"; Real TC_1620_1621.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1620_1621.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1620_1621.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1620_1621.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1620_1621.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1620_1621.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1620_1621.G(quantity = "ThermalConductance", unit = "W/K") = 0.0559982206405725 "Constant thermal conductance of material"; Real TC_1620_1629.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1620_1629.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1620_1629.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1620_1629.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1620_1629.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1620_1629.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1620_1629.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285718854484658 "Constant thermal conductance of material"; Real TC_1620_1635.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1620_1635.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1620_1635.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1620_1635.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1620_1635.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1620_1635.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1620_1635.G(quantity = "ThermalConductance", unit = "W/K") = 0.311153552330008 "Constant thermal conductance of material"; Real TC_1621_1622.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1621_1622.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1621_1622.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1621_1622.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1621_1622.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1621_1622.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1621_1622.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560000881231962 "Constant thermal conductance of material"; Real TC_1621_1630.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1621_1630.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1621_1630.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1621_1630.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1621_1630.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1621_1630.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1621_1630.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285708849272566 "Constant thermal conductance of material"; Real TC_1621_1636.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1621_1636.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1621_1636.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1621_1636.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1621_1636.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1621_1636.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1621_1636.G(quantity = "ThermalConductance", unit = "W/K") = 0.311068175545161 "Constant thermal conductance of material"; Real TC_1622_1623.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1622_1623.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1622_1623.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1622_1623.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1622_1623.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1622_1623.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1622_1623.G(quantity = "ThermalConductance", unit = "W/K") = 0.0559991589964021 "Constant thermal conductance of material"; Real TC_1622_1631.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1622_1631.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1622_1631.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1622_1631.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1622_1631.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1622_1631.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1622_1631.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285713398347727 "Constant thermal conductance of material"; Real TC_1622_1637.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1622_1637.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1622_1637.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1622_1637.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1622_1637.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1622_1637.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1622_1637.G(quantity = "ThermalConductance", unit = "W/K") = 0.311098604232361 "Constant thermal conductance of material"; Real TC_1623_1624.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1623_1624.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1623_1624.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1623_1624.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1623_1624.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1623_1624.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1623_1624.G(quantity = "ThermalConductance", unit = "W/K") = 0.056 "Constant thermal conductance of material"; Real TC_1623_1632.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1623_1632.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1623_1632.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1623_1632.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1623_1632.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1623_1632.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1623_1632.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285713800943362 "Constant thermal conductance of material"; Real TC_1623_1638.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1623_1638.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1623_1638.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1623_1638.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1623_1638.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1623_1638.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1623_1638.G(quantity = "ThermalConductance", unit = "W/K") = 0.311087378640794 "Constant thermal conductance of material"; Real TC_1624_1625.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1624_1625.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1624_1625.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1624_1625.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1624_1625.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1624_1625.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1624_1625.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560013022717405 "Constant thermal conductance of material"; Real TC_1624_1633.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1624_1633.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1624_1633.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1624_1633.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1624_1633.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1624_1633.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1624_1633.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285725552050471 "Constant thermal conductance of material"; Real TC_1625_1634.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1625_1634.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1625_1634.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1625_1634.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1625_1634.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1625_1634.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1625_1634.G(quantity = "ThermalConductance", unit = "W/K") = 0.0285717136243915 "Constant thermal conductance of material"; Real TC_1626_1627.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1626_1627.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1626_1627.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1626_1627.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1626_1627.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1626_1627.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1626_1627.G(quantity = "ThermalConductance", unit = "W/K") = 0.0559994508511803 "Constant thermal conductance of material"; Real TC_1627_1628.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1627_1628.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1627_1628.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1627_1628.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1627_1628.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1627_1628.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1627_1628.G(quantity = "ThermalConductance", unit = "W/K") = 0.0559988926186111 "Constant thermal conductance of material"; Real TC_1628_1629.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1628_1629.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1628_1629.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1628_1629.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1628_1629.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1628_1629.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1628_1629.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560027758501038 "Constant thermal conductance of material"; Real TC_1629_1630.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1629_1630.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1629_1630.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1629_1630.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1629_1630.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1629_1630.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1629_1630.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560048805996142 "Constant thermal conductance of material"; Real TC_1629_1639.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1629_1639.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1629_1639.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1629_1639.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1629_1639.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1629_1639.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1629_1639.G(quantity = "ThermalConductance", unit = "W/K") = 0.31113751584285 "Constant thermal conductance of material"; Real TC_1630_1631.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1630_1631.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1630_1631.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1630_1631.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1630_1631.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1630_1631.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1630_1631.G(quantity = "ThermalConductance", unit = "W/K") = 0.0559994931790345 "Constant thermal conductance of material"; Real TC_1630_1640.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1630_1640.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1630_1640.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1630_1640.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1630_1640.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1630_1640.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1630_1640.G(quantity = "ThermalConductance", unit = "W/K") = 0.311175851175874 "Constant thermal conductance of material"; Real TC_1631_1632.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1631_1632.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1631_1632.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1631_1632.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1631_1632.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1631_1632.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1631_1632.G(quantity = "ThermalConductance", unit = "W/K") = 0.0559986823322724 "Constant thermal conductance of material"; Real TC_1631_1641.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1631_1641.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1631_1641.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1631_1641.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1631_1641.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1631_1641.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1631_1641.G(quantity = "ThermalConductance", unit = "W/K") = 0.311152317880773 "Constant thermal conductance of material"; Real TC_1632_1633.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1632_1633.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1632_1633.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1632_1633.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1632_1633.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1632_1633.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1632_1633.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560000759142927 "Constant thermal conductance of material"; Real TC_1632_1642.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1632_1642.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1632_1642.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1632_1642.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1632_1642.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1632_1642.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1632_1642.G(quantity = "ThermalConductance", unit = "W/K") = 0.311070585711261 "Constant thermal conductance of material"; Real TC_1633_1634.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1633_1634.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1633_1634.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1633_1634.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1633_1634.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1633_1634.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1633_1634.G(quantity = "ThermalConductance", unit = "W/K") = 0.0560005476826173 "Constant thermal conductance of material"; Real TC_1635_1636.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1635_1636.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1635_1636.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1635_1636.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1635_1636.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1635_1636.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1635_1636.G(quantity = "ThermalConductance", unit = "W/K") = 0.00700051975051978 "Constant thermal conductance of material"; Real TC_1635_1639.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1635_1639.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1635_1639.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1635_1639.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1635_1639.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1635_1639.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1635_1639.G(quantity = "ThermalConductance", unit = "W/K") = 0.0035715560314061 "Constant thermal conductance of material"; Real TC_1636_1637.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1636_1637.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1636_1637.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1636_1637.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1636_1637.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1636_1637.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1636_1637.G(quantity = "ThermalConductance", unit = "W/K") = 0.00699991025756078 "Constant thermal conductance of material"; Real TC_1636_1640.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1636_1640.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1636_1640.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1636_1640.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1636_1640.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1636_1640.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1636_1640.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357144996555548 "Constant thermal conductance of material"; Real TC_1637_1638.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1637_1638.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1637_1638.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1637_1638.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1637_1638.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1637_1638.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1637_1638.G(quantity = "ThermalConductance", unit = "W/K") = 0.00699985747541451 "Constant thermal conductance of material"; Real TC_1637_1641.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1637_1641.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1637_1641.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1637_1641.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1637_1641.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1637_1641.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1637_1641.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357140591798543 "Constant thermal conductance of material"; Real TC_1638_1642.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1638_1642.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1638_1642.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1638_1642.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1638_1642.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1638_1642.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1638_1642.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357142857142858 "Constant thermal conductance of material"; Real TC_1639_1640.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1639_1640.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1639_1640.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1639_1640.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1639_1640.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1639_1640.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1639_1640.G(quantity = "ThermalConductance", unit = "W/K") = 0.00700042441218878 "Constant thermal conductance of material"; Real TC_1639_1643.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1639_1643.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1639_1643.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1639_1643.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1639_1643.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1639_1643.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1639_1643.G(quantity = "ThermalConductance", unit = "W/K") = 0.003571902513717 "Constant thermal conductance of material"; Real TC_1640_1641.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1640_1641.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1640_1641.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1640_1641.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1640_1641.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1640_1641.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1640_1641.G(quantity = "ThermalConductance", unit = "W/K") = 0.00700008615490659 "Constant thermal conductance of material"; Real TC_1640_1644.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1640_1644.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1640_1644.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1640_1644.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1640_1644.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1640_1644.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1640_1644.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357140629872184 "Constant thermal conductance of material"; Real TC_1641_1642.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1641_1642.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1641_1642.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1641_1642.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1641_1642.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1641_1642.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1641_1642.G(quantity = "ThermalConductance", unit = "W/K") = 0.00699993280924538 "Constant thermal conductance of material"; Real TC_1641_1645.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1641_1645.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1641_1645.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1641_1645.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1641_1645.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1641_1645.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1641_1645.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357069033530528 "Constant thermal conductance of material"; Real TC_1642_1646.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1642_1646.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1642_1646.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1642_1646.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1642_1646.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1642_1646.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1642_1646.G(quantity = "ThermalConductance", unit = "W/K") = 0.00357291079812145 "Constant thermal conductance of material"; Real TC_1643_1644.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1643_1644.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1643_1644.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1643_1644.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1643_1644.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1643_1644.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1643_1644.G(quantity = "ThermalConductance", unit = "W/K") = 0.00699980691253132 "Constant thermal conductance of material"; Real TC_1644_1645.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1644_1645.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1644_1645.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1644_1645.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1644_1645.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1644_1645.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1644_1645.G(quantity = "ThermalConductance", unit = "W/K") = 0.00699992949305501 "Constant thermal conductance of material"; Real TC_1645_1646.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1645_1646.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1645_1646.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1645_1646.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1645_1646.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1645_1646.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1645_1646.G(quantity = "ThermalConductance", unit = "W/K") = 0.00700005002000805 "Constant thermal conductance of material"; Real TC_1647_1648.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1647_1648.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1647_1648.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1647_1648.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1647_1648.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1647_1648.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1647_1648.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500032679738508 "Constant thermal conductance of material"; Real TC_1647_1650.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1647_1650.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1647_1650.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1647_1650.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1647_1650.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1647_1650.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1647_1650.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500006663113021 "Constant thermal conductance of material"; Real TC_1648_1649.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1648_1649.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1648_1649.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1648_1649.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1648_1649.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1648_1649.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1648_1649.G(quantity = "ThermalConductance", unit = "W/K") = 0.0050000612482392 "Constant thermal conductance of material"; Real TC_1648_1651.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1648_1651.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1648_1651.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1648_1651.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1648_1651.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1648_1651.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1648_1651.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500037998733337 "Constant thermal conductance of material"; Real TC_1649_1652.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1649_1652.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1649_1652.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1649_1652.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1649_1652.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1649_1652.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1649_1652.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500055172413758 "Constant thermal conductance of material"; Real TC_1650_1651.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1650_1651.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1650_1651.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1650_1651.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1650_1651.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1650_1651.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1650_1651.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499992443134603 "Constant thermal conductance of material"; Real TC_1650_1653.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1650_1653.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1650_1653.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1650_1653.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1650_1653.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1650_1653.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1650_1653.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499959075097188 "Constant thermal conductance of material"; Real TC_1651_1652.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1651_1652.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1651_1652.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1651_1652.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1651_1652.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1651_1652.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1651_1652.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500024275379908 "Constant thermal conductance of material"; Real TC_1651_1654.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1651_1654.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1651_1654.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1651_1654.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1651_1654.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1651_1654.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1651_1654.G(quantity = "ThermalConductance", unit = "W/K") = 0.0050000986485152 "Constant thermal conductance of material"; Real TC_1652_1655.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1652_1655.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1652_1655.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1652_1655.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1652_1655.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1652_1655.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1652_1655.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500005605381156 "Constant thermal conductance of material"; Real TC_1653_1654.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1653_1654.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1653_1654.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1653_1654.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1653_1654.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1653_1654.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1653_1654.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499982305269491 "Constant thermal conductance of material"; Real TC_1654_1655.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1654_1655.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1654_1655.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1654_1655.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1654_1655.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1654_1655.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1654_1655.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499999999999998 "Constant thermal conductance of material"; Real TC_1656_1657.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1656_1657.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1656_1657.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1656_1657.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1656_1657.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1656_1657.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1656_1657.G(quantity = "ThermalConductance", unit = "W/K") = 0.0050001757160427 "Constant thermal conductance of material"; Real TC_1656_1659.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1656_1659.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1656_1659.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1656_1659.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1656_1659.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1656_1659.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1656_1659.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499999999999991 "Constant thermal conductance of material"; Real TC_1657_1658.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1657_1658.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1657_1658.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1657_1658.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1657_1658.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1657_1658.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1657_1658.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499980970504274 "Constant thermal conductance of material"; Real TC_1657_1660.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1657_1660.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1657_1660.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1657_1660.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1657_1660.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1657_1660.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1657_1660.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499988263599563 "Constant thermal conductance of material"; Real TC_1658_1661.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1658_1661.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1658_1661.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1658_1661.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1658_1661.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1658_1661.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1658_1661.G(quantity = "ThermalConductance", unit = "W/K") = 0.0049999051053329 "Constant thermal conductance of material"; Real TC_1659_1660.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1659_1660.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1659_1660.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1659_1660.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1659_1660.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1659_1660.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1659_1660.G(quantity = "ThermalConductance", unit = "W/K") = 0.0050000000000001 "Constant thermal conductance of material"; Real TC_1659_1662.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1659_1662.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1659_1662.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1659_1662.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1659_1662.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1659_1662.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1659_1662.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499984296975597 "Constant thermal conductance of material"; Real TC_1660_1661.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1660_1661.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1660_1661.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1660_1661.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1660_1661.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1660_1661.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1660_1661.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500000000000004 "Constant thermal conductance of material"; Real TC_1660_1663.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1660_1663.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1660_1663.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1660_1663.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1660_1663.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1660_1663.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1660_1663.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499985228514875 "Constant thermal conductance of material"; Real TC_1661_1664.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1661_1664.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1661_1664.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1661_1664.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1661_1664.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1661_1664.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1661_1664.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500014304923753 "Constant thermal conductance of material"; Real TC_1662_1663.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1662_1663.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1662_1663.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1662_1663.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1662_1663.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1662_1663.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1662_1663.G(quantity = "ThermalConductance", unit = "W/K") = 0.00499977975993846 "Constant thermal conductance of material"; Real TC_1663_1664.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1663_1664.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1663_1664.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1663_1664.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1663_1664.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1663_1664.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1663_1664.G(quantity = "ThermalConductance", unit = "W/K") = 0.00500000000000002 "Constant thermal conductance of material"; Real TC_1_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_1_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_1_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_1_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_1_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_1_0.G(quantity = "ThermalConductance", unit = "W/K") = 3.2999929138322e-05 "Constant thermal conductance of material"; Real TC_2_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_2_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_2_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_2_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_2_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_2_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_2_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.39991632702637e-05 "Constant thermal conductance of material"; Real TC_3_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_3_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_3_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_3_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_3_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_3_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_3_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000342653509 "Constant thermal conductance of material"; Real TC_4_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_4_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_4_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_4_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_4_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_4_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_4_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998901889969 "Constant thermal conductance of material"; Real TC_5_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_5_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_5_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_5_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_5_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_5_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_5_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000865323745 "Constant thermal conductance of material"; Real TC_6_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_6_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_6_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_6_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_6_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_6_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_6_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00011 "Constant thermal conductance of material"; Real TC_7_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_7_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_7_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_7_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_7_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_7_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_7_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000154367611 "Constant thermal conductance of material"; Real TC_8_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_8_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_8_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_8_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_8_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_8_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_8_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000089020243 "Constant thermal conductance of material"; Real TC_9_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_9_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_9_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_9_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_9_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_9_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_9_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000663067809 "Constant thermal conductance of material"; Real TC_10_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_10_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_10_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_10_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_10_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_10_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_10_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000803120977 "Constant thermal conductance of material"; Real TC_11_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_11_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_11_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_11_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_11_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_11_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_11_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110001174240518 "Constant thermal conductance of material"; Real TC_12_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_12_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_12_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_12_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_12_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_12_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_12_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.4000196795513e-05 "Constant thermal conductance of material"; Real TC_13_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_13_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_13_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_13_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_13_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_13_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_13_0.G(quantity = "ThermalConductance", unit = "W/K") = 3.30000756622163e-05 "Constant thermal conductance of material"; Real TC_14_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_14_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_14_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_14_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_14_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_14_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_14_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998764058831 "Constant thermal conductance of material"; Real TC_15_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_15_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_15_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_15_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_15_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_15_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_15_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999972818036 "Constant thermal conductance of material"; Real TC_16_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_16_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_16_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_16_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_16_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_16_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_16_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00027499621187523 "Constant thermal conductance of material"; Real TC_17_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_17_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_17_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_17_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_17_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_17_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_17_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275008807364234 "Constant thermal conductance of material"; Real TC_18_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_18_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_18_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_18_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_18_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_18_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_18_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274994918256526 "Constant thermal conductance of material"; Real TC_19_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_19_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_19_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_19_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_19_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_19_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_19_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998873980953 "Constant thermal conductance of material"; Real TC_20_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_20_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_20_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_20_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_20_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_20_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_20_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274996968655063 "Constant thermal conductance of material"; Real TC_21_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_21_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_21_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_21_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_21_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_21_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_21_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275003308146751 "Constant thermal conductance of material"; Real TC_22_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_22_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_22_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_22_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_22_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_22_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_22_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275003345330776 "Constant thermal conductance of material"; Real TC_23_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_23_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_23_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_23_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_23_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_23_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_23_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001771918633 "Constant thermal conductance of material"; Real TC_24_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_24_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_24_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_24_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_24_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_24_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_24_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274992129289537 "Constant thermal conductance of material"; Real TC_25_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_25_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_25_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_25_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_25_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_25_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_25_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999057779081 "Constant thermal conductance of material"; Real TC_26_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_26_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_26_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_26_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_26_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_26_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_26_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000481923612 "Constant thermal conductance of material"; Real TC_27_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_27_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_27_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_27_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_27_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_27_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_27_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000219996272185673 "Constant thermal conductance of material"; Real TC_28_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_28_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_28_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_28_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_28_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_28_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_28_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000219998409590171 "Constant thermal conductance of material"; Real TC_29_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_29_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_29_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_29_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_29_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_29_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_29_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550001746605986 "Constant thermal conductance of material"; Real TC_30_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_30_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_30_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_30_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_30_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_30_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_30_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000549999667164441 "Constant thermal conductance of material"; Real TC_31_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_31_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_31_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_31_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_31_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_31_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_31_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550001266603055 "Constant thermal conductance of material"; Real TC_32_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_32_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_32_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_32_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_32_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_32_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_32_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550001319314345 "Constant thermal conductance of material"; Real TC_33_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_33_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_33_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_33_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_33_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_33_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_33_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550001214084771 "Constant thermal conductance of material"; Real TC_34_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_34_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_34_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_34_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_34_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_34_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_34_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550001850071594 "Constant thermal conductance of material"; Real TC_35_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_35_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_35_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_35_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_35_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_35_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_35_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000549999610592176 "Constant thermal conductance of material"; Real TC_36_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_36_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_36_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_36_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_36_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_36_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_36_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550001799696035 "Constant thermal conductance of material"; Real TC_37_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_37_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_37_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_37_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_37_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_37_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_37_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550003948609881 "Constant thermal conductance of material"; Real TC_38_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_38_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_38_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_38_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_38_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_38_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_38_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000219997757226651 "Constant thermal conductance of material"; Real TC_39_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_39_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_39_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_39_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_39_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_39_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_39_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000219994864529613 "Constant thermal conductance of material"; Real TC_40_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_40_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_40_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_40_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_40_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_40_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_40_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154002308511576 "Constant thermal conductance of material"; Real TC_41_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_41_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_41_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_41_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_41_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_41_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_41_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153996987015471 "Constant thermal conductance of material"; Real TC_42_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_42_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_42_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_42_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_42_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_42_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_42_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384999948126323 "Constant thermal conductance of material"; Real TC_43_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_43_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_43_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_43_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_43_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_43_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_43_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384997211719358 "Constant thermal conductance of material"; Real TC_44_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_44_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_44_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_44_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_44_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_44_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_44_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385006350346289 "Constant thermal conductance of material"; Real TC_45_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_45_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_45_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_45_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_45_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_45_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_45_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384997351318331 "Constant thermal conductance of material"; Real TC_46_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_46_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_46_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_46_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_46_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_46_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_46_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384985891432841 "Constant thermal conductance of material"; Real TC_47_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_47_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_47_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_47_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_47_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_47_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_47_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384990491884246 "Constant thermal conductance of material"; Real TC_48_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_48_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_48_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_48_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_48_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_48_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_48_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384997841506184 "Constant thermal conductance of material"; Real TC_49_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_49_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_49_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_49_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_49_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_49_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_49_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00038500254602138 "Constant thermal conductance of material"; Real TC_50_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_50_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_50_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_50_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_50_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_50_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_50_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00038500040812492 "Constant thermal conductance of material"; Real TC_51_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_51_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_51_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_51_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_51_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_51_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_51_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153999832472986 "Constant thermal conductance of material"; Real TC_52_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_52_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_52_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_52_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_52_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_52_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_52_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154000286245885 "Constant thermal conductance of material"; Real TC_53_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_53_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_53_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_53_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_53_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_53_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_53_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153995504311397 "Constant thermal conductance of material"; Real TC_54_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_54_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_54_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_54_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_54_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_54_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_54_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154003600179095 "Constant thermal conductance of material"; Real TC_55_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_55_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_55_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_55_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_55_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_55_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_55_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385002566642145 "Constant thermal conductance of material"; Real TC_56_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_56_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_56_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_56_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_56_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_56_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_56_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00038499163268136 "Constant thermal conductance of material"; Real TC_57_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_57_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_57_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_57_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_57_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_57_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_57_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385010537606223 "Constant thermal conductance of material"; Real TC_58_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_58_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_58_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_58_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_58_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_58_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_58_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384993237418514 "Constant thermal conductance of material"; Real TC_59_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_59_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_59_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_59_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_59_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_59_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_59_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385015659583616 "Constant thermal conductance of material"; Real TC_60_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_60_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_60_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_60_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_60_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_60_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_60_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384996885971688 "Constant thermal conductance of material"; Real TC_61_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_61_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_61_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_61_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_61_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_61_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_61_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385003549598113 "Constant thermal conductance of material"; Real TC_62_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_62_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_62_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_62_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_62_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_62_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_62_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384987338369878 "Constant thermal conductance of material"; Real TC_63_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_63_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_63_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_63_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_63_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_63_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_63_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385009270222219 "Constant thermal conductance of material"; Real TC_64_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_64_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_64_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_64_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_64_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_64_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_64_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154001227992245 "Constant thermal conductance of material"; Real TC_65_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_65_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_65_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_65_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_65_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_65_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_65_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153996588321783 "Constant thermal conductance of material"; Real TC_66_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_66_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_66_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_66_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_66_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_66_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_66_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153997974928172 "Constant thermal conductance of material"; Real TC_67_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_67_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_67_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_67_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_67_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_67_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_67_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153995967289432 "Constant thermal conductance of material"; Real TC_68_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_68_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_68_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_68_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_68_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_68_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_68_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385000099158147 "Constant thermal conductance of material"; Real TC_69_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_69_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_69_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_69_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_69_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_69_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_69_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385013145270817 "Constant thermal conductance of material"; Real TC_70_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_70_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_70_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_70_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_70_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_70_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_70_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00038499773453714 "Constant thermal conductance of material"; Real TC_71_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_71_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_71_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_71_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_71_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_71_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_71_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385016284699252 "Constant thermal conductance of material"; Real TC_72_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_72_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_72_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_72_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_72_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_72_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_72_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384983985083547 "Constant thermal conductance of material"; Real TC_73_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_73_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_73_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_73_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_73_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_73_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_73_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384984954140458 "Constant thermal conductance of material"; Real TC_74_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_74_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_74_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_74_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_74_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_74_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_74_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384993903922244 "Constant thermal conductance of material"; Real TC_75_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_75_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_75_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_75_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_75_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_75_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_75_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00038501246405744 "Constant thermal conductance of material"; Real TC_76_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_76_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_76_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_76_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_76_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_76_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_76_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385004288069458 "Constant thermal conductance of material"; Real TC_77_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_77_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_77_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_77_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_77_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_77_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_77_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153998997681476 "Constant thermal conductance of material"; Real TC_78_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_78_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_78_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_78_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_78_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_78_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_78_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154000848226448 "Constant thermal conductance of material"; Real TC_79_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_79_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_79_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_79_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_79_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_79_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_79_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000308002593099474 "Constant thermal conductance of material"; Real TC_80_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_80_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_80_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_80_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_80_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_80_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_80_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000307995404242836 "Constant thermal conductance of material"; Real TC_81_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_81_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_81_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_81_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_81_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_81_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_81_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000770021614859132 "Constant thermal conductance of material"; Real TC_82_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_82_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_82_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_82_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_82_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_82_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_82_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000769982807115554 "Constant thermal conductance of material"; Real TC_83_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_83_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_83_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_83_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_83_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_83_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_83_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000770013419336336 "Constant thermal conductance of material"; Real TC_84_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_84_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_84_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_84_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_84_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_84_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_84_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000770003384791982 "Constant thermal conductance of material"; Real TC_85_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_85_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_85_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_85_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_85_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_85_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_85_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000770013564797247 "Constant thermal conductance of material"; Real TC_86_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_86_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_86_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_86_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_86_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_86_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_86_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000770005942998889 "Constant thermal conductance of material"; Real TC_87_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_87_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_87_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_87_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_87_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_87_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_87_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000769992112505995 "Constant thermal conductance of material"; Real TC_88_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_88_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_88_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_88_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_88_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_88_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_88_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000769997906766586 "Constant thermal conductance of material"; Real TC_89_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_89_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_89_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_89_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_89_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_89_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_89_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.0007700116786328 "Constant thermal conductance of material"; Real TC_90_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_90_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_90_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_90_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_90_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_90_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_90_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000307999085601623 "Constant thermal conductance of material"; Real TC_91_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_91_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_91_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_91_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_91_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_91_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_91_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000307996988107149 "Constant thermal conductance of material"; Real TC_92_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_92_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_92_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_92_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_92_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_92_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_92_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110003224320121 "Constant thermal conductance of material"; Real TC_93_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_93_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_93_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_93_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_93_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_93_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_93_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109997118057607 "Constant thermal conductance of material"; Real TC_94_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_94_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_94_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_94_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_94_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_94_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_94_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002372504661 "Constant thermal conductance of material"; Real TC_95_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_95_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_95_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_95_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_95_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_95_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_95_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001336945237 "Constant thermal conductance of material"; Real TC_96_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_96_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_96_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_96_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_96_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_96_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_96_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999708509199 "Constant thermal conductance of material"; Real TC_97_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_97_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_97_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_97_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_97_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_97_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_97_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998645451426 "Constant thermal conductance of material"; Real TC_98_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_98_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_98_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_98_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_98_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_98_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_98_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000356282689 "Constant thermal conductance of material"; Real TC_99_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_99_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_99_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_99_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_99_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_99_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_99_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001351636527 "Constant thermal conductance of material"; Real TC_100_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_100_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_100_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_100_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_100_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_100_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_100_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001367150049 "Constant thermal conductance of material"; Real TC_101_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_101_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_101_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_101_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_101_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_101_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_101_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999843882158 "Constant thermal conductance of material"; Real TC_102_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_102_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_102_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_102_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_102_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_102_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_102_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001037398481 "Constant thermal conductance of material"; Real TC_103_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_103_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_103_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_103_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_103_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_103_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_103_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000720968042 "Constant thermal conductance of material"; Real TC_104_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_104_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_104_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_104_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_104_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_104_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_104_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000193933104 "Constant thermal conductance of material"; Real TC_105_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_105_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_105_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_105_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_105_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_105_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_105_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010999795254132 "Constant thermal conductance of material"; Real TC_106_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_106_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_106_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_106_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_106_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_106_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_106_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109996066812689 "Constant thermal conductance of material"; Real TC_107_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_107_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_107_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_107_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_107_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_107_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_107_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997112970966 "Constant thermal conductance of material"; Real TC_108_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_108_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_108_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_108_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_108_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_108_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_108_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998697592785 "Constant thermal conductance of material"; Real TC_109_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_109_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_109_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_109_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_109_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_109_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_109_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000190225042 "Constant thermal conductance of material"; Real TC_110_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_110_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_110_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_110_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_110_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_110_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_110_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000897311654 "Constant thermal conductance of material"; Real TC_111_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_111_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_111_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_111_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_111_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_111_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_111_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001140196029 "Constant thermal conductance of material"; Real TC_112_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_112_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_112_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_112_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_112_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_112_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_112_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998592222226 "Constant thermal conductance of material"; Real TC_113_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_113_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_113_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_113_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_113_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_113_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_113_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998783964222 "Constant thermal conductance of material"; Real TC_114_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_114_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_114_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_114_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_114_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_114_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_114_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999982828385 "Constant thermal conductance of material"; Real TC_115_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_115_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_115_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_115_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_115_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_115_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_115_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00027500097515584 "Constant thermal conductance of material"; Real TC_116_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_116_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_116_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_116_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_116_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_116_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_116_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999407115829 "Constant thermal conductance of material"; Real TC_117_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_117_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_117_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_117_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_117_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_117_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_117_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110002626057386 "Constant thermal conductance of material"; Real TC_118_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_118_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_118_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_118_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_118_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_118_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_118_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109995504270943 "Constant thermal conductance of material"; Real TC_119_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_119_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_119_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_119_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_119_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_119_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_119_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110002772069856 "Constant thermal conductance of material"; Real TC_120_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_120_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_120_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_120_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_120_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_120_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_120_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000301535418 "Constant thermal conductance of material"; Real TC_121_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_121_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_121_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_121_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_121_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_121_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_121_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999031307413 "Constant thermal conductance of material"; Real TC_122_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_122_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_122_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_122_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_122_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_122_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_122_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999981942822 "Constant thermal conductance of material"; Real TC_123_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_123_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_123_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_123_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_123_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_123_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_123_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000089506604 "Constant thermal conductance of material"; Real TC_124_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_124_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_124_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_124_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_124_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_124_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_124_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998392772492 "Constant thermal conductance of material"; Real TC_125_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_125_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_125_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_125_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_125_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_125_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_125_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000865021972 "Constant thermal conductance of material"; Real TC_126_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_126_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_126_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_126_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_126_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_126_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_126_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001596690421 "Constant thermal conductance of material"; Real TC_127_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_127_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_127_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_127_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_127_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_127_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_127_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998417255493 "Constant thermal conductance of material"; Real TC_128_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_128_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_128_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_128_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_128_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_128_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_128_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001326768495 "Constant thermal conductance of material"; Real TC_129_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_129_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_129_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_129_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_129_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_129_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_129_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998188121725 "Constant thermal conductance of material"; Real TC_130_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_130_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_130_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_130_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_130_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_130_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_130_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110002692211287 "Constant thermal conductance of material"; Real TC_131_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_131_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_131_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_131_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_131_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_131_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_131_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000486332566 "Constant thermal conductance of material"; Real TC_132_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_132_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_132_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_132_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_132_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_132_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_132_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999868808298 "Constant thermal conductance of material"; Real TC_133_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_133_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_133_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_133_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_133_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_133_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_133_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001633026324 "Constant thermal conductance of material"; Real TC_134_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_134_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_134_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_134_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_134_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_134_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_134_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000337390161 "Constant thermal conductance of material"; Real TC_135_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_135_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_135_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_135_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_135_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_135_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_135_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999377902894 "Constant thermal conductance of material"; Real TC_136_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_136_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_136_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_136_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_136_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_136_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_136_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000492549958 "Constant thermal conductance of material"; Real TC_137_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_137_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_137_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_137_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_137_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_137_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_137_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998819541854 "Constant thermal conductance of material"; Real TC_138_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_138_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_138_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_138_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_138_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_138_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_138_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998805498641 "Constant thermal conductance of material"; Real TC_139_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_139_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_139_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_139_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_139_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_139_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_139_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000428001276 "Constant thermal conductance of material"; Real TC_140_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_140_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_140_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_140_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_140_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_140_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_140_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000096086686 "Constant thermal conductance of material"; Real TC_141_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_141_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_141_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_141_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_141_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_141_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_141_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998335168191 "Constant thermal conductance of material"; Real TC_142_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_142_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_142_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_142_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_142_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_142_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_142_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999553142525 "Constant thermal conductance of material"; Real TC_143_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_143_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_143_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_143_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_143_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_143_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_143_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110003203132784 "Constant thermal conductance of material"; Real TC_144_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_144_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_144_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_144_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_144_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_144_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_144_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109997570274559 "Constant thermal conductance of material"; Real TC_145_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_145_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_145_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_145_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_145_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_145_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_145_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109996106488423 "Constant thermal conductance of material"; Real TC_146_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_146_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_146_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_146_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_146_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_146_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_146_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000180624092 "Constant thermal conductance of material"; Real TC_147_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_147_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_147_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_147_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_147_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_147_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_147_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001440122618 "Constant thermal conductance of material"; Real TC_148_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_148_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_148_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_148_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_148_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_148_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_148_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000991923936 "Constant thermal conductance of material"; Real TC_149_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_149_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_149_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_149_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_149_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_149_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_149_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998044238254 "Constant thermal conductance of material"; Real TC_150_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_150_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_150_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_150_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_150_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_150_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_150_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999821646418 "Constant thermal conductance of material"; Real TC_151_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_151_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_151_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_151_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_151_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_151_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_151_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001347055337 "Constant thermal conductance of material"; Real TC_152_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_152_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_152_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_152_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_152_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_152_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_152_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999876415659 "Constant thermal conductance of material"; Real TC_153_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_153_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_153_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_153_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_153_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_153_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_153_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00027500019407212 "Constant thermal conductance of material"; Real TC_154_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_154_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_154_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_154_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_154_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_154_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_154_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998206440325 "Constant thermal conductance of material"; Real TC_155_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_155_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_155_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_155_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_155_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_155_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_155_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000946817757 "Constant thermal conductance of material"; Real TC_156_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_156_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_156_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_156_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_156_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_156_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_156_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000844274863 "Constant thermal conductance of material"; Real TC_157_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_157_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_157_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_157_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_157_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_157_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_157_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109996395093587 "Constant thermal conductance of material"; Real TC_158_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_158_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_158_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_158_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_158_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_158_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_158_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110004173897761 "Constant thermal conductance of material"; Real TC_159_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_159_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_159_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_159_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_159_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_159_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_159_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002708312839 "Constant thermal conductance of material"; Real TC_160_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_160_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_160_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_160_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_160_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_160_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_160_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000632256982 "Constant thermal conductance of material"; Real TC_161_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_161_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_161_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_161_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_161_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_161_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_161_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001423177598 "Constant thermal conductance of material"; Real TC_162_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_162_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_162_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_162_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_162_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_162_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_162_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998564914081 "Constant thermal conductance of material"; Real TC_163_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_163_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_163_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_163_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_163_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_163_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_163_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999595715664 "Constant thermal conductance of material"; Real TC_164_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_164_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_164_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_164_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_164_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_164_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_164_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00027499995528456 "Constant thermal conductance of material"; Real TC_165_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_165_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_165_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_165_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_165_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_165_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_165_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000133735849 "Constant thermal conductance of material"; Real TC_166_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_166_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_166_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_166_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_166_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_166_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_166_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999162435481 "Constant thermal conductance of material"; Real TC_167_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_167_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_167_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_167_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_167_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_167_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_167_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999062273683 "Constant thermal conductance of material"; Real TC_168_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_168_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_168_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_168_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_168_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_168_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_168_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998760393566 "Constant thermal conductance of material"; Real TC_169_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_169_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_169_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_169_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_169_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_169_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_169_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000690020011 "Constant thermal conductance of material"; Real TC_170_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_170_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_170_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_170_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_170_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_170_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_170_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000330002023591156 "Constant thermal conductance of material"; Real TC_171_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_171_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_171_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_171_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_171_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_171_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_171_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000329999256120183 "Constant thermal conductance of material"; Real TC_172_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_172_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_172_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_172_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_172_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_172_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_172_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000824995964745253 "Constant thermal conductance of material"; Real TC_173_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_173_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_173_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_173_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_173_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_173_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_173_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00082496667336243 "Constant thermal conductance of material"; Real TC_174_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_174_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_174_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_174_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_174_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_174_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_174_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000824964909618227 "Constant thermal conductance of material"; Real TC_175_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_175_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_175_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_175_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_175_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_175_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_175_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000825009259246415 "Constant thermal conductance of material"; Real TC_176_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_176_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_176_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_176_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_176_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_176_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_176_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00082499023340253 "Constant thermal conductance of material"; Real TC_177_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_177_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_177_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_177_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_177_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_177_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_177_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00082501860666804 "Constant thermal conductance of material"; Real TC_178_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_178_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_178_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_178_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_178_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_178_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_178_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000824999160569784 "Constant thermal conductance of material"; Real TC_179_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_179_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_179_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_179_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_179_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_179_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_179_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000824966958207522 "Constant thermal conductance of material"; Real TC_180_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_180_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_180_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_180_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_180_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_180_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_180_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000825004033371823 "Constant thermal conductance of material"; Real TC_181_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_181_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_181_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_181_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_181_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_181_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_181_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00032999873369634 "Constant thermal conductance of material"; Real TC_182_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_182_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_182_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_182_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_182_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_182_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_182_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000329993941547436 "Constant thermal conductance of material"; Real TC_183_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_183_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_183_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_183_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_183_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_183_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_183_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000759308963 "Constant thermal conductance of material"; Real TC_184_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_184_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_184_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_184_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_184_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_184_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_184_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00011000030581975 "Constant thermal conductance of material"; Real TC_185_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_185_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_185_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_185_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_185_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_185_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_185_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274988220049476 "Constant thermal conductance of material"; Real TC_186_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_186_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_186_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_186_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_186_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_186_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_186_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275004346032125 "Constant thermal conductance of material"; Real TC_187_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_187_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_187_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_187_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_187_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_187_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_187_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999013845608 "Constant thermal conductance of material"; Real TC_188_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_188_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_188_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_188_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_188_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_188_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_188_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997094487274 "Constant thermal conductance of material"; Real TC_189_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_189_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_189_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_189_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_189_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_189_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_189_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274994521828333 "Constant thermal conductance of material"; Real TC_190_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_190_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_190_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_190_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_190_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_190_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_190_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274991213240419 "Constant thermal conductance of material"; Real TC_191_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_191_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_191_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_191_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_191_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_191_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_191_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275005951636397 "Constant thermal conductance of material"; Real TC_192_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_192_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_192_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_192_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_192_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_192_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_192_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275005948565806 "Constant thermal conductance of material"; Real TC_193_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_193_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_193_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_193_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_193_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_193_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_193_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998945270718 "Constant thermal conductance of material"; Real TC_194_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_194_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_194_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_194_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_194_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_194_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_194_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000894065563 "Constant thermal conductance of material"; Real TC_195_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_195_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_195_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_195_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_195_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_195_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_195_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998500974367 "Constant thermal conductance of material"; Real TC_196_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_196_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_196_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_196_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_196_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_196_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_196_0.G(quantity = "ThermalConductance", unit = "W/K") = 3.29998251664892e-05 "Constant thermal conductance of material"; Real TC_197_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_197_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_197_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_197_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_197_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_197_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_197_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.39983787080425e-05 "Constant thermal conductance of material"; Real TC_198_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_198_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_198_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_198_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_198_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_198_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_198_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998454444759 "Constant thermal conductance of material"; Real TC_199_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_199_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_199_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_199_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_199_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_199_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_199_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000194356444 "Constant thermal conductance of material"; Real TC_200_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_200_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_200_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_200_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_200_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_200_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_200_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998800477723 "Constant thermal conductance of material"; Real TC_201_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_201_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_201_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_201_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_201_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_201_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_201_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999693402011 "Constant thermal conductance of material"; Real TC_202_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_202_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_202_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_202_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_202_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_202_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_202_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000894648723 "Constant thermal conductance of material"; Real TC_203_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_203_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_203_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_203_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_203_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_203_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_203_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000181364535 "Constant thermal conductance of material"; Real TC_204_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_204_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_204_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_204_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_204_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_204_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_204_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999225714812 "Constant thermal conductance of material"; Real TC_205_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_205_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_205_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_205_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_205_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_205_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_205_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999230894128 "Constant thermal conductance of material"; Real TC_206_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_206_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_206_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_206_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_206_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_206_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_206_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999934422359 "Constant thermal conductance of material"; Real TC_207_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_207_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_207_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_207_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_207_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_207_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_207_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.39990927229461e-05 "Constant thermal conductance of material"; Real TC_208_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_208_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_208_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_208_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_208_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_208_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_208_0.G(quantity = "ThermalConductance", unit = "W/K") = 3.30000685066754e-05 "Constant thermal conductance of material"; Real TC_209_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_209_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_209_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_209_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_209_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_209_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_209_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.2000054922045e-05 "Constant thermal conductance of material"; Real TC_210_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_210_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_210_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_210_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_210_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_210_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_210_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000442051472e-05 "Constant thermal conductance of material"; Real TC_211_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_211_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_211_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_211_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_211_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_211_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_211_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.4999076049949e-05 "Constant thermal conductance of material"; Real TC_212_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_212_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_212_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_212_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_212_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_212_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_212_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.5001027681244e-05 "Constant thermal conductance of material"; Real TC_213_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_213_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_213_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_213_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_213_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_213_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_213_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49999540191832e-05 "Constant thermal conductance of material"; Real TC_214_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_214_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_214_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_214_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_214_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_214_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_214_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49999428512647e-05 "Constant thermal conductance of material"; Real TC_215_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_215_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_215_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_215_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_215_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_215_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_215_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50006114768435e-05 "Constant thermal conductance of material"; Real TC_216_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_216_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_216_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_216_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_216_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_216_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_216_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49988137603796e-05 "Constant thermal conductance of material"; Real TC_217_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_217_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_217_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_217_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_217_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_217_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_217_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50007708853049e-05 "Constant thermal conductance of material"; Real TC_218_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_218_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_218_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_218_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_218_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_218_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_218_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49992033719094e-05 "Constant thermal conductance of material"; Real TC_219_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_219_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_219_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_219_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_219_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_219_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_219_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20000200885907e-05 "Constant thermal conductance of material"; Real TC_220_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_220_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_220_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_220_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_220_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_220_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_220_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20000956689308e-05 "Constant thermal conductance of material"; Real TC_221_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_221_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_221_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_221_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_221_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_221_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_221_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50005152893718e-05 "Constant thermal conductance of material"; Real TC_222_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_222_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_222_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_222_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_222_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_222_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_222_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50013220104794e-05 "Constant thermal conductance of material"; Real TC_223_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_223_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_223_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_223_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_223_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_223_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_223_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999600847305 "Constant thermal conductance of material"; Real TC_224_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_224_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_224_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_224_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_224_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_224_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_224_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000526471906 "Constant thermal conductance of material"; Real TC_225_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_225_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_225_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_225_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_225_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_225_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_225_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70001856731092e-05 "Constant thermal conductance of material"; Real TC_226_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_226_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_226_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_226_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_226_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_226_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_226_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70002421944254e-05 "Constant thermal conductance of material"; Real TC_227_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_227_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_227_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_227_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_227_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_227_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_227_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69996768668332e-05 "Constant thermal conductance of material"; Real TC_228_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_228_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_228_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_228_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_228_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_228_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_228_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69985012751248e-05 "Constant thermal conductance of material"; Real TC_229_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_229_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_229_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_229_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_229_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_229_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_229_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69998996076332e-05 "Constant thermal conductance of material"; Real TC_230_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_230_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_230_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_230_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_230_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_230_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_230_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.6996340370777e-05 "Constant thermal conductance of material"; Real TC_231_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_231_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_231_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_231_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_231_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_231_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_231_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154003138730637 "Constant thermal conductance of material"; Real TC_232_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_232_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_232_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_232_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_232_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_232_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_232_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153997366831549 "Constant thermal conductance of material"; Real TC_233_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_233_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_233_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_233_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_233_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_233_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_233_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50001863886576e-05 "Constant thermal conductance of material"; Real TC_234_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_234_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_234_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_234_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_234_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_234_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_234_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50002163966202e-05 "Constant thermal conductance of material"; Real TC_235_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_235_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_235_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_235_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_235_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_235_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_235_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49996253501437e-05 "Constant thermal conductance of material"; Real TC_236_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_236_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_236_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_236_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_236_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_236_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_236_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000386997176e-05 "Constant thermal conductance of material"; Real TC_237_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_237_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_237_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_237_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_237_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_237_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_237_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004013367052e-05 "Constant thermal conductance of material"; Real TC_238_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_238_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_238_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_238_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_238_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_238_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_238_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49997467200243e-05 "Constant thermal conductance of material"; Real TC_239_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_239_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_239_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_239_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_239_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_239_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_239_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998537479361e-05 "Constant thermal conductance of material"; Real TC_240_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_240_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_240_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_240_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_240_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_240_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_240_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49999041912428e-05 "Constant thermal conductance of material"; Real TC_241_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_241_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_241_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_241_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_241_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_241_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_241_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49997105385304e-05 "Constant thermal conductance of material"; Real TC_242_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_242_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_242_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_242_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_242_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_242_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_242_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000108559795e-05 "Constant thermal conductance of material"; Real TC_243_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_243_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_243_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_243_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_243_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_243_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_243_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50001633334352e-05 "Constant thermal conductance of material"; Real TC_244_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_244_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_244_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_244_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_244_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_244_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_244_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50002412190522e-05 "Constant thermal conductance of material"; Real TC_245_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_245_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_245_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_245_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_245_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_245_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_245_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000164998155719607 "Constant thermal conductance of material"; Real TC_246_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_246_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_246_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_246_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_246_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_246_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_246_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000165003154679099 "Constant thermal conductance of material"; Real TC_247_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_247_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_247_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_247_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_247_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_247_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_247_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49996702064508e-05 "Constant thermal conductance of material"; Real TC_248_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_248_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_248_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_248_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_248_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_248_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_248_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004167708594e-05 "Constant thermal conductance of material"; Real TC_249_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_249_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_249_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_249_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_249_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_249_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_249_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999212784382e-05 "Constant thermal conductance of material"; Real TC_250_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_250_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_250_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_250_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_250_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_250_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_250_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999538099124e-05 "Constant thermal conductance of material"; Real TC_251_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_251_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_251_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_251_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_251_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_251_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_251_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50013257324672e-05 "Constant thermal conductance of material"; Real TC_252_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_252_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_252_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_252_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_252_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_252_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_252_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49995696209796e-05 "Constant thermal conductance of material"; Real TC_253_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_253_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_253_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_253_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_253_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_253_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_253_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50012666893054e-05 "Constant thermal conductance of material"; Real TC_254_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_254_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_254_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_254_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_254_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_254_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_254_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50008711859216e-05 "Constant thermal conductance of material"; Real TC_255_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_255_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_255_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_255_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_255_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_255_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_255_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000264118452e-05 "Constant thermal conductance of material"; Real TC_256_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_256_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_256_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_256_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_256_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_256_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_256_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.4999410825808e-05 "Constant thermal conductance of material"; Real TC_257_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_257_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_257_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_257_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_257_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_257_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_257_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49992543784554e-05 "Constant thermal conductance of material"; Real TC_258_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_258_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_258_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_258_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_258_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_258_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_258_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49990566705186e-05 "Constant thermal conductance of material"; Real TC_259_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_259_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_259_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_259_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_259_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_259_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_259_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50009647510435e-05 "Constant thermal conductance of material"; Real TC_260_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_260_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_260_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_260_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_260_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_260_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_260_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19998355269599e-05 "Constant thermal conductance of material"; Real TC_261_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_261_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_261_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_261_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_261_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_261_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_261_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20000639687832e-05 "Constant thermal conductance of material"; Real TC_262_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_262_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_262_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_262_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_262_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_262_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_262_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20000070247165e-05 "Constant thermal conductance of material"; Real TC_263_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_263_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_263_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_263_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_263_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_263_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_263_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.2e-05 "Constant thermal conductance of material"; Real TC_264_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_264_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_264_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_264_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_264_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_264_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_264_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50007176346761e-05 "Constant thermal conductance of material"; Real TC_265_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_265_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_265_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_265_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_265_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_265_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_265_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000908706184e-05 "Constant thermal conductance of material"; Real TC_266_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_266_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_266_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_266_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_266_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_266_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_266_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50003280337656e-05 "Constant thermal conductance of material"; Real TC_267_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_267_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_267_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_267_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_267_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_267_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_267_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49992198692217e-05 "Constant thermal conductance of material"; Real TC_268_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_268_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_268_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_268_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_268_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_268_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_268_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50005992118601e-05 "Constant thermal conductance of material"; Real TC_269_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_269_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_269_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_269_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_269_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_269_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_269_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49993711781274e-05 "Constant thermal conductance of material"; Real TC_270_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_270_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_270_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_270_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_270_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_270_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_270_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49997557520395e-05 "Constant thermal conductance of material"; Real TC_271_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_271_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_271_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_271_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_271_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_271_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_271_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49994142074227e-05 "Constant thermal conductance of material"; Real TC_272_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_272_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_272_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_272_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_272_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_272_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_272_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50011589827103e-05 "Constant thermal conductance of material"; Real TC_273_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_273_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_273_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_273_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_273_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_273_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_273_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999109232124e-05 "Constant thermal conductance of material"; Real TC_274_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_274_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_274_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_274_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_274_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_274_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_274_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999931020449e-05 "Constant thermal conductance of material"; Real TC_275_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_275_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_275_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_275_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_275_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_275_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_275_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50010766267248e-05 "Constant thermal conductance of material"; Real TC_276_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_276_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_276_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_276_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_276_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_276_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_276_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004977034541e-05 "Constant thermal conductance of material"; Real TC_277_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_277_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_277_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_277_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_277_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_277_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_277_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999961313934 "Constant thermal conductance of material"; Real TC_278_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_278_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_278_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_278_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_278_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_278_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_278_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999576848116 "Constant thermal conductance of material"; Real TC_279_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_279_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_279_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_279_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_279_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_279_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_279_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70000700090137e-05 "Constant thermal conductance of material"; Real TC_280_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_280_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_280_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_280_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_280_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_280_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_280_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69999253492687e-05 "Constant thermal conductance of material"; Real TC_281_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_281_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_281_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_281_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_281_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_281_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_281_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69996041638593e-05 "Constant thermal conductance of material"; Real TC_282_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_282_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_282_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_282_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_282_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_282_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_282_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70002313289192e-05 "Constant thermal conductance of material"; Real TC_283_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_283_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_283_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_283_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_283_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_283_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_283_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69997305072105e-05 "Constant thermal conductance of material"; Real TC_284_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_284_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_284_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_284_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_284_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_284_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_284_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70000249221612e-05 "Constant thermal conductance of material"; Real TC_285_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_285_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_285_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_285_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_285_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_285_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_285_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154003266258874 "Constant thermal conductance of material"; Real TC_286_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_286_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_286_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_286_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_286_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_286_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_286_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154001990242214 "Constant thermal conductance of material"; Real TC_287_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_287_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_287_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_287_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_287_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_287_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_287_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004200247037e-05 "Constant thermal conductance of material"; Real TC_288_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_288_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_288_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_288_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_288_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_288_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_288_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50002322294693e-05 "Constant thermal conductance of material"; Real TC_289_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_289_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_289_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_289_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_289_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_289_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_289_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.4999902476982e-05 "Constant thermal conductance of material"; Real TC_290_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_290_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_290_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_290_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_290_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_290_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_290_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998273625436e-05 "Constant thermal conductance of material"; Real TC_291_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_291_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_291_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_291_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_291_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_291_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_291_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50002431532108e-05 "Constant thermal conductance of material"; Real TC_292_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_292_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_292_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_292_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_292_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_292_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_292_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998315711292e-05 "Constant thermal conductance of material"; Real TC_293_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_293_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_293_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_293_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_293_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_293_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_293_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50002854530139e-05 "Constant thermal conductance of material"; Real TC_294_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_294_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_294_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_294_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_294_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_294_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_294_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000622182034e-05 "Constant thermal conductance of material"; Real TC_295_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_295_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_295_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_295_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_295_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_295_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_295_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50003769696665e-05 "Constant thermal conductance of material"; Real TC_296_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_296_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_296_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_296_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_296_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_296_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_296_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50001316259886e-05 "Constant thermal conductance of material"; Real TC_297_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_297_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_297_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_297_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_297_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_297_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_297_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000103603538e-05 "Constant thermal conductance of material"; Real TC_298_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_298_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_298_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_298_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_298_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_298_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_298_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49997625496966e-05 "Constant thermal conductance of material"; Real TC_299_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_299_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_299_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_299_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_299_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_299_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_299_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000165001412807922 "Constant thermal conductance of material"; Real TC_300_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_300_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_300_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_300_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_300_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_300_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_300_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000165001563908668 "Constant thermal conductance of material"; Real TC_301_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_301_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_301_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_301_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_301_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_301_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_301_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50016708464865e-05 "Constant thermal conductance of material"; Real TC_302_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_302_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_302_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_302_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_302_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_302_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_302_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50001159082404e-05 "Constant thermal conductance of material"; Real TC_303_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_303_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_303_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_303_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_303_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_303_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_303_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999372986699e-05 "Constant thermal conductance of material"; Real TC_304_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_304_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_304_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_304_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_304_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_304_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_304_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.2000108663593e-05 "Constant thermal conductance of material"; Real TC_305_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_305_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_305_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_305_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_305_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_305_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_305_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50009330098899e-05 "Constant thermal conductance of material"; Real TC_306_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_306_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_306_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_306_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_306_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_306_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_306_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49987934398013e-05 "Constant thermal conductance of material"; Real TC_307_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_307_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_307_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_307_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_307_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_307_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_307_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49994111412084e-05 "Constant thermal conductance of material"; Real TC_308_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_308_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_308_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_308_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_308_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_308_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_308_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49986839207344e-05 "Constant thermal conductance of material"; Real TC_309_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_309_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_309_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_309_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_309_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_309_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_309_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50005648532188e-05 "Constant thermal conductance of material"; Real TC_310_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_310_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_310_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_310_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_310_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_310_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_310_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.5000791653245e-05 "Constant thermal conductance of material"; Real TC_311_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_311_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_311_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_311_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_311_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_311_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_311_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.5001295672454e-05 "Constant thermal conductance of material"; Real TC_312_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_312_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_312_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_312_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_312_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_312_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_312_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50003905850965e-05 "Constant thermal conductance of material"; Real TC_313_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_313_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_313_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_313_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_313_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_313_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_313_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50003434301807e-05 "Constant thermal conductance of material"; Real TC_314_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_314_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_314_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_314_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_314_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_314_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_314_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999761215889e-05 "Constant thermal conductance of material"; Real TC_315_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_315_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_315_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_315_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_315_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_315_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_315_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19997432935438e-05 "Constant thermal conductance of material"; Real TC_316_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_316_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_316_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_316_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_316_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_316_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_316_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20001262218981e-05 "Constant thermal conductance of material"; Real TC_317_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_317_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_317_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_317_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_317_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_317_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_317_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.2000111017055e-05 "Constant thermal conductance of material"; Real TC_318_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_318_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_318_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_318_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_318_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_318_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_318_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49989392250666e-05 "Constant thermal conductance of material"; Real TC_319_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_319_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_319_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_319_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_319_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_319_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_319_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998058830381e-05 "Constant thermal conductance of material"; Real TC_320_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_320_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_320_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_320_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_320_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_320_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_320_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.5000992404475e-05 "Constant thermal conductance of material"; Real TC_321_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_321_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_321_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_321_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_321_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_321_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_321_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50010597960482e-05 "Constant thermal conductance of material"; Real TC_322_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_322_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_322_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_322_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_322_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_322_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_322_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49996488188608e-05 "Constant thermal conductance of material"; Real TC_323_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_323_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_323_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_323_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_323_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_323_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_323_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49991135275693e-05 "Constant thermal conductance of material"; Real TC_324_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_324_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_324_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_324_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_324_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_324_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_324_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49993432478583e-05 "Constant thermal conductance of material"; Real TC_325_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_325_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_325_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_325_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_325_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_325_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_325_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004276860629e-05 "Constant thermal conductance of material"; Real TC_326_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_326_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_326_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_326_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_326_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_326_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_326_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50001628187176e-05 "Constant thermal conductance of material"; Real TC_327_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_327_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_327_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_327_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_327_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_327_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_327_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999318592212e-05 "Constant thermal conductance of material"; Real TC_328_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_328_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_328_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_328_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_328_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_328_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_328_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20000480417826e-05 "Constant thermal conductance of material"; Real TC_329_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_329_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_329_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_329_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_329_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_329_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_329_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50005968515354e-05 "Constant thermal conductance of material"; Real TC_330_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_330_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_330_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_330_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_330_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_330_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_330_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004817146775e-05 "Constant thermal conductance of material"; Real TC_331_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_331_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_331_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_331_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_331_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_331_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_331_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000052278288 "Constant thermal conductance of material"; Real TC_332_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_332_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_332_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_332_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_332_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_332_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_332_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999800238715 "Constant thermal conductance of material"; Real TC_333_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_333_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_333_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_333_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_333_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_333_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_333_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69995716296433e-05 "Constant thermal conductance of material"; Real TC_334_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_334_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_334_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_334_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_334_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_334_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_334_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70003079765938e-05 "Constant thermal conductance of material"; Real TC_335_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_335_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_335_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_335_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_335_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_335_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_335_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70000871006096e-05 "Constant thermal conductance of material"; Real TC_336_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_336_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_336_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_336_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_336_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_336_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_336_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70002687632978e-05 "Constant thermal conductance of material"; Real TC_337_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_337_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_337_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_337_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_337_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_337_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_337_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70003205008137e-05 "Constant thermal conductance of material"; Real TC_338_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_338_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_338_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_338_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_338_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_338_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_338_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69997232670211e-05 "Constant thermal conductance of material"; Real TC_339_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_339_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_339_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_339_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_339_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_339_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_339_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153995461934152 "Constant thermal conductance of material"; Real TC_340_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_340_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_340_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_340_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_340_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_340_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_340_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154003461005627 "Constant thermal conductance of material"; Real TC_341_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_341_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_341_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_341_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_341_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_341_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_341_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998399786913e-05 "Constant thermal conductance of material"; Real TC_342_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_342_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_342_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_342_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_342_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_342_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_342_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50003031990254e-05 "Constant thermal conductance of material"; Real TC_343_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_343_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_343_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_343_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_343_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_343_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_343_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50002095966644e-05 "Constant thermal conductance of material"; Real TC_344_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_344_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_344_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_344_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_344_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_344_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_344_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49996251569655e-05 "Constant thermal conductance of material"; Real TC_345_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_345_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_345_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_345_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_345_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_345_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_345_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998585784304e-05 "Constant thermal conductance of material"; Real TC_346_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_346_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_346_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_346_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_346_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_346_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_346_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.5000121001203e-05 "Constant thermal conductance of material"; Real TC_347_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_347_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_347_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_347_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_347_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_347_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_347_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50002200448892e-05 "Constant thermal conductance of material"; Real TC_348_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_348_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_348_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_348_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_348_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_348_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_348_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50003230539153e-05 "Constant thermal conductance of material"; Real TC_349_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_349_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_349_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_349_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_349_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_349_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_349_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998241179515e-05 "Constant thermal conductance of material"; Real TC_350_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_350_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_350_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_350_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_350_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_350_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_350_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000120838425e-05 "Constant thermal conductance of material"; Real TC_351_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_351_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_351_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_351_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_351_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_351_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_351_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004255151328e-05 "Constant thermal conductance of material"; Real TC_352_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_352_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_352_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_352_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_352_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_352_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_352_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50001234714028e-05 "Constant thermal conductance of material"; Real TC_353_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_353_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_353_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_353_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_353_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_353_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_353_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000164999280043419 "Constant thermal conductance of material"; Real TC_354_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_354_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_354_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_354_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_354_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_354_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_354_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000164998203319968 "Constant thermal conductance of material"; Real TC_355_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_355_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_355_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_355_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_355_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_355_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_355_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49996098626717e-05 "Constant thermal conductance of material"; Real TC_356_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_356_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_356_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_356_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_356_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_356_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_356_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004465127355e-05 "Constant thermal conductance of material"; Real TC_357_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_357_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_357_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_357_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_357_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_357_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_357_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20000548453947e-05 "Constant thermal conductance of material"; Real TC_358_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_358_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_358_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_358_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_358_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_358_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_358_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20000387754706e-05 "Constant thermal conductance of material"; Real TC_359_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_359_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_359_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_359_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_359_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_359_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_359_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49997996607589e-05 "Constant thermal conductance of material"; Real TC_360_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_360_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_360_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_360_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_360_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_360_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_360_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50001890540607e-05 "Constant thermal conductance of material"; Real TC_361_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_361_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_361_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_361_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_361_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_361_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_361_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49987269446947e-05 "Constant thermal conductance of material"; Real TC_362_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_362_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_362_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_362_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_362_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_362_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_362_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50006440670688e-05 "Constant thermal conductance of material"; Real TC_363_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_363_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_363_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_363_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_363_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_363_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_363_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49999059738822e-05 "Constant thermal conductance of material"; Real TC_364_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_364_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_364_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_364_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_364_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_364_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_364_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50007359234204e-05 "Constant thermal conductance of material"; Real TC_365_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_365_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_365_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_365_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_365_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_365_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_365_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50005201991941e-05 "Constant thermal conductance of material"; Real TC_366_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_366_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_366_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_366_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_366_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_366_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_366_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000749973751e-05 "Constant thermal conductance of material"; Real TC_367_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_367_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_367_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_367_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_367_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_367_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_367_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49992106690095e-05 "Constant thermal conductance of material"; Real TC_368_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_368_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_368_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_368_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_368_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_368_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_368_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19998572210456e-05 "Constant thermal conductance of material"; Real TC_369_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_369_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_369_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_369_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_369_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_369_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_369_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20001439642968e-05 "Constant thermal conductance of material"; Real TC_370_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_370_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_370_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_370_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_370_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_370_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_370_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.1999992987156e-05 "Constant thermal conductance of material"; Real TC_371_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_371_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_371_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_371_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_371_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_371_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_371_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999239151862e-05 "Constant thermal conductance of material"; Real TC_372_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_372_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_372_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_372_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_372_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_372_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_372_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000447324552e-05 "Constant thermal conductance of material"; Real TC_373_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_373_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_373_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_373_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_373_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_373_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_373_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50003988892864e-05 "Constant thermal conductance of material"; Real TC_374_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_374_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_374_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_374_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_374_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_374_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_374_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49990263744347e-05 "Constant thermal conductance of material"; Real TC_375_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_375_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_375_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_375_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_375_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_375_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_375_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50009356287425e-05 "Constant thermal conductance of material"; Real TC_376_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_376_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_376_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_376_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_376_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_376_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_376_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49991279576769e-05 "Constant thermal conductance of material"; Real TC_377_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_377_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_377_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_377_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_377_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_377_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_377_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000586930237e-05 "Constant thermal conductance of material"; Real TC_378_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_378_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_378_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_378_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_378_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_378_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_378_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49989011811699e-05 "Constant thermal conductance of material"; Real TC_379_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_379_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_379_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_379_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_379_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_379_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_379_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004246044102e-05 "Constant thermal conductance of material"; Real TC_380_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_380_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_380_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_380_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_380_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_380_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_380_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49989404035885e-05 "Constant thermal conductance of material"; Real TC_381_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_381_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_381_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_381_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_381_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_381_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_381_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20001015451791e-05 "Constant thermal conductance of material"; Real TC_382_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_382_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_382_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_382_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_382_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_382_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_382_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19998563419882e-05 "Constant thermal conductance of material"; Real TC_383_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_383_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_383_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_383_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_383_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_383_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_383_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000731967969e-05 "Constant thermal conductance of material"; Real TC_384_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_384_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_384_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_384_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_384_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_384_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_384_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.500036886339e-05 "Constant thermal conductance of material"; Real TC_385_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_385_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_385_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_385_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_385_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_385_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_385_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999355071023 "Constant thermal conductance of material"; Real TC_386_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_386_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_386_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_386_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_386_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_386_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_386_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999353235913 "Constant thermal conductance of material"; Real TC_387_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_387_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_387_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_387_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_387_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_387_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_387_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70004627895189e-05 "Constant thermal conductance of material"; Real TC_388_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_388_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_388_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_388_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_388_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_388_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_388_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69996256682243e-05 "Constant thermal conductance of material"; Real TC_389_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_389_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_389_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_389_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_389_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_389_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_389_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69998712517914e-05 "Constant thermal conductance of material"; Real TC_390_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_390_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_390_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_390_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_390_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_390_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_390_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69999698051798e-05 "Constant thermal conductance of material"; Real TC_391_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_391_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_391_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_391_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_391_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_391_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_391_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.7000298025191e-05 "Constant thermal conductance of material"; Real TC_392_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_392_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_392_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_392_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_392_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_392_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_392_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69999679570593e-05 "Constant thermal conductance of material"; Real TC_393_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_393_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_393_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_393_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_393_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_393_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_393_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154000715209314 "Constant thermal conductance of material"; Real TC_394_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_394_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_394_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_394_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_394_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_394_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_394_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00015399679749329 "Constant thermal conductance of material"; Real TC_395_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_395_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_395_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_395_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_395_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_395_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_395_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49997823432716e-05 "Constant thermal conductance of material"; Real TC_396_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_396_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_396_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_396_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_396_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_396_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_396_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998277393562e-05 "Constant thermal conductance of material"; Real TC_397_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_397_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_397_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_397_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_397_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_397_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_397_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50001489071754e-05 "Constant thermal conductance of material"; Real TC_398_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_398_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_398_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_398_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_398_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_398_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_398_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49999554331453e-05 "Constant thermal conductance of material"; Real TC_399_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_399_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_399_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_399_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_399_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_399_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_399_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50002793026574e-05 "Constant thermal conductance of material"; Real TC_400_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_400_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_400_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_400_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_400_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_400_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_400_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.5000271061678e-05 "Constant thermal conductance of material"; Real TC_401_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_401_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_401_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_401_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_401_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_401_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_401_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49997129871791e-05 "Constant thermal conductance of material"; Real TC_402_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_402_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_402_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_402_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_402_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_402_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_402_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.5000340946813e-05 "Constant thermal conductance of material"; Real TC_403_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_403_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_403_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_403_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_403_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_403_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_403_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998632297831e-05 "Constant thermal conductance of material"; Real TC_404_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_404_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_404_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_404_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_404_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_404_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_404_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49995944434157e-05 "Constant thermal conductance of material"; Real TC_405_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_405_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_405_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_405_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_405_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_405_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_405_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50001992570857e-05 "Constant thermal conductance of material"; Real TC_406_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_406_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_406_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_406_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_406_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_406_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_406_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000971804706e-05 "Constant thermal conductance of material"; Real TC_407_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_407_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_407_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_407_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_407_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_407_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_407_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000165000202609612 "Constant thermal conductance of material"; Real TC_408_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_408_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_408_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_408_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_408_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_408_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_408_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000164995436376798 "Constant thermal conductance of material"; Real TC_409_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_409_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_409_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_409_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_409_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_409_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_409_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50016535203612e-05 "Constant thermal conductance of material"; Real TC_410_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_410_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_410_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_410_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_410_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_410_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_410_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50013113730906e-05 "Constant thermal conductance of material"; Real TC_411_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_411_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_411_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_411_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_411_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_411_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_411_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20001490950324e-05 "Constant thermal conductance of material"; Real TC_412_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_412_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_412_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_412_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_412_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_412_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_412_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999303052244e-05 "Constant thermal conductance of material"; Real TC_413_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_413_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_413_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_413_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_413_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_413_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_413_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50003844777956e-05 "Constant thermal conductance of material"; Real TC_414_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_414_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_414_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_414_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_414_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_414_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_414_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49996950431441e-05 "Constant thermal conductance of material"; Real TC_415_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_415_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_415_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_415_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_415_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_415_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_415_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.4998798497029e-05 "Constant thermal conductance of material"; Real TC_416_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_416_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_416_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_416_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_416_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_416_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_416_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49995050392357e-05 "Constant thermal conductance of material"; Real TC_417_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_417_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_417_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_417_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_417_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_417_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_417_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50006024015743e-05 "Constant thermal conductance of material"; Real TC_418_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_418_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_418_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_418_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_418_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_418_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_418_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49987100978968e-05 "Constant thermal conductance of material"; Real TC_419_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_419_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_419_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_419_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_419_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_419_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_419_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998459388069e-05 "Constant thermal conductance of material"; Real TC_420_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_420_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_420_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_420_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_420_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_420_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_420_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998206235127e-05 "Constant thermal conductance of material"; Real TC_421_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_421_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_421_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_421_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_421_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_421_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_421_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49986982556626e-05 "Constant thermal conductance of material"; Real TC_422_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_422_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_422_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_422_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_422_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_422_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_422_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999447049019e-05 "Constant thermal conductance of material"; Real TC_423_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_423_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_423_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_423_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_423_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_423_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_423_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20000798913478e-05 "Constant thermal conductance of material"; Real TC_424_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_424_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_424_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_424_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_424_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_424_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_424_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20000070259504e-05 "Constant thermal conductance of material"; Real TC_425_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_425_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_425_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_425_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_425_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_425_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_425_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999506237281e-05 "Constant thermal conductance of material"; Real TC_426_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_426_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_426_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_426_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_426_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_426_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_426_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19998813665181e-05 "Constant thermal conductance of material"; Real TC_427_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_427_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_427_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_427_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_427_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_427_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_427_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000150462371e-05 "Constant thermal conductance of material"; Real TC_428_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_428_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_428_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_428_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_428_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_428_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_428_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49996078738923e-05 "Constant thermal conductance of material"; Real TC_429_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_429_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_429_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_429_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_429_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_429_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_429_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50007583949427e-05 "Constant thermal conductance of material"; Real TC_430_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_430_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_430_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_430_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_430_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_430_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_430_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49990720869478e-05 "Constant thermal conductance of material"; Real TC_431_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_431_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_431_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_431_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_431_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_431_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_431_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49994916212081e-05 "Constant thermal conductance of material"; Real TC_432_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_432_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_432_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_432_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_432_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_432_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_432_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50011343148141e-05 "Constant thermal conductance of material"; Real TC_433_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_433_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_433_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_433_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_433_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_433_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_433_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.4999213032187e-05 "Constant thermal conductance of material"; Real TC_434_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_434_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_434_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_434_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_434_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_434_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_434_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49995801759063e-05 "Constant thermal conductance of material"; Real TC_435_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_435_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_435_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_435_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_435_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_435_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_435_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50001348997695e-05 "Constant thermal conductance of material"; Real TC_436_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_436_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_436_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_436_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_436_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_436_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_436_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999793191164e-05 "Constant thermal conductance of material"; Real TC_437_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_437_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_437_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_437_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_437_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_437_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_437_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999444209005e-05 "Constant thermal conductance of material"; Real TC_438_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_438_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_438_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_438_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_438_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_438_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_438_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50013480722567e-05 "Constant thermal conductance of material"; Real TC_439_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_439_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_439_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_439_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_439_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_439_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_439_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49991805329124e-05 "Constant thermal conductance of material"; Real TC_440_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_440_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_440_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_440_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_440_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_440_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_440_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000541490737 "Constant thermal conductance of material"; Real TC_441_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_441_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_441_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_441_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_441_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_441_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_441_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010999970482281 "Constant thermal conductance of material"; Real TC_442_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_442_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_442_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_442_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_442_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_442_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_442_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69997171075543e-05 "Constant thermal conductance of material"; Real TC_443_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_443_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_443_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_443_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_443_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_443_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_443_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70000911951567e-05 "Constant thermal conductance of material"; Real TC_444_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_444_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_444_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_444_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_444_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_444_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_444_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70000683904683e-05 "Constant thermal conductance of material"; Real TC_445_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_445_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_445_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_445_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_445_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_445_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_445_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70003039742542e-05 "Constant thermal conductance of material"; Real TC_446_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_446_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_446_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_446_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_446_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_446_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_446_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.69999030350044e-05 "Constant thermal conductance of material"; Real TC_447_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_447_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_447_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_447_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_447_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_447_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_447_0.G(quantity = "ThermalConductance", unit = "W/K") = 7.70001849183521e-05 "Constant thermal conductance of material"; Real TC_448_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_448_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_448_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_448_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_448_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_448_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_448_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154002627728055 "Constant thermal conductance of material"; Real TC_449_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_449_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_449_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_449_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_449_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_449_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_449_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00015400105758017 "Constant thermal conductance of material"; Real TC_450_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_450_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_450_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_450_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_450_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_450_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_450_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004280272225e-05 "Constant thermal conductance of material"; Real TC_451_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_451_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_451_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_451_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_451_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_451_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_451_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004117460067e-05 "Constant thermal conductance of material"; Real TC_452_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_452_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_452_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_452_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_452_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_452_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_452_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49995447933891e-05 "Constant thermal conductance of material"; Real TC_453_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_453_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_453_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_453_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_453_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_453_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_453_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49996536269641e-05 "Constant thermal conductance of material"; Real TC_454_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_454_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_454_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_454_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_454_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_454_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_454_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000417418019e-05 "Constant thermal conductance of material"; Real TC_455_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_455_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_455_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_455_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_455_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_455_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_455_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.4999737178701e-05 "Constant thermal conductance of material"; Real TC_456_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_456_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_456_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_456_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_456_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_456_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_456_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.4999557169427e-05 "Constant thermal conductance of material"; Real TC_457_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_457_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_457_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_457_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_457_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_457_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_457_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50004735087351e-05 "Constant thermal conductance of material"; Real TC_458_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_458_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_458_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_458_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_458_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_458_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_458_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998606030004e-05 "Constant thermal conductance of material"; Real TC_459_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_459_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_459_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_459_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_459_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_459_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_459_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50002314060686e-05 "Constant thermal conductance of material"; Real TC_460_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_460_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_460_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_460_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_460_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_460_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_460_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49998883585625e-05 "Constant thermal conductance of material"; Real TC_461_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_461_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_461_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_461_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_461_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_461_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_461_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.5e-05 "Constant thermal conductance of material"; Real TC_462_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_462_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_462_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_462_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_462_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_462_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_462_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000164996601263166 "Constant thermal conductance of material"; Real TC_463_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_463_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_463_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_463_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_463_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_463_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_463_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000165001826495522 "Constant thermal conductance of material"; Real TC_464_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_464_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_464_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_464_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_464_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_464_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_464_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49985808291221e-05 "Constant thermal conductance of material"; Real TC_465_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_465_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_465_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_465_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_465_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_465_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_465_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50008518200555e-05 "Constant thermal conductance of material"; Real TC_466_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_466_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_466_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_466_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_466_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_466_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_466_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.20000943181193e-05 "Constant thermal conductance of material"; Real TC_467_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_467_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_467_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_467_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_467_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_467_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_467_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19998599973555e-05 "Constant thermal conductance of material"; Real TC_468_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_468_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_468_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_468_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_468_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_468_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_468_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50015414103235e-05 "Constant thermal conductance of material"; Real TC_469_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_469_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_469_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_469_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_469_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_469_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_469_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49995030605623e-05 "Constant thermal conductance of material"; Real TC_470_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_470_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_470_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_470_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_470_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_470_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_470_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.5000853622941e-05 "Constant thermal conductance of material"; Real TC_471_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_471_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_471_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_471_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_471_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_471_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_471_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50000810254582e-05 "Constant thermal conductance of material"; Real TC_472_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_472_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_472_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_472_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_472_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_472_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_472_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49992288689808e-05 "Constant thermal conductance of material"; Real TC_473_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_473_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_473_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_473_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_473_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_473_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_473_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49999038559267e-05 "Constant thermal conductance of material"; Real TC_474_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_474_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_474_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_474_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_474_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_474_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_474_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.50006096056844e-05 "Constant thermal conductance of material"; Real TC_475_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_475_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_475_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_475_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_475_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_475_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_475_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49987593127198e-05 "Constant thermal conductance of material"; Real TC_476_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_476_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_476_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_476_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_476_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_476_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_476_0.G(quantity = "ThermalConductance", unit = "W/K") = 5.49996365662782e-05 "Constant thermal conductance of material"; Real TC_477_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_477_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_477_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_477_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_477_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_477_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_477_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999680209783e-05 "Constant thermal conductance of material"; Real TC_478_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_478_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_478_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_478_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_478_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_478_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_478_0.G(quantity = "ThermalConductance", unit = "W/K") = 2.19999435454278e-05 "Constant thermal conductance of material"; Real TC_479_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_479_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_479_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_479_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_479_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_479_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_479_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.40008112060285e-05 "Constant thermal conductance of material"; Real TC_480_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_480_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_480_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_480_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_480_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_480_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_480_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.40015543551701e-05 "Constant thermal conductance of material"; Real TC_481_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_481_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_481_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_481_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_481_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_481_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_481_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110001242917643 "Constant thermal conductance of material"; Real TC_482_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_482_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_482_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_482_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_482_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_482_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_482_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110001052188552 "Constant thermal conductance of material"; Real TC_483_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_483_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_483_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_483_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_483_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_483_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_483_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00011000086097684 "Constant thermal conductance of material"; Real TC_484_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_484_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_484_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_484_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_484_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_484_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_484_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999450146189 "Constant thermal conductance of material"; Real TC_485_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_485_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_485_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_485_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_485_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_485_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_485_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000617527326 "Constant thermal conductance of material"; Real TC_486_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_486_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_486_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_486_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_486_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_486_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_486_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000887645652 "Constant thermal conductance of material"; Real TC_487_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_487_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_487_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_487_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_487_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_487_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_487_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999826919891 "Constant thermal conductance of material"; Real TC_488_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_488_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_488_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_488_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_488_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_488_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_488_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000766463774 "Constant thermal conductance of material"; Real TC_489_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_489_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_489_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_489_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_489_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_489_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_489_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110001150671326 "Constant thermal conductance of material"; Real TC_490_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_490_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_490_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_490_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_490_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_490_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_490_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.40004302881196e-05 "Constant thermal conductance of material"; Real TC_491_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_491_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_491_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_491_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_491_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_491_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_491_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.39996904155468e-05 "Constant thermal conductance of material"; Real TC_492_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_492_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_492_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_492_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_492_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_492_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_492_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999254120982 "Constant thermal conductance of material"; Real TC_493_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_493_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_493_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_493_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_493_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_493_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_493_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998881885964 "Constant thermal conductance of material"; Real TC_494_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_494_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_494_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_494_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_494_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_494_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_494_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000219997590449213 "Constant thermal conductance of material"; Real TC_495_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_495_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_495_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_495_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_495_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_495_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_495_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000220005516605394 "Constant thermal conductance of material"; Real TC_496_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_496_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_496_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_496_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_496_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_496_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_496_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154003146494249 "Constant thermal conductance of material"; Real TC_497_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_497_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_497_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_497_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_497_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_497_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_497_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154002682830104 "Constant thermal conductance of material"; Real TC_498_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_498_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_498_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_498_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_498_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_498_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_498_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154005233636222 "Constant thermal conductance of material"; Real TC_499_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_499_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_499_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_499_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_499_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_499_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_499_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153998638708789 "Constant thermal conductance of material"; Real TC_500_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_500_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_500_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_500_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_500_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_500_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_500_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154003541576827 "Constant thermal conductance of material"; Real TC_501_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_501_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_501_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_501_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_501_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_501_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_501_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00015399592167096 "Constant thermal conductance of material"; Real TC_502_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_502_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_502_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_502_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_502_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_502_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_502_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000307996912415758 "Constant thermal conductance of material"; Real TC_503_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_503_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_503_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_503_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_503_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_503_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_503_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000308003673936156 "Constant thermal conductance of material"; Real TC_504_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_504_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_504_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_504_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_504_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_504_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_504_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999772110936 "Constant thermal conductance of material"; Real TC_505_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_505_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_505_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_505_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_505_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_505_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_505_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110002799428327 "Constant thermal conductance of material"; Real TC_506_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_506_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_506_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_506_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_506_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_506_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_506_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000405440105 "Constant thermal conductance of material"; Real TC_507_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_507_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_507_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_507_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_507_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_507_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_507_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109996146106257 "Constant thermal conductance of material"; Real TC_508_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_508_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_508_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_508_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_508_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_508_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_508_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999656555742 "Constant thermal conductance of material"; Real TC_509_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_509_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_509_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_509_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_509_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_509_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_509_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110002781323076 "Constant thermal conductance of material"; Real TC_510_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_510_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_510_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_510_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_510_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_510_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_510_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999455070568 "Constant thermal conductance of material"; Real TC_511_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_511_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_511_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_511_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_511_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_511_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_511_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010999608941997 "Constant thermal conductance of material"; Real TC_512_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_512_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_512_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_512_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_512_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_512_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_512_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010999789430732 "Constant thermal conductance of material"; Real TC_513_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_513_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_513_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_513_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_513_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_513_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_513_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110001310259331 "Constant thermal conductance of material"; Real TC_514_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_514_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_514_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_514_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_514_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_514_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_514_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000471603835 "Constant thermal conductance of material"; Real TC_515_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_515_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_515_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_515_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_515_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_515_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_515_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109996009407609 "Constant thermal conductance of material"; Real TC_516_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_516_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_516_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_516_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_516_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_516_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_516_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00032999676179334 "Constant thermal conductance of material"; Real TC_517_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_517_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_517_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_517_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_517_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_517_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_517_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000330004028356417 "Constant thermal conductance of material"; Real TC_518_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_518_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_518_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_518_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_518_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_518_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_518_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999138405254 "Constant thermal conductance of material"; Real TC_519_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_519_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_519_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_519_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_519_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_519_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_519_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000238530922 "Constant thermal conductance of material"; Real TC_520_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_520_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_520_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_520_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_520_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_520_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_520_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.40001899801313e-05 "Constant thermal conductance of material"; Real TC_521_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_521_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_521_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_521_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_521_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_521_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_521_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.39993298605565e-05 "Constant thermal conductance of material"; Real TC_522_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_522_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_522_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_522_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_522_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_522_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_522_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999223741364 "Constant thermal conductance of material"; Real TC_523_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_523_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_523_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_523_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_523_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_523_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_523_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999294706774 "Constant thermal conductance of material"; Real TC_524_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_524_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_524_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_524_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_524_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_524_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_524_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000193657442 "Constant thermal conductance of material"; Real TC_525_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_525_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_525_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_525_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_525_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_525_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_525_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999837153884 "Constant thermal conductance of material"; Real TC_526_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_526_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_526_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_526_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_526_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_526_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_526_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00011000111543683 "Constant thermal conductance of material"; Real TC_527_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_527_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_527_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_527_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_527_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_527_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_527_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998949864311 "Constant thermal conductance of material"; Real TC_528_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_528_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_528_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_528_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_528_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_528_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_528_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999600426972 "Constant thermal conductance of material"; Real TC_529_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_529_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_529_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_529_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_529_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_529_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_529_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999329067831 "Constant thermal conductance of material"; Real TC_530_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_530_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_530_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_530_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_530_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_530_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_530_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000489465993 "Constant thermal conductance of material"; Real TC_531_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_531_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_531_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_531_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_531_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_531_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_531_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.3998553868402e-05 "Constant thermal conductance of material"; Real TC_532_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_532_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_532_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_532_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_532_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_532_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_532_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.3999119854613e-05 "Constant thermal conductance of material"; Real TC_533_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_533_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_533_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_533_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_533_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_533_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_533_0.G(quantity = "ThermalConductance", unit = "W/K") = 3.29999242252027e-05 "Constant thermal conductance of material"; Real TC_534_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_534_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_534_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_534_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_534_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_534_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_534_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.40010443720713e-05 "Constant thermal conductance of material"; Real TC_535_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_535_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_535_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_535_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_535_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_535_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_535_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000146094172 "Constant thermal conductance of material"; Real TC_536_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_536_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_536_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_536_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_536_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_536_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_536_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000075809839 "Constant thermal conductance of material"; Real TC_537_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_537_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_537_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_537_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_537_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_537_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_537_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000803771105 "Constant thermal conductance of material"; Real TC_538_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_538_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_538_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_538_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_538_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_538_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_538_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999149947044 "Constant thermal conductance of material"; Real TC_539_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_539_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_539_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_539_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_539_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_539_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_539_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000114117473 "Constant thermal conductance of material"; Real TC_540_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_540_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_540_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_540_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_540_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_540_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_540_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00011000025357366 "Constant thermal conductance of material"; Real TC_541_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_541_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_541_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_541_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_541_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_541_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_541_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000546439 "Constant thermal conductance of material"; Real TC_542_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_542_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_542_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_542_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_542_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_542_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_542_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999212240262 "Constant thermal conductance of material"; Real TC_543_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_543_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_543_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_543_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_543_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_543_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_543_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110001549811829 "Constant thermal conductance of material"; Real TC_544_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_544_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_544_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_544_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_544_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_544_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_544_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.39999454137298e-05 "Constant thermal conductance of material"; Real TC_545_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_545_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_545_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_545_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_545_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_545_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_545_0.G(quantity = "ThermalConductance", unit = "W/K") = 3.30001179839756e-05 "Constant thermal conductance of material"; Real TC_546_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_546_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_546_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_546_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_546_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_546_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_546_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000150220072 "Constant thermal conductance of material"; Real TC_547_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_547_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_547_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_547_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_547_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_547_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_547_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00011000097761267 "Constant thermal conductance of material"; Real TC_548_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_548_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_548_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_548_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_548_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_548_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_548_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275005285103206 "Constant thermal conductance of material"; Real TC_549_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_549_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_549_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_549_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_549_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_549_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_549_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274993376100196 "Constant thermal conductance of material"; Real TC_550_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_550_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_550_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_550_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_550_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_550_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_550_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274993192339112 "Constant thermal conductance of material"; Real TC_551_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_551_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_551_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_551_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_551_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_551_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_551_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275004416180887 "Constant thermal conductance of material"; Real TC_552_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_552_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_552_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_552_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_552_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_552_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_552_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275005003282856 "Constant thermal conductance of material"; Real TC_553_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_553_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_553_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_553_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_553_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_553_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_553_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274995524565262 "Constant thermal conductance of material"; Real TC_554_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_554_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_554_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_554_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_554_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_554_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_554_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998905476993 "Constant thermal conductance of material"; Real TC_555_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_555_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_555_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_555_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_555_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_555_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_555_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997370030819 "Constant thermal conductance of material"; Real TC_556_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_556_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_556_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_556_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_556_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_556_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_556_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997967828467 "Constant thermal conductance of material"; Real TC_557_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_557_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_557_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_557_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_557_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_557_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_557_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998888703673 "Constant thermal conductance of material"; Real TC_558_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_558_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_558_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_558_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_558_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_558_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_558_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999226342445 "Constant thermal conductance of material"; Real TC_559_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_559_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_559_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_559_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_559_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_559_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_559_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000219998456953283 "Constant thermal conductance of material"; Real TC_560_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_560_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_560_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_560_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_560_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_560_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_560_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000220003201845096 "Constant thermal conductance of material"; Real TC_561_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_561_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_561_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_561_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_561_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_561_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_561_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000549997847497596 "Constant thermal conductance of material"; Real TC_562_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_562_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_562_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_562_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_562_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_562_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_562_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000549995960444001 "Constant thermal conductance of material"; Real TC_563_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_563_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_563_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_563_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_563_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_563_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_563_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550001388651936 "Constant thermal conductance of material"; Real TC_564_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_564_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_564_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_564_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_564_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_564_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_564_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550003055357666 "Constant thermal conductance of material"; Real TC_565_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_565_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_565_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_565_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_565_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_565_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_565_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550000115391095 "Constant thermal conductance of material"; Real TC_566_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_566_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_566_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_566_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_566_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_566_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_566_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550000077566401 "Constant thermal conductance of material"; Real TC_567_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_567_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_567_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_567_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_567_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_567_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_567_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000549997021504736 "Constant thermal conductance of material"; Real TC_568_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_568_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_568_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_568_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_568_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_568_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_568_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000550003195199801 "Constant thermal conductance of material"; Real TC_569_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_569_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_569_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_569_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_569_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_569_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_569_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000549999227542736 "Constant thermal conductance of material"; Real TC_570_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_570_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_570_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_570_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_570_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_570_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_570_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000220004166402493 "Constant thermal conductance of material"; Real TC_571_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_571_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_571_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_571_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_571_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_571_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_571_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.0002199962791327 "Constant thermal conductance of material"; Real TC_572_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_572_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_572_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_572_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_572_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_572_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_572_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153995902771214 "Constant thermal conductance of material"; Real TC_573_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_573_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_573_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_573_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_573_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_573_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_573_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153994963034445 "Constant thermal conductance of material"; Real TC_574_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_574_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_574_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_574_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_574_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_574_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_574_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385001347610661 "Constant thermal conductance of material"; Real TC_575_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_575_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_575_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_575_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_575_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_575_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_575_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384998089858063 "Constant thermal conductance of material"; Real TC_576_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_576_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_576_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_576_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_576_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_576_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_576_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384997980685049 "Constant thermal conductance of material"; Real TC_577_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_577_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_577_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_577_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_577_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_577_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_577_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384997163925128 "Constant thermal conductance of material"; Real TC_578_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_578_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_578_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_578_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_578_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_578_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_578_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384998967172663 "Constant thermal conductance of material"; Real TC_579_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_579_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_579_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_579_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_579_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_579_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_579_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384997055288749 "Constant thermal conductance of material"; Real TC_580_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_580_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_580_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_580_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_580_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_580_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_580_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385002835776937 "Constant thermal conductance of material"; Real TC_581_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_581_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_581_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_581_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_581_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_581_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_581_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384996678640851 "Constant thermal conductance of material"; Real TC_582_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_582_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_582_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_582_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_582_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_582_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_582_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384996898101369 "Constant thermal conductance of material"; Real TC_583_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_583_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_583_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_583_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_583_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_583_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_583_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154001752795795 "Constant thermal conductance of material"; Real TC_584_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_584_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_584_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_584_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_584_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_584_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_584_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153998882036651 "Constant thermal conductance of material"; Real TC_585_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_585_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_585_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_585_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_585_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_585_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_585_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154000788472672 "Constant thermal conductance of material"; Real TC_586_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_586_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_586_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_586_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_586_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_586_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_586_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154004117967002 "Constant thermal conductance of material"; Real TC_587_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_587_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_587_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_587_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_587_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_587_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_587_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384995943979884 "Constant thermal conductance of material"; Real TC_588_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_588_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_588_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_588_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_588_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_588_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_588_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385001998971957 "Constant thermal conductance of material"; Real TC_589_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_589_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_589_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_589_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_589_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_589_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_589_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384997081911532 "Constant thermal conductance of material"; Real TC_590_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_590_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_590_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_590_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_590_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_590_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_590_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385002157382516 "Constant thermal conductance of material"; Real TC_591_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_591_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_591_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_591_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_591_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_591_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_591_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.0003850020001436 "Constant thermal conductance of material"; Real TC_592_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_592_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_592_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_592_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_592_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_592_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_592_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385002665744463 "Constant thermal conductance of material"; Real TC_593_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_593_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_593_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_593_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_593_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_593_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_593_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384998620952708 "Constant thermal conductance of material"; Real TC_594_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_594_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_594_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_594_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_594_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_594_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_594_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384997594201502 "Constant thermal conductance of material"; Real TC_595_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_595_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_595_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_595_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_595_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_595_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_595_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384998880817207 "Constant thermal conductance of material"; Real TC_596_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_596_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_596_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_596_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_596_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_596_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_596_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00015400403317073 "Constant thermal conductance of material"; Real TC_597_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_597_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_597_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_597_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_597_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_597_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_597_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000154001793690887 "Constant thermal conductance of material"; Real TC_598_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_598_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_598_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_598_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_598_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_598_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_598_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153996850919619 "Constant thermal conductance of material"; Real TC_599_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_599_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_599_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_599_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_599_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_599_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_599_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153999711724678 "Constant thermal conductance of material"; Real TC_600_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_600_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_600_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_600_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_600_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_600_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_600_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385000896996789 "Constant thermal conductance of material"; Real TC_601_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_601_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_601_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_601_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_601_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_601_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_601_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384997129498191 "Constant thermal conductance of material"; Real TC_602_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_602_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_602_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_602_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_602_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_602_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_602_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384997378364707 "Constant thermal conductance of material"; Real TC_603_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_603_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_603_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_603_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_603_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_603_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_603_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00038500138089772 "Constant thermal conductance of material"; Real TC_604_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_604_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_604_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_604_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_604_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_604_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_604_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385002702340643 "Constant thermal conductance of material"; Real TC_605_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_605_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_605_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_605_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_605_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_605_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_605_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385000408358515 "Constant thermal conductance of material"; Real TC_606_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_606_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_606_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_606_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_606_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_606_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_606_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384999978698684 "Constant thermal conductance of material"; Real TC_607_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_607_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_607_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_607_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_607_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_607_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_607_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000385001620147936 "Constant thermal conductance of material"; Real TC_608_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_608_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_608_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_608_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_608_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_608_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_608_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000384996077987401 "Constant thermal conductance of material"; Real TC_609_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_609_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_609_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_609_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_609_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_609_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_609_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153997654005245 "Constant thermal conductance of material"; Real TC_610_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_610_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_610_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_610_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_610_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_610_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_610_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000153997371766792 "Constant thermal conductance of material"; Real TC_611_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_611_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_611_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_611_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_611_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_611_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_611_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000307996930452 "Constant thermal conductance of material"; Real TC_612_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_612_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_612_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_612_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_612_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_612_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_612_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000308005093703374 "Constant thermal conductance of material"; Real TC_613_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_613_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_613_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_613_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_613_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_613_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_613_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000770003001700964 "Constant thermal conductance of material"; Real TC_614_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_614_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_614_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_614_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_614_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_614_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_614_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00076997042016856 "Constant thermal conductance of material"; Real TC_615_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_615_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_615_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_615_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_615_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_615_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_615_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000770000386158669 "Constant thermal conductance of material"; Real TC_616_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_616_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_616_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_616_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_616_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_616_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_616_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000770020145235655 "Constant thermal conductance of material"; Real TC_617_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_617_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_617_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_617_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_617_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_617_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_617_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000769981073893952 "Constant thermal conductance of material"; Real TC_618_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_618_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_618_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_618_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_618_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_618_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_618_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000770002335838635 "Constant thermal conductance of material"; Real TC_619_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_619_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_619_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_619_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_619_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_619_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_619_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000769973680112458 "Constant thermal conductance of material"; Real TC_620_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_620_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_620_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_620_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_620_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_620_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_620_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000770032143644007 "Constant thermal conductance of material"; Real TC_621_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_621_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_621_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_621_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_621_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_621_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_621_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000770002137738925 "Constant thermal conductance of material"; Real TC_622_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_622_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_622_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_622_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_622_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_622_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_622_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000308002070058544 "Constant thermal conductance of material"; Real TC_623_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_623_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_623_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_623_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_623_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_623_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_623_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000308004546019947 "Constant thermal conductance of material"; Real TC_624_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_624_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_624_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_624_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_624_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_624_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_624_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999473865742 "Constant thermal conductance of material"; Real TC_625_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_625_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_625_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_625_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_625_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_625_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_625_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109997539784278 "Constant thermal conductance of material"; Real TC_626_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_626_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_626_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_626_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_626_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_626_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_626_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274996460474198 "Constant thermal conductance of material"; Real TC_627_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_627_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_627_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_627_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_627_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_627_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_627_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275 "Constant thermal conductance of material"; Real TC_628_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_628_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_628_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_628_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_628_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_628_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_628_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001320651373 "Constant thermal conductance of material"; Real TC_629_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_629_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_629_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_629_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_629_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_629_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_629_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998050047415 "Constant thermal conductance of material"; Real TC_630_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_630_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_630_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_630_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_630_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_630_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_630_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00027500212876098 "Constant thermal conductance of material"; Real TC_631_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_631_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_631_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_631_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_631_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_631_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_631_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000976542457 "Constant thermal conductance of material"; Real TC_632_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_632_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_632_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_632_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_632_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_632_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_632_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999068589099 "Constant thermal conductance of material"; Real TC_633_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_633_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_633_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_633_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_633_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_633_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_633_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001405050828 "Constant thermal conductance of material"; Real TC_634_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_634_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_634_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_634_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_634_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_634_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_634_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999465243607 "Constant thermal conductance of material"; Real TC_635_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_635_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_635_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_635_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_635_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_635_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_635_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110001222016801 "Constant thermal conductance of material"; Real TC_636_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_636_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_636_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_636_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_636_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_636_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_636_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010999892056164 "Constant thermal conductance of material"; Real TC_637_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_637_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_637_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_637_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_637_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_637_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_637_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999630532772 "Constant thermal conductance of material"; Real TC_638_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_638_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_638_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_638_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_638_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_638_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_638_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110003832886163 "Constant thermal conductance of material"; Real TC_639_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_639_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_639_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_639_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_639_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_639_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_639_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002270132835 "Constant thermal conductance of material"; Real TC_640_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_640_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_640_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_640_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_640_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_640_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_640_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001561621588 "Constant thermal conductance of material"; Real TC_641_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_641_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_641_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_641_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_641_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_641_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_641_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275003146761557 "Constant thermal conductance of material"; Real TC_642_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_642_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_642_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_642_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_642_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_642_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_642_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000033480245 "Constant thermal conductance of material"; Real TC_643_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_643_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_643_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_643_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_643_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_643_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_643_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001259822525 "Constant thermal conductance of material"; Real TC_644_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_644_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_644_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_644_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_644_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_644_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_644_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002603617939 "Constant thermal conductance of material"; Real TC_645_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_645_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_645_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_645_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_645_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_645_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_645_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997065277264 "Constant thermal conductance of material"; Real TC_646_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_646_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_646_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_646_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_646_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_646_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_646_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998073402724 "Constant thermal conductance of material"; Real TC_647_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_647_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_647_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_647_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_647_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_647_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_647_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275003302743274 "Constant thermal conductance of material"; Real TC_648_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_648_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_648_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_648_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_648_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_648_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_648_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110003793567967 "Constant thermal conductance of material"; Real TC_649_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_649_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_649_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_649_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_649_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_649_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_649_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110002516330576 "Constant thermal conductance of material"; Real TC_650_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_650_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_650_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_650_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_650_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_650_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_650_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000215304526 "Constant thermal conductance of material"; Real TC_651_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_651_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_651_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_651_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_651_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_651_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_651_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998936704744 "Constant thermal conductance of material"; Real TC_652_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_652_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_652_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_652_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_652_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_652_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_652_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997396679741 "Constant thermal conductance of material"; Real TC_653_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_653_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_653_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_653_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_653_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_653_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_653_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002452298565 "Constant thermal conductance of material"; Real TC_654_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_654_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_654_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_654_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_654_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_654_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_654_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000904565731 "Constant thermal conductance of material"; Real TC_655_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_655_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_655_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_655_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_655_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_655_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_655_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998975031774 "Constant thermal conductance of material"; Real TC_656_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_656_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_656_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_656_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_656_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_656_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_656_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001531721962 "Constant thermal conductance of material"; Real TC_657_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_657_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_657_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_657_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_657_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_657_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_657_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002247765248 "Constant thermal conductance of material"; Real TC_658_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_658_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_658_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_658_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_658_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_658_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_658_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002459060327 "Constant thermal conductance of material"; Real TC_659_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_659_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_659_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_659_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_659_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_659_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_659_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998589130663 "Constant thermal conductance of material"; Real TC_660_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_660_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_660_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_660_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_660_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_660_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_660_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000991104456 "Constant thermal conductance of material"; Real TC_661_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_661_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_661_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_661_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_661_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_661_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_661_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.0001099976286551 "Constant thermal conductance of material"; Real TC_662_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_662_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_662_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_662_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_662_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_662_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_662_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999071694749 "Constant thermal conductance of material"; Real TC_663_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_663_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_663_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_663_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_663_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_663_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_663_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000210953833 "Constant thermal conductance of material"; Real TC_664_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_664_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_664_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_664_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_664_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_664_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_664_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000010163542 "Constant thermal conductance of material"; Real TC_665_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_665_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_665_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_665_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_665_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_665_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_665_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999772846356 "Constant thermal conductance of material"; Real TC_666_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_666_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_666_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_666_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_666_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_666_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_666_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.0002750025917903 "Constant thermal conductance of material"; Real TC_667_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_667_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_667_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_667_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_667_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_667_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_667_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000820751832 "Constant thermal conductance of material"; Real TC_668_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_668_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_668_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_668_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_668_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_668_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_668_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999360615297 "Constant thermal conductance of material"; Real TC_669_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_669_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_669_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_669_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_669_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_669_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_669_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998595321484 "Constant thermal conductance of material"; Real TC_670_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_670_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_670_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_670_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_670_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_670_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_670_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997245416613 "Constant thermal conductance of material"; Real TC_671_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_671_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_671_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_671_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_671_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_671_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_671_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998900630887 "Constant thermal conductance of material"; Real TC_672_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_672_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_672_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_672_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_672_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_672_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_672_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997158529903 "Constant thermal conductance of material"; Real TC_673_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_673_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_673_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_673_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_673_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_673_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_673_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997581971177 "Constant thermal conductance of material"; Real TC_674_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_674_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_674_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_674_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_674_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_674_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_674_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00010999978515667 "Constant thermal conductance of material"; Real TC_675_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_675_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_675_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_675_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_675_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_675_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_675_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998822768889 "Constant thermal conductance of material"; Real TC_676_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_676_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_676_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_676_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_676_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_676_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_676_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999833604189 "Constant thermal conductance of material"; Real TC_677_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_677_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_677_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_677_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_677_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_677_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_677_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110001884357201 "Constant thermal conductance of material"; Real TC_678_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_678_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_678_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_678_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_678_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_678_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_678_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000581404508 "Constant thermal conductance of material"; Real TC_679_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_679_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_679_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_679_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_679_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_679_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_679_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001171265043 "Constant thermal conductance of material"; Real TC_680_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_680_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_680_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_680_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_680_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_680_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_680_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997959579983 "Constant thermal conductance of material"; Real TC_681_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_681_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_681_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_681_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_681_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_681_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_681_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997607994055 "Constant thermal conductance of material"; Real TC_682_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_682_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_682_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_682_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_682_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_682_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_682_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997916296849 "Constant thermal conductance of material"; Real TC_683_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_683_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_683_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_683_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_683_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_683_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_683_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275003066010049 "Constant thermal conductance of material"; Real TC_684_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_684_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_684_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_684_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_684_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_684_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_684_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999613755153 "Constant thermal conductance of material"; Real TC_685_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_685_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_685_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_685_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_685_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_685_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_685_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997284169033 "Constant thermal conductance of material"; Real TC_686_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_686_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_686_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_686_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_686_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_686_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_686_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002423498239 "Constant thermal conductance of material"; Real TC_687_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_687_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_687_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_687_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_687_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_687_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_687_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110002069985712 "Constant thermal conductance of material"; Real TC_688_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_688_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_688_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_688_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_688_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_688_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_688_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109997412451963 "Constant thermal conductance of material"; Real TC_689_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_689_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_689_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_689_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_689_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_689_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_689_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999703354152 "Constant thermal conductance of material"; Real TC_690_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_690_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_690_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_690_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_690_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_690_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_690_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110004235334763 "Constant thermal conductance of material"; Real TC_691_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_691_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_691_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_691_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_691_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_691_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_691_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999155148525 "Constant thermal conductance of material"; Real TC_692_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_692_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_692_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_692_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_692_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_692_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_692_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001995638236 "Constant thermal conductance of material"; Real TC_693_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_693_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_693_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_693_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_693_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_693_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_693_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999174481096 "Constant thermal conductance of material"; Real TC_694_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_694_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_694_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_694_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_694_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_694_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_694_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275001283728869 "Constant thermal conductance of material"; Real TC_695_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_695_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_695_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_695_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_695_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_695_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_695_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274997483756249 "Constant thermal conductance of material"; Real TC_696_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_696_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_696_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_696_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_696_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_696_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_696_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275000637740592 "Constant thermal conductance of material"; Real TC_697_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_697_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_697_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_697_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_697_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_697_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_697_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002131469008 "Constant thermal conductance of material"; Real TC_698_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_698_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_698_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_698_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_698_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_698_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_698_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002549628424 "Constant thermal conductance of material"; Real TC_699_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_699_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_699_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_699_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_699_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_699_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_699_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275 "Constant thermal conductance of material"; Real TC_700_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_700_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_700_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_700_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_700_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_700_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_700_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109995693290316 "Constant thermal conductance of material"; Real TC_701_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_701_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_701_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_701_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_701_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_701_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_701_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999888069307 "Constant thermal conductance of material"; Real TC_702_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_702_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_702_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_702_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_702_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_702_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_702_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000330005748812731 "Constant thermal conductance of material"; Real TC_703_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_703_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_703_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_703_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_703_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_703_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_703_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000330001983810174 "Constant thermal conductance of material"; Real TC_704_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_704_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_704_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_704_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_704_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_704_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_704_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000824996088773663 "Constant thermal conductance of material"; Real TC_705_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_705_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_705_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_705_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_705_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_705_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_705_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000825016829939101 "Constant thermal conductance of material"; Real TC_706_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_706_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_706_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_706_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_706_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_706_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_706_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000825017320350926 "Constant thermal conductance of material"; Real TC_707_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_707_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_707_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_707_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_707_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_707_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_707_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000825024140313802 "Constant thermal conductance of material"; Real TC_708_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_708_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_708_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_708_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_708_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_708_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_708_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000824985045016394 "Constant thermal conductance of material"; Real TC_709_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_709_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_709_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_709_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_709_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_709_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_709_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000825025967336209 "Constant thermal conductance of material"; Real TC_710_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_710_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_710_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_710_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_710_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_710_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_710_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000825017827374347 "Constant thermal conductance of material"; Real TC_711_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_711_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_711_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_711_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_711_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_711_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_711_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000825006814664994 "Constant thermal conductance of material"; Real TC_712_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_712_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_712_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_712_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_712_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_712_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_712_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000824994781549062 "Constant thermal conductance of material"; Real TC_713_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_713_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_713_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_713_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_713_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_713_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_713_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000329995276809133 "Constant thermal conductance of material"; Real TC_714_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_714_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_714_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_714_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_714_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_714_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_714_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000329995438987209 "Constant thermal conductance of material"; Real TC_715_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_715_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_715_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_715_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_715_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_715_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_715_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998399829315 "Constant thermal conductance of material"; Real TC_716_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_716_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_716_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_716_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_716_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_716_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_716_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110001146813872 "Constant thermal conductance of material"; Real TC_717_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_717_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_717_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_717_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_717_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_717_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_717_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275010193437677 "Constant thermal conductance of material"; Real TC_718_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_718_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_718_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_718_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_718_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_718_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_718_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002532747891 "Constant thermal conductance of material"; Real TC_719_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_719_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_719_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_719_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_719_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_719_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_719_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275002954829822 "Constant thermal conductance of material"; Real TC_720_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_720_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_720_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_720_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_720_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_720_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_720_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274996686786906 "Constant thermal conductance of material"; Real TC_721_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_721_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_721_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_721_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_721_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_721_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_721_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00027499742549587 "Constant thermal conductance of material"; Real TC_722_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_722_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_722_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_722_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_722_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_722_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_722_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275006823354135 "Constant thermal conductance of material"; Real TC_723_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_723_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_723_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_723_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_723_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_723_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_723_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274998096752637 "Constant thermal conductance of material"; Real TC_724_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_724_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_724_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_724_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_724_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_724_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_724_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000275011373412789 "Constant thermal conductance of material"; Real TC_725_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_725_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_725_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_725_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_725_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_725_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_725_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000274999478525688 "Constant thermal conductance of material"; Real TC_726_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_726_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_726_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_726_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_726_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_726_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_726_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998748592166 "Constant thermal conductance of material"; Real TC_727_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_727_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_727_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_727_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_727_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_727_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_727_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.00011000003439866 "Constant thermal conductance of material"; Real TC_728_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_728_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_728_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_728_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_728_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_728_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_728_0.G(quantity = "ThermalConductance", unit = "W/K") = 3.29999037412565e-05 "Constant thermal conductance of material"; Real TC_729_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_729_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_729_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_729_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_729_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_729_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_729_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.40001986120076e-05 "Constant thermal conductance of material"; Real TC_730_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_730_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_730_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_730_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_730_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_730_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_730_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998926839738 "Constant thermal conductance of material"; Real TC_731_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_731_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_731_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_731_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_731_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_731_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_731_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998730588584 "Constant thermal conductance of material"; Real TC_732_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_732_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_732_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_732_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_732_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_732_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_732_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998379172634 "Constant thermal conductance of material"; Real TC_733_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_733_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_733_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_733_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_733_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_733_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_733_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109998277688763 "Constant thermal conductance of material"; Real TC_734_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_734_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_734_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_734_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_734_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_734_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_734_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000078549042 "Constant thermal conductance of material"; Real TC_735_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_735_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_735_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_735_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_735_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_735_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_735_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999042237334 "Constant thermal conductance of material"; Real TC_736_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_736_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_736_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_736_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_736_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_736_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_736_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000769120895 "Constant thermal conductance of material"; Real TC_737_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_737_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_737_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_737_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_737_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_737_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_737_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000109999559813948 "Constant thermal conductance of material"; Real TC_738_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_738_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_738_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_738_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_738_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_738_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_738_0.G(quantity = "ThermalConductance", unit = "W/K") = 0.000110000574027614 "Constant thermal conductance of material"; Real TC_739_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_739_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_739_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_739_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_739_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_739_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_739_0.G(quantity = "ThermalConductance", unit = "W/K") = 4.40006155035885e-05 "Constant thermal conductance of material"; Real TC_740_0.Q_flow(quantity = "Power", unit = "W") "Heat flow rate from port_a -> port_b"; Real TC_740_0.dT(quantity = "ThermodynamicTemperature", unit = "K") "port_a.T - port_b.T"; Real TC_740_0.port_a.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_740_0.port_a.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; Real TC_740_0.port_b.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TC_740_0.port_b.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real TC_740_0.G(quantity = "ThermalConductance", unit = "W/K") = 3.29999089908743e-05 "Constant thermal conductance of material"; parameter Real HFIC101.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC101.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC101.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC101.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC101.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC102.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC102.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC102.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC102.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC102.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC103.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC103.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC103.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC103.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC103.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC104.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC104.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC104.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC104.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC104.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC105.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC105.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC105.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC105.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC105.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC106.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC106.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC106.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC106.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC106.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC107.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC107.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC107.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC107.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC107.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC108.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC108.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC108.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC108.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC108.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC109.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC109.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC109.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC109.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC109.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC201.Q_flow(quantity = "Power", unit = "W") = 0.08 "Fixed heat flow rate at port"; parameter Real HFIC201.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC201.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC201.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC201.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC202.Q_flow(quantity = "Power", unit = "W") = 0.08 "Fixed heat flow rate at port"; parameter Real HFIC202.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC202.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC202.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC202.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC203.Q_flow(quantity = "Power", unit = "W") = 0.08 "Fixed heat flow rate at port"; parameter Real HFIC203.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC203.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC203.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC203.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC204.Q_flow(quantity = "Power", unit = "W") = 0.08 "Fixed heat flow rate at port"; parameter Real HFIC204.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC204.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC204.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC204.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC205.Q_flow(quantity = "Power", unit = "W") = 0.08 "Fixed heat flow rate at port"; parameter Real HFIC205.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC205.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC205.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC205.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC206.Q_flow(quantity = "Power", unit = "W") = 0.08 "Fixed heat flow rate at port"; parameter Real HFIC206.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC206.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC206.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC206.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC207.Q_flow(quantity = "Power", unit = "W") = 0.08 "Fixed heat flow rate at port"; parameter Real HFIC207.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC207.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC207.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC207.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC208.Q_flow(quantity = "Power", unit = "W") = 0.08 "Fixed heat flow rate at port"; parameter Real HFIC208.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC208.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC208.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC208.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC209.Q_flow(quantity = "Power", unit = "W") = 0.08 "Fixed heat flow rate at port"; parameter Real HFIC209.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC209.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC209.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC209.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC301.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC301.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC301.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC301.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC301.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC302.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC302.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC302.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC302.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC302.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC303.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC303.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC303.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC303.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC303.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC304.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC304.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC304.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC304.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC304.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC305.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC305.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC305.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC305.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC305.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC306.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC306.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC306.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC306.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC306.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC307.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC307.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC307.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC307.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC307.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC308.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC308.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC308.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC308.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC308.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC309.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC309.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC309.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC309.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC309.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC310.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC310.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC310.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC310.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC310.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC311.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC311.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC311.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC311.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC311.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC312.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC312.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC312.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC312.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC312.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC401.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC401.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC401.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC401.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC401.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC402.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC402.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC402.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC402.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC402.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC403.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC403.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC403.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC403.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC403.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC404.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC404.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC404.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC404.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC404.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC405.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC405.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC405.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC405.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC405.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC406.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC406.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC406.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC406.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC406.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC407.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC407.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC407.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC407.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC407.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC408.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC408.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC408.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC408.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC408.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC409.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC409.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC409.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC409.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC409.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC501.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC501.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC501.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC501.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC501.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC502.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC502.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC502.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC502.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC502.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC503.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC503.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC503.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC503.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC503.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC504.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC504.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC504.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC504.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC504.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC505.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC505.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC505.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC505.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC505.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC506.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC506.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC506.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC506.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC506.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC507.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC507.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC507.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC507.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC507.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC508.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC508.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC508.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC508.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC508.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC509.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC509.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC509.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC509.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC509.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC510.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC510.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC510.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC510.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC510.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC511.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC511.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC511.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC511.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC511.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC512.Q_flow(quantity = "Power", unit = "W") = 0.02 "Fixed heat flow rate at port"; parameter Real HFIC512.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC512.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC512.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC512.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC601.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC601.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC601.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC601.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC601.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC602.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC602.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC602.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC602.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC602.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC603.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC603.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC603.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC603.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC603.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC604.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC604.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC604.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC604.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC604.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC605.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC605.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC605.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC605.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC605.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC606.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC606.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC606.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC606.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC606.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC607.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC607.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC607.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC607.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC607.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC608.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC608.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC608.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC608.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC608.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real HFIC609.Q_flow(quantity = "Power", unit = "W") = 0.03 "Fixed heat flow rate at port"; parameter Real HFIC609.T_ref(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) = 293.15 "Reference temperature"; parameter Real HFIC609.alpha(quantity = "LinearTemperatureCoefficient", unit = "1/K") = 0.0 "Temperature coefficient of heat flow rate"; Real HFIC609.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real HFIC609.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp001.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp002.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp003.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp004.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp005.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp006.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp007.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp008.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp009.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp009.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp009.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp010.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp010.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp010.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp011.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp011.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp011.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp012.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp012.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp012.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp013.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp013.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp013.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp014.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp014.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp014.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp015.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp015.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp015.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp016.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp016.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp016.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp017.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp017.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp017.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp018.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp018.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp018.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp019.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp019.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp019.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp020.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp020.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp020.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp021.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp021.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp021.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp022.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp022.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp022.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp023.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp023.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp023.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp024.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp024.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp024.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp025.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp025.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp025.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp026.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp026.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp026.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp027.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp027.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp027.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp028.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp028.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp028.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp029.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp029.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp029.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp030.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp030.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp030.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp031.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp031.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp031.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp032.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp032.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp032.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp033.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp033.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp033.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp034.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp034.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp034.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp035.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp035.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp035.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp036.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp036.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp036.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp037.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp037.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp037.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp038.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp038.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp038.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp039.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp039.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp039.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp040.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp040.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp040.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp041.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp041.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp041.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp042.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp042.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp042.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp043.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp043.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp043.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp044.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp044.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp044.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp045.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp045.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp045.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp046.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp046.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp046.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp047.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp047.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp047.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp048.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp048.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp048.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp049.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp049.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp049.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp050.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp050.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp050.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp051.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp051.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp051.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp052.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp052.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp052.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp053.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp053.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp053.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp054.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp054.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp054.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp055.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp055.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp055.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp056.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp056.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp056.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp057.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp057.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp057.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp058.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp058.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp058.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp059.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp059.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp059.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp060.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp060.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp060.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp061.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp061.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp061.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp062.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp062.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp062.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp063.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp063.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp063.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp064.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp064.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp064.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp065.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp065.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp065.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp066.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp066.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp066.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp067.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp067.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp067.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp068.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp068.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp068.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp069.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp069.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp069.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp070.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp070.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp070.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp071.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp071.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp071.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp072.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp072.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp072.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp073.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp073.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp073.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp074.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp074.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp074.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp075.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp075.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp075.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp076.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp076.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp076.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp077.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp077.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp077.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp078.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp078.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp078.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp079.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp079.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp079.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp080.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp080.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp080.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp081.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp081.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp081.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp082.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp082.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp082.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp083.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp083.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp083.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp084.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp084.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp084.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp085.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp085.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp085.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp086.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp086.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp086.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp087.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp087.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp087.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp088.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp088.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp088.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp089.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp089.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp089.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp090.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp090.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp090.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp091.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp091.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp091.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp092.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp092.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp092.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp093.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp093.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp093.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp094.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp094.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp094.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp095.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp095.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp095.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp096.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp096.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp096.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp097.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp097.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp097.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp098.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp098.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp098.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp099.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp099.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp099.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp100.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp100.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp100.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp101.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp101.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp101.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp102.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp102.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp102.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp103.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp103.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp103.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp104.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp104.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp104.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp105.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp105.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp105.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp106.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp106.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp106.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp107.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp107.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp107.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp108.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp108.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp108.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp109.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp109.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp109.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp110.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp110.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp110.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp111.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp111.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp111.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp112.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp112.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp112.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp113.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp113.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp113.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp114.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp114.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp114.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp115.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp115.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp115.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp116.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp116.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp116.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp117.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp117.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp117.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp118.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp118.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp118.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp119.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp119.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp119.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp120.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp120.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp120.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp121.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp121.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp121.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp122.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp122.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp122.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp123.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp123.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp123.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp124.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp124.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp124.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp125.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp125.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp125.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp126.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp126.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp126.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp127.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp127.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp127.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp128.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp128.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp128.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp129.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp129.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp129.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp130.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp130.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp130.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp131.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp131.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp131.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp132.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp132.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp132.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp133.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp133.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp133.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp134.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp134.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp134.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp135.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp135.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp135.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp136.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp136.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp136.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp137.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp137.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp137.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp138.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp138.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp138.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp139.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp139.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp139.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp140.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp140.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp140.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp141.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp141.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp141.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp142.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp142.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp142.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp143.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp143.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp143.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp144.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp144.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp144.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp145.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp145.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp145.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp146.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp146.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp146.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp147.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp147.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp147.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp148.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp148.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp148.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp149.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp149.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp149.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp150.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp150.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp150.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp151.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp151.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp151.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp152.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp152.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp152.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp153.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp153.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp153.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp154.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp154.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp154.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp155.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp155.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp155.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp156.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp156.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp156.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp157.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp157.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp157.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp158.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp158.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp158.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp159.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp159.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp159.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp160.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp160.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp160.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp161.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp161.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp161.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp162.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp162.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp162.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp163.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp163.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp163.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp164.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp164.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp164.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp165.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp165.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp165.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp166.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp166.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp166.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp167.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp167.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp167.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp168.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp168.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp168.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp169.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp169.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp169.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp170.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp170.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp170.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp171.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp171.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp171.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp172.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp172.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp172.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp173.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp173.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp173.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp174.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp174.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp174.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp175.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp175.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp175.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp176.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp176.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp176.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp177.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp177.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp177.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp178.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp178.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp178.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp179.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp179.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp179.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp180.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp180.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp180.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp181.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp181.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp181.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp182.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp182.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp182.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp183.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp183.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp183.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp184.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp184.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp184.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp185.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp185.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp185.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp186.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp186.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp186.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp187.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp187.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp187.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp188.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp188.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp188.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp189.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp189.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp189.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp190.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp190.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp190.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp191.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp191.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp191.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp192.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp192.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp192.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp193.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp193.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp193.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp194.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp194.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp194.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp195.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp195.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp195.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp196.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp196.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp196.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp197.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp197.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp197.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp198.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp198.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp198.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp199.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp199.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp199.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp200.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp200.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp200.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp201.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp201.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp201.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp202.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp202.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp202.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp203.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp203.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp203.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp204.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp204.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp204.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp205.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp205.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp205.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp206.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp206.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp206.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp207.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp207.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp207.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp208.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp208.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp208.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp209.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp209.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp209.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp210.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp210.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp210.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp211.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp211.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp211.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp212.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp212.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp212.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp213.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp213.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp213.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp214.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp214.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp214.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp215.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp215.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp215.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp216.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp216.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp216.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp217.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp217.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp217.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp218.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp218.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp218.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp219.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp219.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp219.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp220.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp220.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp220.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp221.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp221.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp221.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp222.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp222.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp222.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp223.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp223.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp223.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp224.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp224.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp224.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp225.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp225.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp225.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp226.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp226.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp226.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp227.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp227.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp227.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp228.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp228.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp228.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp229.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp229.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp229.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp230.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp230.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp230.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp231.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp231.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp231.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp232.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp232.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp232.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp233.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp233.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp233.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp234.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp234.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp234.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp235.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp235.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp235.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp236.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp236.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp236.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp237.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp237.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp237.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp238.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp238.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp238.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp239.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp239.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp239.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp240.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp240.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp240.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp241.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp241.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp241.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp242.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp242.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp242.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp243.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp243.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp243.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp244.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp244.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp244.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp245.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp245.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp245.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp246.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp246.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp246.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp247.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp247.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp247.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp248.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp248.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp248.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp249.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp249.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp249.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp250.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp250.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp250.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp251.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp251.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp251.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp252.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp252.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp252.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp253.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp253.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp253.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp254.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp254.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp254.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp255.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp255.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp255.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp256.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp256.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp256.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp257.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp257.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp257.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp258.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp258.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp258.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp259.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp259.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp259.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp260.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp260.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp260.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp261.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp261.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp261.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp262.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp262.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp262.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp263.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp263.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp263.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp264.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp264.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp264.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp265.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp265.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp265.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp266.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp266.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp266.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp267.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp267.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp267.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp268.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp268.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp268.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp269.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp269.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp269.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp270.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp270.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp270.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp271.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp271.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp271.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp272.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp272.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp272.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp273.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp273.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp273.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp274.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp274.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp274.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp275.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp275.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp275.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp276.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp276.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp276.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp277.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp277.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp277.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp278.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp278.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp278.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp279.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp279.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp279.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp280.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp280.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp280.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp281.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp281.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp281.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp282.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp282.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp282.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp283.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp283.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp283.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp284.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp284.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp284.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp285.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp285.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp285.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp286.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp286.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp286.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp287.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp287.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp287.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp288.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp288.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp288.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp289.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp289.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp289.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp290.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp290.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp290.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp291.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp291.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp291.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp292.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp292.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp292.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp293.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp293.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp293.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp294.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp294.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp294.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp295.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp295.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp295.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp296.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp296.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp296.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp297.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp297.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp297.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp298.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp298.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp298.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp299.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp299.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp299.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp300.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp300.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp300.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp301.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp301.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp301.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp302.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp302.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp302.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp303.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp303.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp303.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp304.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp304.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp304.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp305.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp305.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp305.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp306.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp306.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp306.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp307.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp307.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp307.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp308.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp308.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp308.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp309.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp309.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp309.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp310.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp310.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp310.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp311.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp311.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp311.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp312.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp312.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp312.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp313.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp313.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp313.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp314.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp314.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp314.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp315.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp315.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp315.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp316.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp316.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp316.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp317.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp317.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp317.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp318.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp318.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp318.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp319.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp319.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp319.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp320.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp320.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp320.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp321.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp321.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp321.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp322.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp322.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp322.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp323.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp323.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp323.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp324.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp324.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp324.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp325.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp325.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp325.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp326.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp326.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp326.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp327.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp327.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp327.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp328.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp328.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp328.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp329.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp329.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp329.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp330.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp330.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp330.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp331.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp331.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp331.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp332.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp332.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp332.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp333.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp333.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp333.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp334.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp334.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp334.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp335.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp335.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp335.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp336.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp336.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp336.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp337.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp337.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp337.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp338.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp338.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp338.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp339.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp339.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp339.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp340.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp340.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp340.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp341.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp341.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp341.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp342.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp342.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp342.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp343.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp343.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp343.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp344.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp344.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp344.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp345.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp345.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp345.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp346.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp346.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp346.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp347.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp347.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp347.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp348.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp348.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp348.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp349.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp349.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp349.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp350.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp350.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp350.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp351.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp351.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp351.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp352.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp352.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp352.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp353.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp353.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp353.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp354.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp354.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp354.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp355.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp355.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp355.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp356.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp356.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp356.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp357.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp357.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp357.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp358.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp358.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp358.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp359.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp359.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp359.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp360.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp360.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp360.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp361.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp361.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp361.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp362.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp362.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp362.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp363.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp363.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp363.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp364.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp364.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp364.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp365.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp365.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp365.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp366.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp366.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp366.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp367.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp367.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp367.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp368.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp368.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp368.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp369.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp369.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp369.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp370.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp370.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp370.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp371.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp371.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp371.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp372.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp372.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp372.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp373.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp373.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp373.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp374.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp374.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp374.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp375.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp375.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp375.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp376.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp376.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp376.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp377.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp377.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp377.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp378.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp378.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp378.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp379.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp379.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp379.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp380.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp380.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp380.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp381.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp381.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp381.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp382.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp382.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp382.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp383.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp383.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp383.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp384.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp384.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp384.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp385.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp385.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp385.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp386.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp386.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp386.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp387.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp387.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp387.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp388.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp388.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp388.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp389.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp389.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp389.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp390.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp390.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp390.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp391.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp391.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp391.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp392.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp392.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp392.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp393.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp393.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp393.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp394.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp394.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp394.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp395.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp395.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp395.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp396.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp396.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp396.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp397.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp397.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp397.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp398.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp398.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp398.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp399.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp399.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp399.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp400.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp400.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp400.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp401.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp401.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp401.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp402.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp402.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp402.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp403.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp403.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp403.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp404.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp404.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp404.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp405.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp405.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp405.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp406.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp406.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp406.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp407.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp407.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp407.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp408.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp408.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp408.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp409.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp409.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp409.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp410.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp410.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp410.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp411.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp411.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp411.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp412.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp412.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp412.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp413.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp413.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp413.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp414.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp414.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp414.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp415.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp415.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp415.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp416.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp416.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp416.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp417.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp417.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp417.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp418.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp418.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp418.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp419.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp419.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp419.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp420.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp420.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp420.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp421.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp421.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp421.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp422.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp422.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp422.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp423.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp423.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp423.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp424.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp424.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp424.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp425.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp425.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp425.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp426.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp426.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp426.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp427.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp427.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp427.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp428.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp428.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp428.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp429.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp429.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp429.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp430.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp430.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp430.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp431.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp431.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp431.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp432.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp432.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp432.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp433.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp433.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp433.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp434.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp434.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp434.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp435.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp435.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp435.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp436.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp436.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp436.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp437.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp437.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp437.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp438.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp438.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp438.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp439.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp439.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp439.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp440.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp440.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp440.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp441.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp441.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp441.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp442.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp442.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp442.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp443.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp443.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp443.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp444.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp444.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp444.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp445.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp445.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp445.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp446.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp446.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp446.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp447.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp447.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp447.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp448.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp448.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp448.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp449.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp449.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp449.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp450.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp450.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp450.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp451.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp451.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp451.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp452.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp452.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp452.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp453.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp453.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp453.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp454.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp454.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp454.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp455.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp455.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp455.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp456.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp456.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp456.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp457.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp457.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp457.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp458.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp458.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp458.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp459.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp459.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp459.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp460.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp460.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp460.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp461.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp461.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp461.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp462.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp462.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp462.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp463.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp463.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp463.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp464.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp464.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp464.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp465.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp465.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp465.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp466.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp466.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp466.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp467.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp467.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp467.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp468.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp468.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp468.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp469.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp469.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp469.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp470.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp470.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp470.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp471.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp471.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp471.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp472.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp472.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp472.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp473.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp473.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp473.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp474.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp474.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp474.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp475.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp475.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp475.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp476.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp476.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp476.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp477.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp477.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp477.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp478.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp478.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp478.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp479.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp479.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp479.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp480.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp480.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp480.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp481.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp481.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp481.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp482.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp482.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp482.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp483.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp483.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp483.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp484.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp484.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp484.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp485.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp485.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp485.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp486.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp486.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp486.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp487.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp487.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp487.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp488.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp488.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp488.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp489.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp489.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp489.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp490.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp490.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp490.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp491.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp491.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp491.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp492.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp492.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp492.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp493.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp493.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp493.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp494.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp494.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp494.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp495.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp495.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp495.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp496.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp496.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp496.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp497.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp497.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp497.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp498.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp498.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp498.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp499.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp499.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp499.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp500.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp500.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp500.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp501.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp501.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp501.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp502.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp502.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp502.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp503.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp503.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp503.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp504.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp504.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp504.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp505.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp505.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp505.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp506.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp506.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp506.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp507.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp507.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp507.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp508.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp508.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp508.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp509.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp509.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp509.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp510.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp510.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp510.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp511.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp511.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp511.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp512.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp512.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp512.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp513.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp513.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp513.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp514.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp514.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp514.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp515.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp515.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp515.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp516.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp516.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp516.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp517.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp517.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp517.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp518.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp518.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp518.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp519.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp519.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp519.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp520.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp520.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp520.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp521.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp521.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp521.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp522.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp522.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp522.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp523.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp523.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp523.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp524.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp524.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp524.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp525.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp525.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp525.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp526.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp526.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp526.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp527.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp527.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp527.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp528.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp528.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp528.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp529.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp529.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp529.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp530.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp530.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp530.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp531.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp531.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp531.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp532.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp532.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp532.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp533.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp533.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp533.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp534.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp534.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp534.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp535.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp535.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp535.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp536.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp536.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp536.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp537.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp537.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp537.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp538.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp538.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp538.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp539.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp539.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp539.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp540.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp540.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp540.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp541.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp541.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp541.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp542.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp542.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp542.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp543.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp543.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp543.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp544.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp544.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp544.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp545.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp545.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp545.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp546.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp546.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp546.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp547.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp547.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp547.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp548.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp548.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp548.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp549.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp549.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp549.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp550.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp550.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp550.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp551.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp551.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp551.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp552.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp552.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp552.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp553.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp553.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp553.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp554.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp554.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp554.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp555.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp555.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp555.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp556.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp556.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp556.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp557.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp557.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp557.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp558.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp558.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp558.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp559.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp559.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp559.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp560.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp560.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp560.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp561.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp561.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp561.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp562.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp562.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp562.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp563.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp563.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp563.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp564.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp564.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp564.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp565.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp565.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp565.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp566.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp566.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp566.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp567.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp567.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp567.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp568.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp568.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp568.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp569.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp569.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp569.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp570.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp570.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp570.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp571.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp571.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp571.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp572.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp572.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp572.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp573.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp573.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp573.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp574.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp574.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp574.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp575.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp575.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp575.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp576.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp576.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp576.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp577.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp577.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp577.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp578.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp578.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp578.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp579.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp579.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp579.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp580.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp580.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp580.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp581.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp581.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp581.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp582.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp582.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp582.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp583.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp583.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp583.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp584.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp584.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp584.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp585.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp585.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp585.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp586.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp586.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp586.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp587.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp587.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp587.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp588.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp588.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp588.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp589.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp589.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp589.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp590.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp590.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp590.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp591.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp591.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp591.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp592.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp592.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp592.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp593.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp593.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp593.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp594.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp594.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp594.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp595.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp595.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp595.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp596.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp596.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp596.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp597.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp597.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp597.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp598.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp598.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp598.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp599.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp599.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp599.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp600.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp600.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp600.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp601.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp601.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp601.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp602.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp602.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp602.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp603.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp603.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp603.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp604.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp604.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp604.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp605.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp605.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp605.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp606.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp606.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp606.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp607.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp607.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp607.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp608.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp608.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp608.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp609.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp609.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp609.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp610.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp610.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp610.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp611.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp611.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp611.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp612.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp612.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp612.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp613.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp613.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp613.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp614.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp614.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp614.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp615.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp615.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp615.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp616.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp616.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp616.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp617.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp617.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp617.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp618.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp618.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp618.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp619.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp619.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp619.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp620.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp620.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp620.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp621.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp621.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp621.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp622.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp622.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp622.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp623.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp623.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp623.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp624.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp624.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp624.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp625.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp625.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp625.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp626.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp626.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp626.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp627.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp627.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp627.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp628.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp628.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp628.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp629.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp629.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp629.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp630.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp630.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp630.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp631.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp631.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp631.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp632.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp632.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp632.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp633.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp633.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp633.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp634.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp634.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp634.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp635.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp635.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp635.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp636.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp636.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp636.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp637.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp637.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp637.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp638.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp638.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp638.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp639.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp639.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp639.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp640.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp640.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp640.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp641.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp641.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp641.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp642.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp642.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp642.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp643.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp643.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp643.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp644.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp644.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp644.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp645.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp645.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp645.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp646.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp646.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp646.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp647.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp647.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp647.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp648.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp648.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp648.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp649.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp649.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp649.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp650.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp650.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp650.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp651.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp651.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp651.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp652.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp652.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp652.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp653.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp653.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp653.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp654.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp654.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp654.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp655.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp655.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp655.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp656.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp656.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp656.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp657.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp657.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp657.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp658.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp658.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp658.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp659.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp659.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp659.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp660.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp660.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp660.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp661.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp661.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp661.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp662.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp662.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp662.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp663.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp663.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp663.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp664.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp664.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp664.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp665.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp665.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp665.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp666.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp666.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp666.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp667.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp667.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp667.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp668.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp668.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp668.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp669.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp669.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp669.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp670.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp670.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp670.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp671.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp671.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp671.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp672.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp672.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp672.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp673.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp673.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp673.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp674.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp674.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp674.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp675.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp675.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp675.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp676.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp676.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp676.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp677.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp677.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp677.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp678.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp678.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp678.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp679.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp679.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp679.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp680.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp680.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp680.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp681.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp681.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp681.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp682.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp682.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp682.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp683.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp683.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp683.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp684.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp684.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp684.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp685.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp685.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp685.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp686.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp686.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp686.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp687.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp687.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp687.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp688.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp688.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp688.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp689.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp689.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp689.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp690.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp690.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp690.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp691.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp691.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp691.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp692.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp692.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp692.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp693.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp693.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp693.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp694.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp694.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp694.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp695.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp695.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp695.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp696.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp696.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp696.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp697.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp697.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp697.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp698.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp698.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp698.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp699.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp699.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp699.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp700.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp700.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp700.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp701.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp701.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp701.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp702.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp702.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp702.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp703.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp703.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp703.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp704.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp704.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp704.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp705.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp705.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp705.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp706.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp706.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp706.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp707.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp707.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp707.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp708.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp708.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp708.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp709.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp709.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp709.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp710.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp710.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp710.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp711.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp711.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp711.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp712.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp712.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp712.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp713.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp713.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp713.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp714.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp714.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp714.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp715.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp715.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp715.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp716.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp716.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp716.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp717.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp717.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp717.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp718.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp718.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp718.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp719.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp719.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp719.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp720.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp720.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp720.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp721.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp721.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp721.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp722.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp722.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp722.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp723.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp723.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp723.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp724.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp724.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp724.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp725.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp725.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp725.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp726.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp726.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp726.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp727.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp727.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp727.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp728.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp728.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp728.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp729.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp729.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp729.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp730.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp730.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp730.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp731.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp731.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp731.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp732.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp732.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp732.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp733.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp733.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp733.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp734.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp734.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp734.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp735.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp735.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp735.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp736.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp736.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp736.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp737.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp737.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp737.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp738.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp738.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp738.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp739.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp739.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp739.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; parameter Real FixedTemp740.T(quantity = "ThermodynamicTemperature", unit = "degC") = 25.0 "Fixed Temperature at the port"; Real FixedTemp740.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real FixedTemp740.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001001001.T; Real TsCABI0CabiA001001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002001001.T; Real TsCABI0CabiA002001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003001001.T; Real TsCABI0CabiA003001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004001001.T; Real TsCABI0CabiA004001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005001001.T; Real TsCABI0CabiA005001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006001001.T; Real TsCABI0CabiA006001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007001001.T; Real TsCABI0CabiA007001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008001001.T; Real TsCABI0CabiA008001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009001001.T; Real TsCABI0CabiA009001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010001001.T; Real TsCABI0CabiA010001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011001001.T; Real TsCABI0CabiA011001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012001001.T; Real TsCABI0CabiA012001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013001001.T; Real TsCABI0CabiA013001001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013001001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001002001.T; Real TsCABI0CabiA001002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002002001.T; Real TsCABI0CabiA002002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003002001.T; Real TsCABI0CabiA003002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004002001.T; Real TsCABI0CabiA004002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005002001.T; Real TsCABI0CabiA005002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006002001.T; Real TsCABI0CabiA006002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007002001.T; Real TsCABI0CabiA007002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008002001.T; Real TsCABI0CabiA008002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009002001.T; Real TsCABI0CabiA009002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010002001.T; Real TsCABI0CabiA010002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011002001.T; Real TsCABI0CabiA011002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012002001.T; Real TsCABI0CabiA012002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013002001.T; Real TsCABI0CabiA013002001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013002001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001003001.T; Real TsCABI0CabiA001003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002003001.T; Real TsCABI0CabiA002003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003003001.T; Real TsCABI0CabiA003003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004003001.T; Real TsCABI0CabiA004003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005003001.T; Real TsCABI0CabiA005003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006003001.T; Real TsCABI0CabiA006003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007003001.T; Real TsCABI0CabiA007003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008003001.T; Real TsCABI0CabiA008003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009003001.T; Real TsCABI0CabiA009003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010003001.T; Real TsCABI0CabiA010003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011003001.T; Real TsCABI0CabiA011003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012003001.T; Real TsCABI0CabiA012003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013003001.T; Real TsCABI0CabiA013003001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013003001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001004001.T; Real TsCABI0CabiA001004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002004001.T; Real TsCABI0CabiA002004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003004001.T; Real TsCABI0CabiA003004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004004001.T; Real TsCABI0CabiA004004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005004001.T; Real TsCABI0CabiA005004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006004001.T; Real TsCABI0CabiA006004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007004001.T; Real TsCABI0CabiA007004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008004001.T; Real TsCABI0CabiA008004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009004001.T; Real TsCABI0CabiA009004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010004001.T; Real TsCABI0CabiA010004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011004001.T; Real TsCABI0CabiA011004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012004001.T; Real TsCABI0CabiA012004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013004001.T; Real TsCABI0CabiA013004001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013004001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001005001.T; Real TsCABI0CabiA001005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002005001.T; Real TsCABI0CabiA002005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003005001.T; Real TsCABI0CabiA003005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004005001.T; Real TsCABI0CabiA004005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005005001.T; Real TsCABI0CabiA005005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006005001.T; Real TsCABI0CabiA006005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007005001.T; Real TsCABI0CabiA007005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008005001.T; Real TsCABI0CabiA008005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009005001.T; Real TsCABI0CabiA009005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010005001.T; Real TsCABI0CabiA010005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011005001.T; Real TsCABI0CabiA011005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012005001.T; Real TsCABI0CabiA012005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013005001.T; Real TsCABI0CabiA013005001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013005001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001006001.T; Real TsCABI0CabiA001006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002006001.T; Real TsCABI0CabiA002006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003006001.T; Real TsCABI0CabiA003006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004006001.T; Real TsCABI0CabiA004006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005006001.T; Real TsCABI0CabiA005006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006006001.T; Real TsCABI0CabiA006006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007006001.T; Real TsCABI0CabiA007006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008006001.T; Real TsCABI0CabiA008006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009006001.T; Real TsCABI0CabiA009006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010006001.T; Real TsCABI0CabiA010006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011006001.T; Real TsCABI0CabiA011006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012006001.T; Real TsCABI0CabiA012006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013006001.T; Real TsCABI0CabiA013006001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013006001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001007001.T; Real TsCABI0CabiA001007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002007001.T; Real TsCABI0CabiA002007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003007001.T; Real TsCABI0CabiA003007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004007001.T; Real TsCABI0CabiA004007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005007001.T; Real TsCABI0CabiA005007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006007001.T; Real TsCABI0CabiA006007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007007001.T; Real TsCABI0CabiA007007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008007001.T; Real TsCABI0CabiA008007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009007001.T; Real TsCABI0CabiA009007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010007001.T; Real TsCABI0CabiA010007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011007001.T; Real TsCABI0CabiA011007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012007001.T; Real TsCABI0CabiA012007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013007001.T; Real TsCABI0CabiA013007001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013007001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001008001.T; Real TsCABI0CabiA001008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002008001.T; Real TsCABI0CabiA002008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003008001.T; Real TsCABI0CabiA003008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004008001.T; Real TsCABI0CabiA004008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005008001.T; Real TsCABI0CabiA005008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006008001.T; Real TsCABI0CabiA006008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007008001.T; Real TsCABI0CabiA007008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008008001.T; Real TsCABI0CabiA008008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009008001.T; Real TsCABI0CabiA009008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010008001.T; Real TsCABI0CabiA010008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011008001.T; Real TsCABI0CabiA011008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012008001.T; Real TsCABI0CabiA012008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013008001.T; Real TsCABI0CabiA013008001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013008001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001009001.T; Real TsCABI0CabiA001009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002009001.T; Real TsCABI0CabiA002009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003009001.T; Real TsCABI0CabiA003009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004009001.T; Real TsCABI0CabiA004009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005009001.T; Real TsCABI0CabiA005009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006009001.T; Real TsCABI0CabiA006009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007009001.T; Real TsCABI0CabiA007009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008009001.T; Real TsCABI0CabiA008009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009009001.T; Real TsCABI0CabiA009009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010009001.T; Real TsCABI0CabiA010009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011009001.T; Real TsCABI0CabiA011009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012009001.T; Real TsCABI0CabiA012009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013009001.T; Real TsCABI0CabiA013009001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013009001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001010001.T; Real TsCABI0CabiA001010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002010001.T; Real TsCABI0CabiA002010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003010001.T; Real TsCABI0CabiA003010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004010001.T; Real TsCABI0CabiA004010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005010001.T; Real TsCABI0CabiA005010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006010001.T; Real TsCABI0CabiA006010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007010001.T; Real TsCABI0CabiA007010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008010001.T; Real TsCABI0CabiA008010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009010001.T; Real TsCABI0CabiA009010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010010001.T; Real TsCABI0CabiA010010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011010001.T; Real TsCABI0CabiA011010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012010001.T; Real TsCABI0CabiA012010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013010001.T; Real TsCABI0CabiA013010001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013010001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001011001.T; Real TsCABI0CabiA001011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002011001.T; Real TsCABI0CabiA002011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003011001.T; Real TsCABI0CabiA003011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004011001.T; Real TsCABI0CabiA004011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005011001.T; Real TsCABI0CabiA005011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006011001.T; Real TsCABI0CabiA006011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007011001.T; Real TsCABI0CabiA007011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008011001.T; Real TsCABI0CabiA008011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009011001.T; Real TsCABI0CabiA009011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010011001.T; Real TsCABI0CabiA010011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011011001.T; Real TsCABI0CabiA011011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012011001.T; Real TsCABI0CabiA012011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013011001.T; Real TsCABI0CabiA013011001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013011001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001012001.T; Real TsCABI0CabiA001012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002012001.T; Real TsCABI0CabiA002012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003012001.T; Real TsCABI0CabiA003012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004012001.T; Real TsCABI0CabiA004012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005012001.T; Real TsCABI0CabiA005012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006012001.T; Real TsCABI0CabiA006012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007012001.T; Real TsCABI0CabiA007012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008012001.T; Real TsCABI0CabiA008012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009012001.T; Real TsCABI0CabiA009012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010012001.T; Real TsCABI0CabiA010012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011012001.T; Real TsCABI0CabiA011012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012012001.T; Real TsCABI0CabiA012012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013012001.T; Real TsCABI0CabiA013012001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013012001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001013001.T; Real TsCABI0CabiA001013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002013001.T; Real TsCABI0CabiA002013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003013001.T; Real TsCABI0CabiA003013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004013001.T; Real TsCABI0CabiA004013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005013001.T; Real TsCABI0CabiA005013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006013001.T; Real TsCABI0CabiA006013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007013001.T; Real TsCABI0CabiA007013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008013001.T; Real TsCABI0CabiA008013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009013001.T; Real TsCABI0CabiA009013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010013001.T; Real TsCABI0CabiA010013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011013001.T; Real TsCABI0CabiA011013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012013001.T; Real TsCABI0CabiA012013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013013001.T; Real TsCABI0CabiA013013001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013013001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001014001.T; Real TsCABI0CabiA001014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002014001.T; Real TsCABI0CabiA002014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003014001.T; Real TsCABI0CabiA003014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004014001.T; Real TsCABI0CabiA004014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005014001.T; Real TsCABI0CabiA005014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006014001.T; Real TsCABI0CabiA006014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007014001.T; Real TsCABI0CabiA007014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008014001.T; Real TsCABI0CabiA008014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009014001.T; Real TsCABI0CabiA009014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010014001.T; Real TsCABI0CabiA010014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011014001.T; Real TsCABI0CabiA011014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012014001.T; Real TsCABI0CabiA012014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013014001.T; Real TsCABI0CabiA013014001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013014001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001015001.T; Real TsCABI0CabiA001015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002015001.T; Real TsCABI0CabiA002015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003015001.T; Real TsCABI0CabiA003015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004015001.T; Real TsCABI0CabiA004015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005015001.T; Real TsCABI0CabiA005015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006015001.T; Real TsCABI0CabiA006015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007015001.T; Real TsCABI0CabiA007015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008015001.T; Real TsCABI0CabiA008015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009015001.T; Real TsCABI0CabiA009015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010015001.T; Real TsCABI0CabiA010015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011015001.T; Real TsCABI0CabiA011015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012015001.T; Real TsCABI0CabiA012015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013015001.T; Real TsCABI0CabiA013015001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013015001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001016001.T; Real TsCABI0CabiA001016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002016001.T; Real TsCABI0CabiA002016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003016001.T; Real TsCABI0CabiA003016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004016001.T; Real TsCABI0CabiA004016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005016001.T; Real TsCABI0CabiA005016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006016001.T; Real TsCABI0CabiA006016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007016001.T; Real TsCABI0CabiA007016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008016001.T; Real TsCABI0CabiA008016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009016001.T; Real TsCABI0CabiA009016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010016001.T; Real TsCABI0CabiA010016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011016001.T; Real TsCABI0CabiA011016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012016001.T; Real TsCABI0CabiA012016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013016001.T; Real TsCABI0CabiA013016001.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013016001.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002001002.T; Real TsCABI0CabiA002001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003001002.T; Real TsCABI0CabiA003001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004001002.T; Real TsCABI0CabiA004001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005001002.T; Real TsCABI0CabiA005001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006001002.T; Real TsCABI0CabiA006001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007001002.T; Real TsCABI0CabiA007001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008001002.T; Real TsCABI0CabiA008001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009001002.T; Real TsCABI0CabiA009001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010001002.T; Real TsCABI0CabiA010001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011001002.T; Real TsCABI0CabiA011001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012001002.T; Real TsCABI0CabiA012001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013001002.T; Real TsCABI0CabiA013001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001002002.T; Real TsCABI0CabiA001002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013002002.T; Real TsCABI0CabiA013002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001003002.T; Real TsCABI0CabiA001003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013003002.T; Real TsCABI0CabiA013003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001004002.T; Real TsCABI0CabiA001004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013004002.T; Real TsCABI0CabiA013004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001005002.T; Real TsCABI0CabiA001005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013005002.T; Real TsCABI0CabiA013005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001006002.T; Real TsCABI0CabiA001006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013006002.T; Real TsCABI0CabiA013006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001007002.T; Real TsCABI0CabiA001007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013007002.T; Real TsCABI0CabiA013007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001008002.T; Real TsCABI0CabiA001008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013008002.T; Real TsCABI0CabiA013008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001009002.T; Real TsCABI0CabiA001009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013009002.T; Real TsCABI0CabiA013009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001010002.T; Real TsCABI0CabiA001010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013010002.T; Real TsCABI0CabiA013010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001011002.T; Real TsCABI0CabiA001011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013011002.T; Real TsCABI0CabiA013011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001012002.T; Real TsCABI0CabiA001012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013012002.T; Real TsCABI0CabiA013012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001013002.T; Real TsCABI0CabiA001013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013013002.T; Real TsCABI0CabiA013013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001014002.T; Real TsCABI0CabiA001014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013014002.T; Real TsCABI0CabiA013014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001015002.T; Real TsCABI0CabiA001015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013015002.T; Real TsCABI0CabiA013015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001016002.T; Real TsCABI0CabiA001016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002016002.T; Real TsCABI0CabiA002016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003016002.T; Real TsCABI0CabiA003016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004016002.T; Real TsCABI0CabiA004016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005016002.T; Real TsCABI0CabiA005016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006016002.T; Real TsCABI0CabiA006016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007016002.T; Real TsCABI0CabiA007016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008016002.T; Real TsCABI0CabiA008016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009016002.T; Real TsCABI0CabiA009016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010016002.T; Real TsCABI0CabiA010016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011016002.T; Real TsCABI0CabiA011016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012016002.T; Real TsCABI0CabiA012016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013016002.T; Real TsCABI0CabiA013016002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013016002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001001005.T; Real TsCABI0CabiA001001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002001005.T; Real TsCABI0CabiA002001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003001005.T; Real TsCABI0CabiA003001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004001005.T; Real TsCABI0CabiA004001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005001005.T; Real TsCABI0CabiA005001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006001005.T; Real TsCABI0CabiA006001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007001005.T; Real TsCABI0CabiA007001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008001005.T; Real TsCABI0CabiA008001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009001005.T; Real TsCABI0CabiA009001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010001005.T; Real TsCABI0CabiA010001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011001005.T; Real TsCABI0CabiA011001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012001005.T; Real TsCABI0CabiA012001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013001005.T; Real TsCABI0CabiA013001005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013001005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001002005.T; Real TsCABI0CabiA001002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013002005.T; Real TsCABI0CabiA013002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001003005.T; Real TsCABI0CabiA001003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013003005.T; Real TsCABI0CabiA013003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001004005.T; Real TsCABI0CabiA001004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013004005.T; Real TsCABI0CabiA013004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001005005.T; Real TsCABI0CabiA001005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013005005.T; Real TsCABI0CabiA013005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001006005.T; Real TsCABI0CabiA001006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013006005.T; Real TsCABI0CabiA013006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001007005.T; Real TsCABI0CabiA001007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013007005.T; Real TsCABI0CabiA013007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001008005.T; Real TsCABI0CabiA001008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013008005.T; Real TsCABI0CabiA013008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001009005.T; Real TsCABI0CabiA001009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013009005.T; Real TsCABI0CabiA013009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001010005.T; Real TsCABI0CabiA001010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013010005.T; Real TsCABI0CabiA013010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001011005.T; Real TsCABI0CabiA001011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013011005.T; Real TsCABI0CabiA013011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001012005.T; Real TsCABI0CabiA001012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013012005.T; Real TsCABI0CabiA013012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001013005.T; Real TsCABI0CabiA001013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013013005.T; Real TsCABI0CabiA013013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001014005.T; Real TsCABI0CabiA001014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013014005.T; Real TsCABI0CabiA013014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001015005.T; Real TsCABI0CabiA001015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013015005.T; Real TsCABI0CabiA013015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001016005.T; Real TsCABI0CabiA001016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002016005.T; Real TsCABI0CabiA002016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003016005.T; Real TsCABI0CabiA003016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004016005.T; Real TsCABI0CabiA004016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005016005.T; Real TsCABI0CabiA005016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006016005.T; Real TsCABI0CabiA006016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007016005.T; Real TsCABI0CabiA007016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008016005.T; Real TsCABI0CabiA008016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009016005.T; Real TsCABI0CabiA009016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010016005.T; Real TsCABI0CabiA010016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011016005.T; Real TsCABI0CabiA011016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012016005.T; Real TsCABI0CabiA012016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013016005.T; Real TsCABI0CabiA013016005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013016005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001001004.T; Real TsCABI0CabiA001001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002001004.T; Real TsCABI0CabiA002001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003001004.T; Real TsCABI0CabiA003001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004001004.T; Real TsCABI0CabiA004001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005001004.T; Real TsCABI0CabiA005001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006001004.T; Real TsCABI0CabiA006001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007001004.T; Real TsCABI0CabiA007001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008001004.T; Real TsCABI0CabiA008001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009001004.T; Real TsCABI0CabiA009001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010001004.T; Real TsCABI0CabiA010001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011001004.T; Real TsCABI0CabiA011001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012001004.T; Real TsCABI0CabiA012001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013001004.T; Real TsCABI0CabiA013001004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013001004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001002004.T; Real TsCABI0CabiA001002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013002004.T; Real TsCABI0CabiA013002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001003004.T; Real TsCABI0CabiA001003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013003004.T; Real TsCABI0CabiA013003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001004004.T; Real TsCABI0CabiA001004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013004004.T; Real TsCABI0CabiA013004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001005004.T; Real TsCABI0CabiA001005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013005004.T; Real TsCABI0CabiA013005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001006004.T; Real TsCABI0CabiA001006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013006004.T; Real TsCABI0CabiA013006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001007004.T; Real TsCABI0CabiA001007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013007004.T; Real TsCABI0CabiA013007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001008004.T; Real TsCABI0CabiA001008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013008004.T; Real TsCABI0CabiA013008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001009004.T; Real TsCABI0CabiA001009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013009004.T; Real TsCABI0CabiA013009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001010004.T; Real TsCABI0CabiA001010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013010004.T; Real TsCABI0CabiA013010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001011004.T; Real TsCABI0CabiA001011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013011004.T; Real TsCABI0CabiA013011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001012004.T; Real TsCABI0CabiA001012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013012004.T; Real TsCABI0CabiA013012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001013004.T; Real TsCABI0CabiA001013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013013004.T; Real TsCABI0CabiA013013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001014004.T; Real TsCABI0CabiA001014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013014004.T; Real TsCABI0CabiA013014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001015004.T; Real TsCABI0CabiA001015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013015004.T; Real TsCABI0CabiA013015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001016004.T; Real TsCABI0CabiA001016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002016004.T; Real TsCABI0CabiA002016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003016004.T; Real TsCABI0CabiA003016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004016004.T; Real TsCABI0CabiA004016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005016004.T; Real TsCABI0CabiA005016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006016004.T; Real TsCABI0CabiA006016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007016004.T; Real TsCABI0CabiA007016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008016004.T; Real TsCABI0CabiA008016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009016004.T; Real TsCABI0CabiA009016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010016004.T; Real TsCABI0CabiA010016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011016004.T; Real TsCABI0CabiA011016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012016004.T; Real TsCABI0CabiA012016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013016004.T; Real TsCABI0CabiA013016004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013016004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001001003.T; Real TsCABI0CabiA001001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002001003.T; Real TsCABI0CabiA002001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003001003.T; Real TsCABI0CabiA003001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004001003.T; Real TsCABI0CabiA004001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005001003.T; Real TsCABI0CabiA005001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006001003.T; Real TsCABI0CabiA006001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007001003.T; Real TsCABI0CabiA007001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008001003.T; Real TsCABI0CabiA008001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009001003.T; Real TsCABI0CabiA009001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010001003.T; Real TsCABI0CabiA010001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011001003.T; Real TsCABI0CabiA011001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012001003.T; Real TsCABI0CabiA012001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013001003.T; Real TsCABI0CabiA013001003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013001003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001002003.T; Real TsCABI0CabiA001002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013002003.T; Real TsCABI0CabiA013002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001003003.T; Real TsCABI0CabiA001003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013003003.T; Real TsCABI0CabiA013003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001004003.T; Real TsCABI0CabiA001004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013004003.T; Real TsCABI0CabiA013004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001005003.T; Real TsCABI0CabiA001005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013005003.T; Real TsCABI0CabiA013005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001006003.T; Real TsCABI0CabiA001006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013006003.T; Real TsCABI0CabiA013006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001007003.T; Real TsCABI0CabiA001007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013007003.T; Real TsCABI0CabiA013007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001008003.T; Real TsCABI0CabiA001008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013008003.T; Real TsCABI0CabiA013008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001009003.T; Real TsCABI0CabiA001009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013009003.T; Real TsCABI0CabiA013009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001010003.T; Real TsCABI0CabiA001010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013010003.T; Real TsCABI0CabiA013010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001011003.T; Real TsCABI0CabiA001011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013011003.T; Real TsCABI0CabiA013011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001012003.T; Real TsCABI0CabiA001012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013012003.T; Real TsCABI0CabiA013012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001013003.T; Real TsCABI0CabiA001013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013013003.T; Real TsCABI0CabiA013013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001014003.T; Real TsCABI0CabiA001014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013014003.T; Real TsCABI0CabiA013014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001015003.T; Real TsCABI0CabiA001015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013015003.T; Real TsCABI0CabiA013015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001016003.T; Real TsCABI0CabiA001016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002016003.T; Real TsCABI0CabiA002016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003016003.T; Real TsCABI0CabiA003016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004016003.T; Real TsCABI0CabiA004016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005016003.T; Real TsCABI0CabiA005016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006016003.T; Real TsCABI0CabiA006016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007016003.T; Real TsCABI0CabiA007016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008016003.T; Real TsCABI0CabiA008016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009016003.T; Real TsCABI0CabiA009016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010016003.T; Real TsCABI0CabiA010016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011016003.T; Real TsCABI0CabiA011016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012016003.T; Real TsCABI0CabiA012016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013016003.T; Real TsCABI0CabiA013016003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013016003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001001002.T; Real TsCABI0CabiA001001002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001001002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001001006.T; Real TsCABI0CabiA001001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002001006.T; Real TsCABI0CabiA002001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003001006.T; Real TsCABI0CabiA003001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004001006.T; Real TsCABI0CabiA004001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005001006.T; Real TsCABI0CabiA005001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006001006.T; Real TsCABI0CabiA006001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007001006.T; Real TsCABI0CabiA007001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008001006.T; Real TsCABI0CabiA008001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009001006.T; Real TsCABI0CabiA009001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010001006.T; Real TsCABI0CabiA010001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011001006.T; Real TsCABI0CabiA011001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012001006.T; Real TsCABI0CabiA012001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013001006.T; Real TsCABI0CabiA013001006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013001006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001002006.T; Real TsCABI0CabiA001002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013002006.T; Real TsCABI0CabiA013002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001003006.T; Real TsCABI0CabiA001003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013003006.T; Real TsCABI0CabiA013003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001004006.T; Real TsCABI0CabiA001004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013004006.T; Real TsCABI0CabiA013004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001005006.T; Real TsCABI0CabiA001005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013005006.T; Real TsCABI0CabiA013005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001006006.T; Real TsCABI0CabiA001006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013006006.T; Real TsCABI0CabiA013006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001007006.T; Real TsCABI0CabiA001007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013007006.T; Real TsCABI0CabiA013007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001008006.T; Real TsCABI0CabiA001008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013008006.T; Real TsCABI0CabiA013008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001009006.T; Real TsCABI0CabiA001009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013009006.T; Real TsCABI0CabiA013009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001010006.T; Real TsCABI0CabiA001010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013010006.T; Real TsCABI0CabiA013010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001011006.T; Real TsCABI0CabiA001011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013011006.T; Real TsCABI0CabiA013011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001012006.T; Real TsCABI0CabiA001012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013012006.T; Real TsCABI0CabiA013012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001013006.T; Real TsCABI0CabiA001013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013013006.T; Real TsCABI0CabiA013013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001014006.T; Real TsCABI0CabiA001014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013014006.T; Real TsCABI0CabiA013014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001015006.T; Real TsCABI0CabiA001015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013015006.T; Real TsCABI0CabiA013015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001016006.T; Real TsCABI0CabiA001016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002016006.T; Real TsCABI0CabiA002016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003016006.T; Real TsCABI0CabiA003016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004016006.T; Real TsCABI0CabiA004016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005016006.T; Real TsCABI0CabiA005016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006016006.T; Real TsCABI0CabiA006016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007016006.T; Real TsCABI0CabiA007016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008016006.T; Real TsCABI0CabiA008016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009016006.T; Real TsCABI0CabiA009016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010016006.T; Real TsCABI0CabiA010016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011016006.T; Real TsCABI0CabiA011016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012016006.T; Real TsCABI0CabiA012016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013016006.T; Real TsCABI0CabiA013016006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013016006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001001007.T; Real TsCABI0CabiA001001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002001007.T; Real TsCABI0CabiA002001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003001007.T; Real TsCABI0CabiA003001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004001007.T; Real TsCABI0CabiA004001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005001007.T; Real TsCABI0CabiA005001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006001007.T; Real TsCABI0CabiA006001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007001007.T; Real TsCABI0CabiA007001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008001007.T; Real TsCABI0CabiA008001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009001007.T; Real TsCABI0CabiA009001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010001007.T; Real TsCABI0CabiA010001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011001007.T; Real TsCABI0CabiA011001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012001007.T; Real TsCABI0CabiA012001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013001007.T; Real TsCABI0CabiA013001007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013001007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001002007.T; Real TsCABI0CabiA001002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013002007.T; Real TsCABI0CabiA013002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001003007.T; Real TsCABI0CabiA001003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013003007.T; Real TsCABI0CabiA013003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001004007.T; Real TsCABI0CabiA001004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013004007.T; Real TsCABI0CabiA013004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001005007.T; Real TsCABI0CabiA001005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013005007.T; Real TsCABI0CabiA013005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001006007.T; Real TsCABI0CabiA001006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013006007.T; Real TsCABI0CabiA013006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001007007.T; Real TsCABI0CabiA001007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013007007.T; Real TsCABI0CabiA013007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001008007.T; Real TsCABI0CabiA001008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013008007.T; Real TsCABI0CabiA013008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001009007.T; Real TsCABI0CabiA001009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013009007.T; Real TsCABI0CabiA013009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001010007.T; Real TsCABI0CabiA001010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013010007.T; Real TsCABI0CabiA013010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001011007.T; Real TsCABI0CabiA001011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013011007.T; Real TsCABI0CabiA013011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001012007.T; Real TsCABI0CabiA001012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013012007.T; Real TsCABI0CabiA013012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001013007.T; Real TsCABI0CabiA001013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013013007.T; Real TsCABI0CabiA013013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001014007.T; Real TsCABI0CabiA001014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013014007.T; Real TsCABI0CabiA013014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001015007.T; Real TsCABI0CabiA001015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013015007.T; Real TsCABI0CabiA013015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001016007.T; Real TsCABI0CabiA001016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002016007.T; Real TsCABI0CabiA002016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003016007.T; Real TsCABI0CabiA003016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004016007.T; Real TsCABI0CabiA004016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005016007.T; Real TsCABI0CabiA005016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006016007.T; Real TsCABI0CabiA006016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007016007.T; Real TsCABI0CabiA007016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008016007.T; Real TsCABI0CabiA008016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009016007.T; Real TsCABI0CabiA009016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010016007.T; Real TsCABI0CabiA010016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011016007.T; Real TsCABI0CabiA011016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012016007.T; Real TsCABI0CabiA012016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013016007.T; Real TsCABI0CabiA013016007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013016007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001001008.T; Real TsCABI0CabiA001001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002001008.T; Real TsCABI0CabiA002001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003001008.T; Real TsCABI0CabiA003001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004001008.T; Real TsCABI0CabiA004001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005001008.T; Real TsCABI0CabiA005001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006001008.T; Real TsCABI0CabiA006001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007001008.T; Real TsCABI0CabiA007001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008001008.T; Real TsCABI0CabiA008001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009001008.T; Real TsCABI0CabiA009001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010001008.T; Real TsCABI0CabiA010001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011001008.T; Real TsCABI0CabiA011001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012001008.T; Real TsCABI0CabiA012001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013001008.T; Real TsCABI0CabiA013001008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013001008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001002008.T; Real TsCABI0CabiA001002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002002008.T; Real TsCABI0CabiA002002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003002008.T; Real TsCABI0CabiA003002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004002008.T; Real TsCABI0CabiA004002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005002008.T; Real TsCABI0CabiA005002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006002008.T; Real TsCABI0CabiA006002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007002008.T; Real TsCABI0CabiA007002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008002008.T; Real TsCABI0CabiA008002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009002008.T; Real TsCABI0CabiA009002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010002008.T; Real TsCABI0CabiA010002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011002008.T; Real TsCABI0CabiA011002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012002008.T; Real TsCABI0CabiA012002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013002008.T; Real TsCABI0CabiA013002008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013002008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001003008.T; Real TsCABI0CabiA001003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002003008.T; Real TsCABI0CabiA002003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003003008.T; Real TsCABI0CabiA003003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004003008.T; Real TsCABI0CabiA004003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005003008.T; Real TsCABI0CabiA005003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006003008.T; Real TsCABI0CabiA006003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007003008.T; Real TsCABI0CabiA007003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008003008.T; Real TsCABI0CabiA008003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009003008.T; Real TsCABI0CabiA009003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010003008.T; Real TsCABI0CabiA010003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011003008.T; Real TsCABI0CabiA011003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012003008.T; Real TsCABI0CabiA012003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013003008.T; Real TsCABI0CabiA013003008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013003008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001004008.T; Real TsCABI0CabiA001004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002004008.T; Real TsCABI0CabiA002004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003004008.T; Real TsCABI0CabiA003004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004004008.T; Real TsCABI0CabiA004004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005004008.T; Real TsCABI0CabiA005004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006004008.T; Real TsCABI0CabiA006004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007004008.T; Real TsCABI0CabiA007004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008004008.T; Real TsCABI0CabiA008004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009004008.T; Real TsCABI0CabiA009004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010004008.T; Real TsCABI0CabiA010004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011004008.T; Real TsCABI0CabiA011004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012004008.T; Real TsCABI0CabiA012004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013004008.T; Real TsCABI0CabiA013004008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013004008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001005008.T; Real TsCABI0CabiA001005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002005008.T; Real TsCABI0CabiA002005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003005008.T; Real TsCABI0CabiA003005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004005008.T; Real TsCABI0CabiA004005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005005008.T; Real TsCABI0CabiA005005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006005008.T; Real TsCABI0CabiA006005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007005008.T; Real TsCABI0CabiA007005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008005008.T; Real TsCABI0CabiA008005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009005008.T; Real TsCABI0CabiA009005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010005008.T; Real TsCABI0CabiA010005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011005008.T; Real TsCABI0CabiA011005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012005008.T; Real TsCABI0CabiA012005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013005008.T; Real TsCABI0CabiA013005008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013005008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001006008.T; Real TsCABI0CabiA001006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002006008.T; Real TsCABI0CabiA002006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003006008.T; Real TsCABI0CabiA003006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004006008.T; Real TsCABI0CabiA004006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005006008.T; Real TsCABI0CabiA005006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006006008.T; Real TsCABI0CabiA006006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007006008.T; Real TsCABI0CabiA007006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008006008.T; Real TsCABI0CabiA008006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009006008.T; Real TsCABI0CabiA009006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010006008.T; Real TsCABI0CabiA010006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011006008.T; Real TsCABI0CabiA011006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012006008.T; Real TsCABI0CabiA012006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013006008.T; Real TsCABI0CabiA013006008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013006008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001007008.T; Real TsCABI0CabiA001007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002007008.T; Real TsCABI0CabiA002007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003007008.T; Real TsCABI0CabiA003007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004007008.T; Real TsCABI0CabiA004007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005007008.T; Real TsCABI0CabiA005007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006007008.T; Real TsCABI0CabiA006007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007007008.T; Real TsCABI0CabiA007007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008007008.T; Real TsCABI0CabiA008007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009007008.T; Real TsCABI0CabiA009007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010007008.T; Real TsCABI0CabiA010007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011007008.T; Real TsCABI0CabiA011007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012007008.T; Real TsCABI0CabiA012007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013007008.T; Real TsCABI0CabiA013007008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013007008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001008008.T; Real TsCABI0CabiA001008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002008008.T; Real TsCABI0CabiA002008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003008008.T; Real TsCABI0CabiA003008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004008008.T; Real TsCABI0CabiA004008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005008008.T; Real TsCABI0CabiA005008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006008008.T; Real TsCABI0CabiA006008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007008008.T; Real TsCABI0CabiA007008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008008008.T; Real TsCABI0CabiA008008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009008008.T; Real TsCABI0CabiA009008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010008008.T; Real TsCABI0CabiA010008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011008008.T; Real TsCABI0CabiA011008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012008008.T; Real TsCABI0CabiA012008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013008008.T; Real TsCABI0CabiA013008008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013008008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001009008.T; Real TsCABI0CabiA001009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002009008.T; Real TsCABI0CabiA002009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003009008.T; Real TsCABI0CabiA003009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004009008.T; Real TsCABI0CabiA004009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005009008.T; Real TsCABI0CabiA005009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006009008.T; Real TsCABI0CabiA006009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007009008.T; Real TsCABI0CabiA007009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008009008.T; Real TsCABI0CabiA008009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009009008.T; Real TsCABI0CabiA009009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010009008.T; Real TsCABI0CabiA010009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011009008.T; Real TsCABI0CabiA011009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012009008.T; Real TsCABI0CabiA012009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013009008.T; Real TsCABI0CabiA013009008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013009008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001010008.T; Real TsCABI0CabiA001010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002010008.T; Real TsCABI0CabiA002010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003010008.T; Real TsCABI0CabiA003010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004010008.T; Real TsCABI0CabiA004010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005010008.T; Real TsCABI0CabiA005010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006010008.T; Real TsCABI0CabiA006010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007010008.T; Real TsCABI0CabiA007010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008010008.T; Real TsCABI0CabiA008010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009010008.T; Real TsCABI0CabiA009010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010010008.T; Real TsCABI0CabiA010010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011010008.T; Real TsCABI0CabiA011010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012010008.T; Real TsCABI0CabiA012010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013010008.T; Real TsCABI0CabiA013010008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013010008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001011008.T; Real TsCABI0CabiA001011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002011008.T; Real TsCABI0CabiA002011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003011008.T; Real TsCABI0CabiA003011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004011008.T; Real TsCABI0CabiA004011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005011008.T; Real TsCABI0CabiA005011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006011008.T; Real TsCABI0CabiA006011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007011008.T; Real TsCABI0CabiA007011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008011008.T; Real TsCABI0CabiA008011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009011008.T; Real TsCABI0CabiA009011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010011008.T; Real TsCABI0CabiA010011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011011008.T; Real TsCABI0CabiA011011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012011008.T; Real TsCABI0CabiA012011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013011008.T; Real TsCABI0CabiA013011008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013011008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001012008.T; Real TsCABI0CabiA001012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002012008.T; Real TsCABI0CabiA002012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003012008.T; Real TsCABI0CabiA003012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004012008.T; Real TsCABI0CabiA004012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005012008.T; Real TsCABI0CabiA005012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006012008.T; Real TsCABI0CabiA006012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007012008.T; Real TsCABI0CabiA007012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008012008.T; Real TsCABI0CabiA008012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009012008.T; Real TsCABI0CabiA009012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010012008.T; Real TsCABI0CabiA010012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011012008.T; Real TsCABI0CabiA011012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012012008.T; Real TsCABI0CabiA012012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013012008.T; Real TsCABI0CabiA013012008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013012008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001013008.T; Real TsCABI0CabiA001013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002013008.T; Real TsCABI0CabiA002013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003013008.T; Real TsCABI0CabiA003013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004013008.T; Real TsCABI0CabiA004013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005013008.T; Real TsCABI0CabiA005013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006013008.T; Real TsCABI0CabiA006013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007013008.T; Real TsCABI0CabiA007013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008013008.T; Real TsCABI0CabiA008013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009013008.T; Real TsCABI0CabiA009013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010013008.T; Real TsCABI0CabiA010013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011013008.T; Real TsCABI0CabiA011013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012013008.T; Real TsCABI0CabiA012013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013013008.T; Real TsCABI0CabiA013013008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013013008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001014008.T; Real TsCABI0CabiA001014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002014008.T; Real TsCABI0CabiA002014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003014008.T; Real TsCABI0CabiA003014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004014008.T; Real TsCABI0CabiA004014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005014008.T; Real TsCABI0CabiA005014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006014008.T; Real TsCABI0CabiA006014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007014008.T; Real TsCABI0CabiA007014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008014008.T; Real TsCABI0CabiA008014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009014008.T; Real TsCABI0CabiA009014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010014008.T; Real TsCABI0CabiA010014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011014008.T; Real TsCABI0CabiA011014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012014008.T; Real TsCABI0CabiA012014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013014008.T; Real TsCABI0CabiA013014008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013014008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001015008.T; Real TsCABI0CabiA001015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002015008.T; Real TsCABI0CabiA002015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003015008.T; Real TsCABI0CabiA003015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004015008.T; Real TsCABI0CabiA004015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005015008.T; Real TsCABI0CabiA005015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006015008.T; Real TsCABI0CabiA006015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007015008.T; Real TsCABI0CabiA007015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008015008.T; Real TsCABI0CabiA008015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009015008.T; Real TsCABI0CabiA009015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010015008.T; Real TsCABI0CabiA010015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011015008.T; Real TsCABI0CabiA011015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012015008.T; Real TsCABI0CabiA012015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013015008.T; Real TsCABI0CabiA013015008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013015008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA001016008.T; Real TsCABI0CabiA001016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA001016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA002016008.T; Real TsCABI0CabiA002016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA002016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA003016008.T; Real TsCABI0CabiA003016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA003016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA004016008.T; Real TsCABI0CabiA004016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA004016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA005016008.T; Real TsCABI0CabiA005016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA005016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA006016008.T; Real TsCABI0CabiA006016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA006016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA007016008.T; Real TsCABI0CabiA007016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA007016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA008016008.T; Real TsCABI0CabiA008016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA008016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA009016008.T; Real TsCABI0CabiA009016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA009016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA010016008.T; Real TsCABI0CabiA010016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA010016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA011016008.T; Real TsCABI0CabiA011016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA011016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA012016008.T; Real TsCABI0CabiA012016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA012016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsCABI0CabiA013016008.T; Real TsCABI0CabiA013016008.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsCABI0CabiA013016008.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA004005002.T; Real TsGS0CabiA004005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA004005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA005005002.T; Real TsGS0CabiA005005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA005005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA006005002.T; Real TsGS0CabiA006005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA006005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA007005002.T; Real TsGS0CabiA007005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA007005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA008005002.T; Real TsGS0CabiA008005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA008005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA009005002.T; Real TsGS0CabiA009005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA009005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA010005002.T; Real TsGS0CabiA010005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA010005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA011005002.T; Real TsGS0CabiA011005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA011005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA004006002.T; Real TsGS0CabiA004006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA004006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA005006002.T; Real TsGS0CabiA005006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA005006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA006006002.T; Real TsGS0CabiA006006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA006006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA007006002.T; Real TsGS0CabiA007006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA007006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA008006002.T; Real TsGS0CabiA008006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA008006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA009006002.T; Real TsGS0CabiA009006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA009006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA010006002.T; Real TsGS0CabiA010006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA010006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA011006002.T; Real TsGS0CabiA011006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA011006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA004007002.T; Real TsGS0CabiA004007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA004007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA005007002.T; Real TsGS0CabiA005007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA005007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA006007002.T; Real TsGS0CabiA006007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA006007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA007007002.T; Real TsGS0CabiA007007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA007007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA008007002.T; Real TsGS0CabiA008007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA008007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA009007002.T; Real TsGS0CabiA009007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA009007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA010007002.T; Real TsGS0CabiA010007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA010007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA011007002.T; Real TsGS0CabiA011007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA011007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA004008002.T; Real TsGS0CabiA004008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA004008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA005008002.T; Real TsGS0CabiA005008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA005008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA006008002.T; Real TsGS0CabiA006008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA006008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA007008002.T; Real TsGS0CabiA007008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA007008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA008008002.T; Real TsGS0CabiA008008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA008008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA009008002.T; Real TsGS0CabiA009008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA009008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA010008002.T; Real TsGS0CabiA010008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA010008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA011008002.T; Real TsGS0CabiA011008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA011008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA004009002.T; Real TsGS0CabiA004009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA004009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA005009002.T; Real TsGS0CabiA005009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA005009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA006009002.T; Real TsGS0CabiA006009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA006009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA007009002.T; Real TsGS0CabiA007009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA007009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA008009002.T; Real TsGS0CabiA008009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA008009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA009009002.T; Real TsGS0CabiA009009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA009009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA010009002.T; Real TsGS0CabiA010009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA010009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA011009002.T; Real TsGS0CabiA011009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA011009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA004010002.T; Real TsGS0CabiA004010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA004010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA005010002.T; Real TsGS0CabiA005010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA005010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA006010002.T; Real TsGS0CabiA006010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA006010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA007010002.T; Real TsGS0CabiA007010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA007010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA008010002.T; Real TsGS0CabiA008010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA008010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA009010002.T; Real TsGS0CabiA009010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA009010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA010010002.T; Real TsGS0CabiA010010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA010010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA011010002.T; Real TsGS0CabiA011010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA011010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA004011002.T; Real TsGS0CabiA004011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA004011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA005011002.T; Real TsGS0CabiA005011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA005011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA006011002.T; Real TsGS0CabiA006011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA006011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA007011002.T; Real TsGS0CabiA007011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA007011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA008011002.T; Real TsGS0CabiA008011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA008011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA009011002.T; Real TsGS0CabiA009011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA009011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA010011002.T; Real TsGS0CabiA010011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA010011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA011011002.T; Real TsGS0CabiA011011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA011011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA004012002.T; Real TsGS0CabiA004012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA004012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA005012002.T; Real TsGS0CabiA005012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA005012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA006012002.T; Real TsGS0CabiA006012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA006012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA007012002.T; Real TsGS0CabiA007012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA007012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA008012002.T; Real TsGS0CabiA008012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA008012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA009012002.T; Real TsGS0CabiA009012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA009012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA010012002.T; Real TsGS0CabiA010012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA010012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA011012002.T; Real TsGS0CabiA011012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA011012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA004013002.T; Real TsGS0CabiA004013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA004013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA005013002.T; Real TsGS0CabiA005013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA005013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA006013002.T; Real TsGS0CabiA006013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA006013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA007013002.T; Real TsGS0CabiA007013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA007013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA008013002.T; Real TsGS0CabiA008013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA008013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA009013002.T; Real TsGS0CabiA009013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA009013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA010013002.T; Real TsGS0CabiA010013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA010013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA011013002.T; Real TsGS0CabiA011013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA011013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA004004002.T; Real TsGS0CabiA004004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA004004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA005004002.T; Real TsGS0CabiA005004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA005004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA006004002.T; Real TsGS0CabiA006004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA006004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA007004002.T; Real TsGS0CabiA007004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA007004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA008004002.T; Real TsGS0CabiA008004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA008004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA009004002.T; Real TsGS0CabiA009004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA009004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA010004002.T; Real TsGS0CabiA010004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA010004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsGS0CabiA011004002.T; Real TsGS0CabiA011004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsGS0CabiA011004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002015007.T; Real TsAIR0CabiA002015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003015007.T; Real TsAIR0CabiA003015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004015007.T; Real TsAIR0CabiA004015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005015007.T; Real TsAIR0CabiA005015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006015007.T; Real TsAIR0CabiA006015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007015007.T; Real TsAIR0CabiA007015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008015007.T; Real TsAIR0CabiA008015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009015007.T; Real TsAIR0CabiA009015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010015007.T; Real TsAIR0CabiA010015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011015007.T; Real TsAIR0CabiA011015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012015007.T; Real TsAIR0CabiA012015007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012015007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002014007.T; Real TsAIR0CabiA002014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003014007.T; Real TsAIR0CabiA003014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004014007.T; Real TsAIR0CabiA004014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005014007.T; Real TsAIR0CabiA005014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006014007.T; Real TsAIR0CabiA006014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007014007.T; Real TsAIR0CabiA007014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008014007.T; Real TsAIR0CabiA008014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009014007.T; Real TsAIR0CabiA009014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010014007.T; Real TsAIR0CabiA010014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011014007.T; Real TsAIR0CabiA011014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012014007.T; Real TsAIR0CabiA012014007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012014007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002007007.T; Real TsAIR0CabiA002007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003007007.T; Real TsAIR0CabiA003007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004007007.T; Real TsAIR0CabiA004007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005007007.T; Real TsAIR0CabiA005007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006007007.T; Real TsAIR0CabiA006007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007007007.T; Real TsAIR0CabiA007007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008007007.T; Real TsAIR0CabiA008007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009007007.T; Real TsAIR0CabiA009007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010007007.T; Real TsAIR0CabiA010007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011007007.T; Real TsAIR0CabiA011007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012007007.T; Real TsAIR0CabiA012007007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012007007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002008007.T; Real TsAIR0CabiA002008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003008007.T; Real TsAIR0CabiA003008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004008007.T; Real TsAIR0CabiA004008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005008007.T; Real TsAIR0CabiA005008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006008007.T; Real TsAIR0CabiA006008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007008007.T; Real TsAIR0CabiA007008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008008007.T; Real TsAIR0CabiA008008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009008007.T; Real TsAIR0CabiA009008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010008007.T; Real TsAIR0CabiA010008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011008007.T; Real TsAIR0CabiA011008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012008007.T; Real TsAIR0CabiA012008007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012008007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002009007.T; Real TsAIR0CabiA002009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003009007.T; Real TsAIR0CabiA003009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004009007.T; Real TsAIR0CabiA004009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005009007.T; Real TsAIR0CabiA005009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006009007.T; Real TsAIR0CabiA006009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007009007.T; Real TsAIR0CabiA007009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008009007.T; Real TsAIR0CabiA008009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009009007.T; Real TsAIR0CabiA009009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010009007.T; Real TsAIR0CabiA010009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011009007.T; Real TsAIR0CabiA011009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012009007.T; Real TsAIR0CabiA012009007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012009007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002010007.T; Real TsAIR0CabiA002010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003010007.T; Real TsAIR0CabiA003010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004010007.T; Real TsAIR0CabiA004010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005010007.T; Real TsAIR0CabiA005010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006010007.T; Real TsAIR0CabiA006010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007010007.T; Real TsAIR0CabiA007010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008010007.T; Real TsAIR0CabiA008010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009010007.T; Real TsAIR0CabiA009010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010010007.T; Real TsAIR0CabiA010010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011010007.T; Real TsAIR0CabiA011010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012010007.T; Real TsAIR0CabiA012010007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012010007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002011007.T; Real TsAIR0CabiA002011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003011007.T; Real TsAIR0CabiA003011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004011007.T; Real TsAIR0CabiA004011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005011007.T; Real TsAIR0CabiA005011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006011007.T; Real TsAIR0CabiA006011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007011007.T; Real TsAIR0CabiA007011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008011007.T; Real TsAIR0CabiA008011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009011007.T; Real TsAIR0CabiA009011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010011007.T; Real TsAIR0CabiA010011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011011007.T; Real TsAIR0CabiA011011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012011007.T; Real TsAIR0CabiA012011007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012011007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002012007.T; Real TsAIR0CabiA002012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003012007.T; Real TsAIR0CabiA003012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004012007.T; Real TsAIR0CabiA004012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005012007.T; Real TsAIR0CabiA005012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006012007.T; Real TsAIR0CabiA006012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007012007.T; Real TsAIR0CabiA007012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008012007.T; Real TsAIR0CabiA008012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009012007.T; Real TsAIR0CabiA009012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010012007.T; Real TsAIR0CabiA010012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011012007.T; Real TsAIR0CabiA011012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012012007.T; Real TsAIR0CabiA012012007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012012007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002013007.T; Real TsAIR0CabiA002013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003013007.T; Real TsAIR0CabiA003013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004013007.T; Real TsAIR0CabiA004013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005013007.T; Real TsAIR0CabiA005013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006013007.T; Real TsAIR0CabiA006013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007013007.T; Real TsAIR0CabiA007013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008013007.T; Real TsAIR0CabiA008013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009013007.T; Real TsAIR0CabiA009013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010013007.T; Real TsAIR0CabiA010013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011013007.T; Real TsAIR0CabiA011013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012013007.T; Real TsAIR0CabiA012013007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012013007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002002007.T; Real TsAIR0CabiA002002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003002007.T; Real TsAIR0CabiA003002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004002007.T; Real TsAIR0CabiA004002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005002007.T; Real TsAIR0CabiA005002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006002007.T; Real TsAIR0CabiA006002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007002007.T; Real TsAIR0CabiA007002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008002007.T; Real TsAIR0CabiA008002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009002007.T; Real TsAIR0CabiA009002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010002007.T; Real TsAIR0CabiA010002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011002007.T; Real TsAIR0CabiA011002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012002007.T; Real TsAIR0CabiA012002007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012002007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002003007.T; Real TsAIR0CabiA002003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003003007.T; Real TsAIR0CabiA003003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004003007.T; Real TsAIR0CabiA004003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005003007.T; Real TsAIR0CabiA005003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006003007.T; Real TsAIR0CabiA006003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007003007.T; Real TsAIR0CabiA007003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008003007.T; Real TsAIR0CabiA008003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009003007.T; Real TsAIR0CabiA009003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010003007.T; Real TsAIR0CabiA010003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011003007.T; Real TsAIR0CabiA011003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012003007.T; Real TsAIR0CabiA012003007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012003007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002004007.T; Real TsAIR0CabiA002004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003004007.T; Real TsAIR0CabiA003004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004004007.T; Real TsAIR0CabiA004004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005004007.T; Real TsAIR0CabiA005004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006004007.T; Real TsAIR0CabiA006004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007004007.T; Real TsAIR0CabiA007004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008004007.T; Real TsAIR0CabiA008004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009004007.T; Real TsAIR0CabiA009004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010004007.T; Real TsAIR0CabiA010004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011004007.T; Real TsAIR0CabiA011004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012004007.T; Real TsAIR0CabiA012004007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012004007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002005007.T; Real TsAIR0CabiA002005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003005007.T; Real TsAIR0CabiA003005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004005007.T; Real TsAIR0CabiA004005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005005007.T; Real TsAIR0CabiA005005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006005007.T; Real TsAIR0CabiA006005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007005007.T; Real TsAIR0CabiA007005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008005007.T; Real TsAIR0CabiA008005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009005007.T; Real TsAIR0CabiA009005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010005007.T; Real TsAIR0CabiA010005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011005007.T; Real TsAIR0CabiA011005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012005007.T; Real TsAIR0CabiA012005007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012005007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002006007.T; Real TsAIR0CabiA002006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003006007.T; Real TsAIR0CabiA003006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004006007.T; Real TsAIR0CabiA004006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005006007.T; Real TsAIR0CabiA005006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006006007.T; Real TsAIR0CabiA006006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007006007.T; Real TsAIR0CabiA007006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008006007.T; Real TsAIR0CabiA008006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009006007.T; Real TsAIR0CabiA009006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010006007.T; Real TsAIR0CabiA010006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011006007.T; Real TsAIR0CabiA011006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012006007.T; Real TsAIR0CabiA012006007.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012006007.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011009006.T; Real TsAIR0CabiA011009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012009006.T; Real TsAIR0CabiA012009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002010006.T; Real TsAIR0CabiA002010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003010006.T; Real TsAIR0CabiA003010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004010006.T; Real TsAIR0CabiA004010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005010006.T; Real TsAIR0CabiA005010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006010006.T; Real TsAIR0CabiA006010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007010006.T; Real TsAIR0CabiA007010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011010006.T; Real TsAIR0CabiA011010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012010006.T; Real TsAIR0CabiA012010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002011006.T; Real TsAIR0CabiA002011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003011006.T; Real TsAIR0CabiA003011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007011006.T; Real TsAIR0CabiA007011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011011006.T; Real TsAIR0CabiA011011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012011006.T; Real TsAIR0CabiA012011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002012006.T; Real TsAIR0CabiA002012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003012006.T; Real TsAIR0CabiA003012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007012006.T; Real TsAIR0CabiA007012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008012006.T; Real TsAIR0CabiA008012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009012006.T; Real TsAIR0CabiA009012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010012006.T; Real TsAIR0CabiA010012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011012006.T; Real TsAIR0CabiA011012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012012006.T; Real TsAIR0CabiA012012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002013006.T; Real TsAIR0CabiA002013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003013006.T; Real TsAIR0CabiA003013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007013006.T; Real TsAIR0CabiA007013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008013006.T; Real TsAIR0CabiA008013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009013006.T; Real TsAIR0CabiA009013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010013006.T; Real TsAIR0CabiA010013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011013006.T; Real TsAIR0CabiA011013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012013006.T; Real TsAIR0CabiA012013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002014006.T; Real TsAIR0CabiA002014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003014006.T; Real TsAIR0CabiA003014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004014006.T; Real TsAIR0CabiA004014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005014006.T; Real TsAIR0CabiA005014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006014006.T; Real TsAIR0CabiA006014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007014006.T; Real TsAIR0CabiA007014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008014006.T; Real TsAIR0CabiA008014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009014006.T; Real TsAIR0CabiA009014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010014006.T; Real TsAIR0CabiA010014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011014006.T; Real TsAIR0CabiA011014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012014006.T; Real TsAIR0CabiA012014006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012014006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002015006.T; Real TsAIR0CabiA002015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003015006.T; Real TsAIR0CabiA003015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004015006.T; Real TsAIR0CabiA004015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005015006.T; Real TsAIR0CabiA005015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006015006.T; Real TsAIR0CabiA006015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007015006.T; Real TsAIR0CabiA007015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008015006.T; Real TsAIR0CabiA008015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009015006.T; Real TsAIR0CabiA009015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010015006.T; Real TsAIR0CabiA010015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011015006.T; Real TsAIR0CabiA011015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012015006.T; Real TsAIR0CabiA012015006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012015006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010005006.T; Real TsAIR0CabiA010005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011005006.T; Real TsAIR0CabiA011005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012005006.T; Real TsAIR0CabiA012005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002006006.T; Real TsAIR0CabiA002006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003006006.T; Real TsAIR0CabiA003006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004006006.T; Real TsAIR0CabiA004006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005006006.T; Real TsAIR0CabiA005006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010006006.T; Real TsAIR0CabiA010006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011006006.T; Real TsAIR0CabiA011006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012006006.T; Real TsAIR0CabiA012006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002007006.T; Real TsAIR0CabiA002007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003007006.T; Real TsAIR0CabiA003007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004007006.T; Real TsAIR0CabiA004007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005007006.T; Real TsAIR0CabiA005007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006007006.T; Real TsAIR0CabiA006007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007007006.T; Real TsAIR0CabiA007007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008007006.T; Real TsAIR0CabiA008007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009007006.T; Real TsAIR0CabiA009007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010007006.T; Real TsAIR0CabiA010007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011007006.T; Real TsAIR0CabiA011007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012007006.T; Real TsAIR0CabiA012007006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012007006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002008006.T; Real TsAIR0CabiA002008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003008006.T; Real TsAIR0CabiA003008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004008006.T; Real TsAIR0CabiA004008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005008006.T; Real TsAIR0CabiA005008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006008006.T; Real TsAIR0CabiA006008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007008006.T; Real TsAIR0CabiA007008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008008006.T; Real TsAIR0CabiA008008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009008006.T; Real TsAIR0CabiA009008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010008006.T; Real TsAIR0CabiA010008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011008006.T; Real TsAIR0CabiA011008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012008006.T; Real TsAIR0CabiA012008006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012008006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002009006.T; Real TsAIR0CabiA002009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003009006.T; Real TsAIR0CabiA003009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004009006.T; Real TsAIR0CabiA004009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005009006.T; Real TsAIR0CabiA005009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006009006.T; Real TsAIR0CabiA006009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007009006.T; Real TsAIR0CabiA007009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002002006.T; Real TsAIR0CabiA002002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003002006.T; Real TsAIR0CabiA003002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004002006.T; Real TsAIR0CabiA004002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005002006.T; Real TsAIR0CabiA005002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006002006.T; Real TsAIR0CabiA006002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007002006.T; Real TsAIR0CabiA007002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008002006.T; Real TsAIR0CabiA008002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009002006.T; Real TsAIR0CabiA009002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010002006.T; Real TsAIR0CabiA010002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011002006.T; Real TsAIR0CabiA011002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012002006.T; Real TsAIR0CabiA012002006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012002006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002003006.T; Real TsAIR0CabiA002003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003003006.T; Real TsAIR0CabiA003003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004003006.T; Real TsAIR0CabiA004003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005003006.T; Real TsAIR0CabiA005003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006003006.T; Real TsAIR0CabiA006003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007003006.T; Real TsAIR0CabiA007003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008003006.T; Real TsAIR0CabiA008003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009003006.T; Real TsAIR0CabiA009003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010003006.T; Real TsAIR0CabiA010003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011003006.T; Real TsAIR0CabiA011003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012003006.T; Real TsAIR0CabiA012003006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012003006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002004006.T; Real TsAIR0CabiA002004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003004006.T; Real TsAIR0CabiA003004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004004006.T; Real TsAIR0CabiA004004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005004006.T; Real TsAIR0CabiA005004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010004006.T; Real TsAIR0CabiA010004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011004006.T; Real TsAIR0CabiA011004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012004006.T; Real TsAIR0CabiA012004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002005006.T; Real TsAIR0CabiA002005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003005006.T; Real TsAIR0CabiA003005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004005006.T; Real TsAIR0CabiA004005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005005006.T; Real TsAIR0CabiA005005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002002005.T; Real TsAIR0CabiA002002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003002005.T; Real TsAIR0CabiA003002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004002005.T; Real TsAIR0CabiA004002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005002005.T; Real TsAIR0CabiA005002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006002005.T; Real TsAIR0CabiA006002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007002005.T; Real TsAIR0CabiA007002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008002005.T; Real TsAIR0CabiA008002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009002005.T; Real TsAIR0CabiA009002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010002005.T; Real TsAIR0CabiA010002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011002005.T; Real TsAIR0CabiA011002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012002005.T; Real TsAIR0CabiA012002005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012002005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002003005.T; Real TsAIR0CabiA002003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012003005.T; Real TsAIR0CabiA012003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002004005.T; Real TsAIR0CabiA002004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012004005.T; Real TsAIR0CabiA012004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002005005.T; Real TsAIR0CabiA002005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012005005.T; Real TsAIR0CabiA012005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002006005.T; Real TsAIR0CabiA002006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012006005.T; Real TsAIR0CabiA012006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002007005.T; Real TsAIR0CabiA002007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012007005.T; Real TsAIR0CabiA012007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002008005.T; Real TsAIR0CabiA002008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012008005.T; Real TsAIR0CabiA012008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002009005.T; Real TsAIR0CabiA002009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012009005.T; Real TsAIR0CabiA012009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002010005.T; Real TsAIR0CabiA002010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012010005.T; Real TsAIR0CabiA012010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002011005.T; Real TsAIR0CabiA002011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012011005.T; Real TsAIR0CabiA012011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002012005.T; Real TsAIR0CabiA002012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012012005.T; Real TsAIR0CabiA012012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002013005.T; Real TsAIR0CabiA002013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012013005.T; Real TsAIR0CabiA012013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002014005.T; Real TsAIR0CabiA002014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012014005.T; Real TsAIR0CabiA012014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002015005.T; Real TsAIR0CabiA002015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003015005.T; Real TsAIR0CabiA003015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004015005.T; Real TsAIR0CabiA004015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005015005.T; Real TsAIR0CabiA005015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006015005.T; Real TsAIR0CabiA006015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007015005.T; Real TsAIR0CabiA007015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008015005.T; Real TsAIR0CabiA008015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009015005.T; Real TsAIR0CabiA009015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010015005.T; Real TsAIR0CabiA010015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011015005.T; Real TsAIR0CabiA011015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012015005.T; Real TsAIR0CabiA012015005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012015005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002002004.T; Real TsAIR0CabiA002002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003002004.T; Real TsAIR0CabiA003002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004002004.T; Real TsAIR0CabiA004002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005002004.T; Real TsAIR0CabiA005002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006002004.T; Real TsAIR0CabiA006002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007002004.T; Real TsAIR0CabiA007002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008002004.T; Real TsAIR0CabiA008002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009002004.T; Real TsAIR0CabiA009002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010002004.T; Real TsAIR0CabiA010002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011002004.T; Real TsAIR0CabiA011002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012002004.T; Real TsAIR0CabiA012002004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012002004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002003004.T; Real TsAIR0CabiA002003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003003004.T; Real TsAIR0CabiA003003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004003004.T; Real TsAIR0CabiA004003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005003004.T; Real TsAIR0CabiA005003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006003004.T; Real TsAIR0CabiA006003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007003004.T; Real TsAIR0CabiA007003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008003004.T; Real TsAIR0CabiA008003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009003004.T; Real TsAIR0CabiA009003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010003004.T; Real TsAIR0CabiA010003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011003004.T; Real TsAIR0CabiA011003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012003004.T; Real TsAIR0CabiA012003004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012003004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002004004.T; Real TsAIR0CabiA002004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003004004.T; Real TsAIR0CabiA003004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008004004.T; Real TsAIR0CabiA008004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009004004.T; Real TsAIR0CabiA009004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010004004.T; Real TsAIR0CabiA010004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011004004.T; Real TsAIR0CabiA011004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012004004.T; Real TsAIR0CabiA012004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002005004.T; Real TsAIR0CabiA002005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003005004.T; Real TsAIR0CabiA003005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008005004.T; Real TsAIR0CabiA008005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009005004.T; Real TsAIR0CabiA009005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010005004.T; Real TsAIR0CabiA010005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011005004.T; Real TsAIR0CabiA011005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012005004.T; Real TsAIR0CabiA012005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002006004.T; Real TsAIR0CabiA002006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003006004.T; Real TsAIR0CabiA003006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008006004.T; Real TsAIR0CabiA008006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009006004.T; Real TsAIR0CabiA009006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010006004.T; Real TsAIR0CabiA010006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011006004.T; Real TsAIR0CabiA011006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012006004.T; Real TsAIR0CabiA012006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002007004.T; Real TsAIR0CabiA002007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003007004.T; Real TsAIR0CabiA003007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004007004.T; Real TsAIR0CabiA004007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005007004.T; Real TsAIR0CabiA005007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006007004.T; Real TsAIR0CabiA006007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007007004.T; Real TsAIR0CabiA007007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008007004.T; Real TsAIR0CabiA008007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009007004.T; Real TsAIR0CabiA009007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010007004.T; Real TsAIR0CabiA010007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011007004.T; Real TsAIR0CabiA011007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012007004.T; Real TsAIR0CabiA012007004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012007004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002008004.T; Real TsAIR0CabiA002008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003008004.T; Real TsAIR0CabiA003008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004008004.T; Real TsAIR0CabiA004008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005008004.T; Real TsAIR0CabiA005008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006008004.T; Real TsAIR0CabiA006008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007008004.T; Real TsAIR0CabiA007008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011008004.T; Real TsAIR0CabiA011008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012008004.T; Real TsAIR0CabiA012008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002009004.T; Real TsAIR0CabiA002009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003009004.T; Real TsAIR0CabiA003009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004009004.T; Real TsAIR0CabiA004009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005009004.T; Real TsAIR0CabiA005009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006009004.T; Real TsAIR0CabiA006009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007009004.T; Real TsAIR0CabiA007009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011009004.T; Real TsAIR0CabiA011009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012009004.T; Real TsAIR0CabiA012009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002010004.T; Real TsAIR0CabiA002010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003010004.T; Real TsAIR0CabiA003010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004010004.T; Real TsAIR0CabiA004010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005010004.T; Real TsAIR0CabiA005010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006010004.T; Real TsAIR0CabiA006010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007010004.T; Real TsAIR0CabiA007010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011010004.T; Real TsAIR0CabiA011010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012010004.T; Real TsAIR0CabiA012010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002011004.T; Real TsAIR0CabiA002011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003011004.T; Real TsAIR0CabiA003011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007011004.T; Real TsAIR0CabiA007011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008011004.T; Real TsAIR0CabiA008011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009011004.T; Real TsAIR0CabiA009011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010011004.T; Real TsAIR0CabiA010011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011011004.T; Real TsAIR0CabiA011011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012011004.T; Real TsAIR0CabiA012011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002012004.T; Real TsAIR0CabiA002012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003012004.T; Real TsAIR0CabiA003012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007012004.T; Real TsAIR0CabiA007012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008012004.T; Real TsAIR0CabiA008012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009012004.T; Real TsAIR0CabiA009012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010012004.T; Real TsAIR0CabiA010012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011012004.T; Real TsAIR0CabiA011012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012012004.T; Real TsAIR0CabiA012012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002013004.T; Real TsAIR0CabiA002013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003013004.T; Real TsAIR0CabiA003013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007013004.T; Real TsAIR0CabiA007013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008013004.T; Real TsAIR0CabiA008013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009013004.T; Real TsAIR0CabiA009013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010013004.T; Real TsAIR0CabiA010013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011013004.T; Real TsAIR0CabiA011013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012013004.T; Real TsAIR0CabiA012013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002014004.T; Real TsAIR0CabiA002014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003014004.T; Real TsAIR0CabiA003014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004014004.T; Real TsAIR0CabiA004014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005014004.T; Real TsAIR0CabiA005014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006014004.T; Real TsAIR0CabiA006014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007014004.T; Real TsAIR0CabiA007014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008014004.T; Real TsAIR0CabiA008014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009014004.T; Real TsAIR0CabiA009014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010014004.T; Real TsAIR0CabiA010014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011014004.T; Real TsAIR0CabiA011014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012014004.T; Real TsAIR0CabiA012014004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012014004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002015004.T; Real TsAIR0CabiA002015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003015004.T; Real TsAIR0CabiA003015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004015004.T; Real TsAIR0CabiA004015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005015004.T; Real TsAIR0CabiA005015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006015004.T; Real TsAIR0CabiA006015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007015004.T; Real TsAIR0CabiA007015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008015004.T; Real TsAIR0CabiA008015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009015004.T; Real TsAIR0CabiA009015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010015004.T; Real TsAIR0CabiA010015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011015004.T; Real TsAIR0CabiA011015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012015004.T; Real TsAIR0CabiA012015004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012015004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002002003.T; Real TsAIR0CabiA002002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003002003.T; Real TsAIR0CabiA003002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004002003.T; Real TsAIR0CabiA004002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005002003.T; Real TsAIR0CabiA005002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006002003.T; Real TsAIR0CabiA006002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007002003.T; Real TsAIR0CabiA007002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008002003.T; Real TsAIR0CabiA008002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009002003.T; Real TsAIR0CabiA009002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010002003.T; Real TsAIR0CabiA010002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011002003.T; Real TsAIR0CabiA011002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012002003.T; Real TsAIR0CabiA012002003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012002003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002003003.T; Real TsAIR0CabiA002003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003003003.T; Real TsAIR0CabiA003003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004003003.T; Real TsAIR0CabiA004003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005003003.T; Real TsAIR0CabiA005003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006003003.T; Real TsAIR0CabiA006003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007003003.T; Real TsAIR0CabiA007003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008003003.T; Real TsAIR0CabiA008003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009003003.T; Real TsAIR0CabiA009003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010003003.T; Real TsAIR0CabiA010003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011003003.T; Real TsAIR0CabiA011003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012003003.T; Real TsAIR0CabiA012003003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012003003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002004003.T; Real TsAIR0CabiA002004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003004003.T; Real TsAIR0CabiA003004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004004003.T; Real TsAIR0CabiA004004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005004003.T; Real TsAIR0CabiA005004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006004003.T; Real TsAIR0CabiA006004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007004003.T; Real TsAIR0CabiA007004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008004003.T; Real TsAIR0CabiA008004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009004003.T; Real TsAIR0CabiA009004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010004003.T; Real TsAIR0CabiA010004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011004003.T; Real TsAIR0CabiA011004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012004003.T; Real TsAIR0CabiA012004003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012004003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002005003.T; Real TsAIR0CabiA002005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003005003.T; Real TsAIR0CabiA003005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004005003.T; Real TsAIR0CabiA004005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005005003.T; Real TsAIR0CabiA005005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006005003.T; Real TsAIR0CabiA006005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007005003.T; Real TsAIR0CabiA007005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008005003.T; Real TsAIR0CabiA008005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009005003.T; Real TsAIR0CabiA009005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010005003.T; Real TsAIR0CabiA010005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011005003.T; Real TsAIR0CabiA011005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012005003.T; Real TsAIR0CabiA012005003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012005003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002006003.T; Real TsAIR0CabiA002006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003006003.T; Real TsAIR0CabiA003006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004006003.T; Real TsAIR0CabiA004006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005006003.T; Real TsAIR0CabiA005006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006006003.T; Real TsAIR0CabiA006006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007006003.T; Real TsAIR0CabiA007006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008006003.T; Real TsAIR0CabiA008006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009006003.T; Real TsAIR0CabiA009006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010006003.T; Real TsAIR0CabiA010006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011006003.T; Real TsAIR0CabiA011006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012006003.T; Real TsAIR0CabiA012006003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012006003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002007003.T; Real TsAIR0CabiA002007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003007003.T; Real TsAIR0CabiA003007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004007003.T; Real TsAIR0CabiA004007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005007003.T; Real TsAIR0CabiA005007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006007003.T; Real TsAIR0CabiA006007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007007003.T; Real TsAIR0CabiA007007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008007003.T; Real TsAIR0CabiA008007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009007003.T; Real TsAIR0CabiA009007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010007003.T; Real TsAIR0CabiA010007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011007003.T; Real TsAIR0CabiA011007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012007003.T; Real TsAIR0CabiA012007003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012007003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002008003.T; Real TsAIR0CabiA002008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003008003.T; Real TsAIR0CabiA003008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004008003.T; Real TsAIR0CabiA004008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005008003.T; Real TsAIR0CabiA005008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006008003.T; Real TsAIR0CabiA006008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007008003.T; Real TsAIR0CabiA007008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011008003.T; Real TsAIR0CabiA011008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012008003.T; Real TsAIR0CabiA012008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002009003.T; Real TsAIR0CabiA002009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003009003.T; Real TsAIR0CabiA003009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004009003.T; Real TsAIR0CabiA004009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005009003.T; Real TsAIR0CabiA005009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006009003.T; Real TsAIR0CabiA006009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007009003.T; Real TsAIR0CabiA007009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011009003.T; Real TsAIR0CabiA011009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012009003.T; Real TsAIR0CabiA012009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002010003.T; Real TsAIR0CabiA002010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003010003.T; Real TsAIR0CabiA003010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004010003.T; Real TsAIR0CabiA004010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005010003.T; Real TsAIR0CabiA005010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006010003.T; Real TsAIR0CabiA006010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007010003.T; Real TsAIR0CabiA007010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011010003.T; Real TsAIR0CabiA011010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012010003.T; Real TsAIR0CabiA012010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002011003.T; Real TsAIR0CabiA002011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003011003.T; Real TsAIR0CabiA003011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004011003.T; Real TsAIR0CabiA004011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005011003.T; Real TsAIR0CabiA005011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006011003.T; Real TsAIR0CabiA006011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007011003.T; Real TsAIR0CabiA007011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008011003.T; Real TsAIR0CabiA008011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009011003.T; Real TsAIR0CabiA009011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010011003.T; Real TsAIR0CabiA010011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011011003.T; Real TsAIR0CabiA011011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012011003.T; Real TsAIR0CabiA012011003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012011003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002012003.T; Real TsAIR0CabiA002012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003012003.T; Real TsAIR0CabiA003012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004012003.T; Real TsAIR0CabiA004012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005012003.T; Real TsAIR0CabiA005012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006012003.T; Real TsAIR0CabiA006012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007012003.T; Real TsAIR0CabiA007012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008012003.T; Real TsAIR0CabiA008012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009012003.T; Real TsAIR0CabiA009012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010012003.T; Real TsAIR0CabiA010012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011012003.T; Real TsAIR0CabiA011012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012012003.T; Real TsAIR0CabiA012012003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012012003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002013003.T; Real TsAIR0CabiA002013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003013003.T; Real TsAIR0CabiA003013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004013003.T; Real TsAIR0CabiA004013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005013003.T; Real TsAIR0CabiA005013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006013003.T; Real TsAIR0CabiA006013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007013003.T; Real TsAIR0CabiA007013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008013003.T; Real TsAIR0CabiA008013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009013003.T; Real TsAIR0CabiA009013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010013003.T; Real TsAIR0CabiA010013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011013003.T; Real TsAIR0CabiA011013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012013003.T; Real TsAIR0CabiA012013003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012013003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002014003.T; Real TsAIR0CabiA002014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003014003.T; Real TsAIR0CabiA003014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004014003.T; Real TsAIR0CabiA004014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005014003.T; Real TsAIR0CabiA005014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006014003.T; Real TsAIR0CabiA006014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007014003.T; Real TsAIR0CabiA007014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008014003.T; Real TsAIR0CabiA008014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009014003.T; Real TsAIR0CabiA009014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010014003.T; Real TsAIR0CabiA010014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011014003.T; Real TsAIR0CabiA011014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012014003.T; Real TsAIR0CabiA012014003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012014003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002015003.T; Real TsAIR0CabiA002015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003015003.T; Real TsAIR0CabiA003015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004015003.T; Real TsAIR0CabiA004015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005015003.T; Real TsAIR0CabiA005015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006015003.T; Real TsAIR0CabiA006015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007015003.T; Real TsAIR0CabiA007015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008015003.T; Real TsAIR0CabiA008015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009015003.T; Real TsAIR0CabiA009015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010015003.T; Real TsAIR0CabiA010015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011015003.T; Real TsAIR0CabiA011015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012015003.T; Real TsAIR0CabiA012015003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012015003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012005002.T; Real TsAIR0CabiA012005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002006002.T; Real TsAIR0CabiA002006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003006002.T; Real TsAIR0CabiA003006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012006002.T; Real TsAIR0CabiA012006002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012006002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002007002.T; Real TsAIR0CabiA002007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003007002.T; Real TsAIR0CabiA003007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012007002.T; Real TsAIR0CabiA012007002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012007002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002008002.T; Real TsAIR0CabiA002008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003008002.T; Real TsAIR0CabiA003008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012008002.T; Real TsAIR0CabiA012008002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012008002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002009002.T; Real TsAIR0CabiA002009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003009002.T; Real TsAIR0CabiA003009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012009002.T; Real TsAIR0CabiA012009002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012009002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002010002.T; Real TsAIR0CabiA002010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003010002.T; Real TsAIR0CabiA003010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012010002.T; Real TsAIR0CabiA012010002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012010002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002011002.T; Real TsAIR0CabiA002011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003011002.T; Real TsAIR0CabiA003011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012011002.T; Real TsAIR0CabiA012011002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012011002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002012002.T; Real TsAIR0CabiA002012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003012002.T; Real TsAIR0CabiA003012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012012002.T; Real TsAIR0CabiA012012002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012012002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002013002.T; Real TsAIR0CabiA002013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003013002.T; Real TsAIR0CabiA003013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012013002.T; Real TsAIR0CabiA012013002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012013002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002014002.T; Real TsAIR0CabiA002014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003014002.T; Real TsAIR0CabiA003014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004014002.T; Real TsAIR0CabiA004014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005014002.T; Real TsAIR0CabiA005014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006014002.T; Real TsAIR0CabiA006014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007014002.T; Real TsAIR0CabiA007014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008014002.T; Real TsAIR0CabiA008014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009014002.T; Real TsAIR0CabiA009014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010014002.T; Real TsAIR0CabiA010014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011014002.T; Real TsAIR0CabiA011014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012014002.T; Real TsAIR0CabiA012014002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012014002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002015002.T; Real TsAIR0CabiA002015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003015002.T; Real TsAIR0CabiA003015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004015002.T; Real TsAIR0CabiA004015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005015002.T; Real TsAIR0CabiA005015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006015002.T; Real TsAIR0CabiA006015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007015002.T; Real TsAIR0CabiA007015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008015002.T; Real TsAIR0CabiA008015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009015002.T; Real TsAIR0CabiA009015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010015002.T; Real TsAIR0CabiA010015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011015002.T; Real TsAIR0CabiA011015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012015002.T; Real TsAIR0CabiA012015002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012015002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002004002.T; Real TsAIR0CabiA002004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003004002.T; Real TsAIR0CabiA003004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012004002.T; Real TsAIR0CabiA012004002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012004002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002005002.T; Real TsAIR0CabiA002005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003005002.T; Real TsAIR0CabiA003005002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003005002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002003002.T; Real TsAIR0CabiA002003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003003002.T; Real TsAIR0CabiA003003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004003002.T; Real TsAIR0CabiA004003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005003002.T; Real TsAIR0CabiA005003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006003002.T; Real TsAIR0CabiA006003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007003002.T; Real TsAIR0CabiA007003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008003002.T; Real TsAIR0CabiA008003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009003002.T; Real TsAIR0CabiA009003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010003002.T; Real TsAIR0CabiA010003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011003002.T; Real TsAIR0CabiA011003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012003002.T; Real TsAIR0CabiA012003002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012003002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA002002002.T; Real TsAIR0CabiA002002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA002002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA003002002.T; Real TsAIR0CabiA003002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA003002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA004002002.T; Real TsAIR0CabiA004002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA004002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA005002002.T; Real TsAIR0CabiA005002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA005002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA006002002.T; Real TsAIR0CabiA006002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA006002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA007002002.T; Real TsAIR0CabiA007002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA007002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA008002002.T; Real TsAIR0CabiA008002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA008002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA009002002.T; Real TsAIR0CabiA009002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA009002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA010002002.T; Real TsAIR0CabiA010002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA010002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA011002002.T; Real TsAIR0CabiA011002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA011002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsAIR0CabiA012002002.T; Real TsAIR0CabiA012002002.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsAIR0CabiA012002002.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsST0CabiA008008003.T; Real TsST0CabiA008008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsST0CabiA008008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsST0CabiA009008003.T; Real TsST0CabiA009008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsST0CabiA009008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsST0CabiA010008003.T; Real TsST0CabiA010008003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsST0CabiA010008003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsST0CabiA008009003.T; Real TsST0CabiA008009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsST0CabiA008009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsST0CabiA009009003.T; Real TsST0CabiA009009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsST0CabiA009009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsST0CabiA010009003.T; Real TsST0CabiA010009003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsST0CabiA010009003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsST0CabiA008010003.T; Real TsST0CabiA008010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsST0CabiA008010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsST0CabiA009010003.T; Real TsST0CabiA009010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsST0CabiA009010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsST0CabiA010010003.T; Real TsST0CabiA010010003.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsST0CabiA010010003.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA004004004.T; Real TsIC30CabiA004004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA004004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA005004004.T; Real TsIC30CabiA005004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA005004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA006004004.T; Real TsIC30CabiA006004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA006004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA007004004.T; Real TsIC30CabiA007004004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA007004004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA004005004.T; Real TsIC30CabiA004005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA004005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA005005004.T; Real TsIC30CabiA005005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA005005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA006005004.T; Real TsIC30CabiA006005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA006005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA007005004.T; Real TsIC30CabiA007005004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA007005004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA004006004.T; Real TsIC30CabiA004006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA004006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA005006004.T; Real TsIC30CabiA005006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA005006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA006006004.T; Real TsIC30CabiA006006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA006006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC30CabiA007006004.T; Real TsIC30CabiA007006004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC30CabiA007006004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC20CabiA008008004.T; Real TsIC20CabiA008008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC20CabiA008008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC20CabiA009008004.T; Real TsIC20CabiA009008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC20CabiA009008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC20CabiA010008004.T; Real TsIC20CabiA010008004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC20CabiA010008004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC20CabiA008009004.T; Real TsIC20CabiA008009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC20CabiA008009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC20CabiA009009004.T; Real TsIC20CabiA009009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC20CabiA009009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC20CabiA010009004.T; Real TsIC20CabiA010009004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC20CabiA010009004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC20CabiA008010004.T; Real TsIC20CabiA008010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC20CabiA008010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC20CabiA009010004.T; Real TsIC20CabiA009010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC20CabiA009010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC20CabiA010010004.T; Real TsIC20CabiA010010004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC20CabiA010010004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC60CabiA004011004.T; Real TsIC60CabiA004011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC60CabiA004011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC60CabiA005011004.T; Real TsIC60CabiA005011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC60CabiA005011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC60CabiA006011004.T; Real TsIC60CabiA006011004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC60CabiA006011004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC60CabiA004012004.T; Real TsIC60CabiA004012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC60CabiA004012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC60CabiA005012004.T; Real TsIC60CabiA005012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC60CabiA005012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC60CabiA006012004.T; Real TsIC60CabiA006012004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC60CabiA006012004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC60CabiA004013004.T; Real TsIC60CabiA004013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC60CabiA004013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC60CabiA005013004.T; Real TsIC60CabiA005013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC60CabiA005013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC60CabiA006013004.T; Real TsIC60CabiA006013004.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC60CabiA006013004.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003011005.T; Real TsPWB0CabiA003011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004011005.T; Real TsPWB0CabiA004011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005011005.T; Real TsPWB0CabiA005011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006011005.T; Real TsPWB0CabiA006011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007011005.T; Real TsPWB0CabiA007011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008011005.T; Real TsPWB0CabiA008011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009011005.T; Real TsPWB0CabiA009011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010011005.T; Real TsPWB0CabiA010011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011011005.T; Real TsPWB0CabiA011011005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011011005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003012005.T; Real TsPWB0CabiA003012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004012005.T; Real TsPWB0CabiA004012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005012005.T; Real TsPWB0CabiA005012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006012005.T; Real TsPWB0CabiA006012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007012005.T; Real TsPWB0CabiA007012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008012005.T; Real TsPWB0CabiA008012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009012005.T; Real TsPWB0CabiA009012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010012005.T; Real TsPWB0CabiA010012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011012005.T; Real TsPWB0CabiA011012005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011012005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003013005.T; Real TsPWB0CabiA003013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004013005.T; Real TsPWB0CabiA004013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005013005.T; Real TsPWB0CabiA005013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006013005.T; Real TsPWB0CabiA006013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007013005.T; Real TsPWB0CabiA007013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008013005.T; Real TsPWB0CabiA008013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009013005.T; Real TsPWB0CabiA009013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010013005.T; Real TsPWB0CabiA010013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011013005.T; Real TsPWB0CabiA011013005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011013005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003014005.T; Real TsPWB0CabiA003014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004014005.T; Real TsPWB0CabiA004014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005014005.T; Real TsPWB0CabiA005014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006014005.T; Real TsPWB0CabiA006014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007014005.T; Real TsPWB0CabiA007014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008014005.T; Real TsPWB0CabiA008014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009014005.T; Real TsPWB0CabiA009014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010014005.T; Real TsPWB0CabiA010014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011014005.T; Real TsPWB0CabiA011014005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011014005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003006005.T; Real TsPWB0CabiA003006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004006005.T; Real TsPWB0CabiA004006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005006005.T; Real TsPWB0CabiA005006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006006005.T; Real TsPWB0CabiA006006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007006005.T; Real TsPWB0CabiA007006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008006005.T; Real TsPWB0CabiA008006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009006005.T; Real TsPWB0CabiA009006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010006005.T; Real TsPWB0CabiA010006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011006005.T; Real TsPWB0CabiA011006005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011006005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003007005.T; Real TsPWB0CabiA003007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004007005.T; Real TsPWB0CabiA004007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005007005.T; Real TsPWB0CabiA005007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006007005.T; Real TsPWB0CabiA006007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007007005.T; Real TsPWB0CabiA007007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008007005.T; Real TsPWB0CabiA008007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009007005.T; Real TsPWB0CabiA009007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010007005.T; Real TsPWB0CabiA010007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011007005.T; Real TsPWB0CabiA011007005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011007005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003008005.T; Real TsPWB0CabiA003008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004008005.T; Real TsPWB0CabiA004008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005008005.T; Real TsPWB0CabiA005008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006008005.T; Real TsPWB0CabiA006008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007008005.T; Real TsPWB0CabiA007008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008008005.T; Real TsPWB0CabiA008008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009008005.T; Real TsPWB0CabiA009008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010008005.T; Real TsPWB0CabiA010008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011008005.T; Real TsPWB0CabiA011008005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011008005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003009005.T; Real TsPWB0CabiA003009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004009005.T; Real TsPWB0CabiA004009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005009005.T; Real TsPWB0CabiA005009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006009005.T; Real TsPWB0CabiA006009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007009005.T; Real TsPWB0CabiA007009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008009005.T; Real TsPWB0CabiA008009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009009005.T; Real TsPWB0CabiA009009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010009005.T; Real TsPWB0CabiA010009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011009005.T; Real TsPWB0CabiA011009005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011009005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003010005.T; Real TsPWB0CabiA003010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004010005.T; Real TsPWB0CabiA004010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005010005.T; Real TsPWB0CabiA005010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006010005.T; Real TsPWB0CabiA006010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007010005.T; Real TsPWB0CabiA007010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008010005.T; Real TsPWB0CabiA008010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009010005.T; Real TsPWB0CabiA009010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010010005.T; Real TsPWB0CabiA010010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011010005.T; Real TsPWB0CabiA011010005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011010005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003003005.T; Real TsPWB0CabiA003003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004003005.T; Real TsPWB0CabiA004003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005003005.T; Real TsPWB0CabiA005003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006003005.T; Real TsPWB0CabiA006003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007003005.T; Real TsPWB0CabiA007003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008003005.T; Real TsPWB0CabiA008003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009003005.T; Real TsPWB0CabiA009003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010003005.T; Real TsPWB0CabiA010003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011003005.T; Real TsPWB0CabiA011003005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011003005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003004005.T; Real TsPWB0CabiA003004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004004005.T; Real TsPWB0CabiA004004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005004005.T; Real TsPWB0CabiA005004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006004005.T; Real TsPWB0CabiA006004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007004005.T; Real TsPWB0CabiA007004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008004005.T; Real TsPWB0CabiA008004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009004005.T; Real TsPWB0CabiA009004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010004005.T; Real TsPWB0CabiA010004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011004005.T; Real TsPWB0CabiA011004005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011004005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA003005005.T; Real TsPWB0CabiA003005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA003005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA004005005.T; Real TsPWB0CabiA004005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA004005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA005005005.T; Real TsPWB0CabiA005005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA005005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA006005005.T; Real TsPWB0CabiA006005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA006005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA007005005.T; Real TsPWB0CabiA007005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA007005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA008005005.T; Real TsPWB0CabiA008005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA008005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA009005005.T; Real TsPWB0CabiA009005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA009005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA010005005.T; Real TsPWB0CabiA010005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA010005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsPWB0CabiA011005005.T; Real TsPWB0CabiA011005005.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsPWB0CabiA011005005.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA006004006.T; Real TsIC50CabiA006004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA006004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA007004006.T; Real TsIC50CabiA007004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA007004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA008004006.T; Real TsIC50CabiA008004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA008004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA009004006.T; Real TsIC50CabiA009004006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA009004006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA006005006.T; Real TsIC50CabiA006005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA006005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA007005006.T; Real TsIC50CabiA007005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA007005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA008005006.T; Real TsIC50CabiA008005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA008005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA009005006.T; Real TsIC50CabiA009005006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA009005006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA006006006.T; Real TsIC50CabiA006006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA006006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA007006006.T; Real TsIC50CabiA007006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA007006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA008006006.T; Real TsIC50CabiA008006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA008006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC50CabiA009006006.T; Real TsIC50CabiA009006006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC50CabiA009006006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC40CabiA008009006.T; Real TsIC40CabiA008009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC40CabiA008009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC40CabiA009009006.T; Real TsIC40CabiA009009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC40CabiA009009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC40CabiA010009006.T; Real TsIC40CabiA010009006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC40CabiA010009006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC40CabiA008010006.T; Real TsIC40CabiA008010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC40CabiA008010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC40CabiA009010006.T; Real TsIC40CabiA009010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC40CabiA009010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC40CabiA010010006.T; Real TsIC40CabiA010010006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC40CabiA010010006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC40CabiA008011006.T; Real TsIC40CabiA008011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC40CabiA008011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC40CabiA009011006.T; Real TsIC40CabiA009011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC40CabiA009011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC40CabiA010011006.T; Real TsIC40CabiA010011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC40CabiA010011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC10CabiA004011006.T; Real TsIC10CabiA004011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC10CabiA004011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC10CabiA005011006.T; Real TsIC10CabiA005011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC10CabiA005011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC10CabiA006011006.T; Real TsIC10CabiA006011006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC10CabiA006011006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC10CabiA004012006.T; Real TsIC10CabiA004012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC10CabiA004012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC10CabiA005012006.T; Real TsIC10CabiA005012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC10CabiA005012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC10CabiA006012006.T; Real TsIC10CabiA006012006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC10CabiA006012006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC10CabiA004013006.T; Real TsIC10CabiA004013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC10CabiA004013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC10CabiA005013006.T; Real TsIC10CabiA005013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC10CabiA005013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; output Real TsIC10CabiA006013006.T; Real TsIC10CabiA006013006.port.T(quantity = "ThermodynamicTemperature", unit = "K", displayUnit = "degC", min = 0.0) "Port temperature"; Real TsIC10CabiA006013006.port.Q_flow(quantity = "Power", unit = "W") "Heat flow rate (positive if flowing from outside into the component)"; equation CABI0CabiA001001001.T = CABI0CabiA001001001.port.T; CABI0CabiA001001001.der_T = der(CABI0CabiA001001001.T); CABI0CabiA001001001.C * der(CABI0CabiA001001001.T) = CABI0CabiA001001001.port.Q_flow; CABI0CabiA002001001.T = CABI0CabiA002001001.port.T; CABI0CabiA002001001.der_T = der(CABI0CabiA002001001.T); CABI0CabiA002001001.C * der(CABI0CabiA002001001.T) = CABI0CabiA002001001.port.Q_flow; CABI0CabiA003001001.T = CABI0CabiA003001001.port.T; CABI0CabiA003001001.der_T = der(CABI0CabiA003001001.T); CABI0CabiA003001001.C * der(CABI0CabiA003001001.T) = CABI0CabiA003001001.port.Q_flow; CABI0CabiA004001001.T = CABI0CabiA004001001.port.T; CABI0CabiA004001001.der_T = der(CABI0CabiA004001001.T); CABI0CabiA004001001.C * der(CABI0CabiA004001001.T) = CABI0CabiA004001001.port.Q_flow; CABI0CabiA005001001.T = CABI0CabiA005001001.port.T; CABI0CabiA005001001.der_T = der(CABI0CabiA005001001.T); CABI0CabiA005001001.C * der(CABI0CabiA005001001.T) = CABI0CabiA005001001.port.Q_flow; CABI0CabiA006001001.T = CABI0CabiA006001001.port.T; CABI0CabiA006001001.der_T = der(CABI0CabiA006001001.T); CABI0CabiA006001001.C * der(CABI0CabiA006001001.T) = CABI0CabiA006001001.port.Q_flow; CABI0CabiA007001001.T = CABI0CabiA007001001.port.T; CABI0CabiA007001001.der_T = der(CABI0CabiA007001001.T); CABI0CabiA007001001.C * der(CABI0CabiA007001001.T) = CABI0CabiA007001001.port.Q_flow; CABI0CabiA008001001.T = CABI0CabiA008001001.port.T; CABI0CabiA008001001.der_T = der(CABI0CabiA008001001.T); CABI0CabiA008001001.C * der(CABI0CabiA008001001.T) = CABI0CabiA008001001.port.Q_flow; CABI0CabiA009001001.T = CABI0CabiA009001001.port.T; CABI0CabiA009001001.der_T = der(CABI0CabiA009001001.T); CABI0CabiA009001001.C * der(CABI0CabiA009001001.T) = CABI0CabiA009001001.port.Q_flow; CABI0CabiA010001001.T = CABI0CabiA010001001.port.T; CABI0CabiA010001001.der_T = der(CABI0CabiA010001001.T); CABI0CabiA010001001.C * der(CABI0CabiA010001001.T) = CABI0CabiA010001001.port.Q_flow; CABI0CabiA011001001.T = CABI0CabiA011001001.port.T; CABI0CabiA011001001.der_T = der(CABI0CabiA011001001.T); CABI0CabiA011001001.C * der(CABI0CabiA011001001.T) = CABI0CabiA011001001.port.Q_flow; CABI0CabiA012001001.T = CABI0CabiA012001001.port.T; CABI0CabiA012001001.der_T = der(CABI0CabiA012001001.T); CABI0CabiA012001001.C * der(CABI0CabiA012001001.T) = CABI0CabiA012001001.port.Q_flow; CABI0CabiA013001001.T = CABI0CabiA013001001.port.T; CABI0CabiA013001001.der_T = der(CABI0CabiA013001001.T); CABI0CabiA013001001.C * der(CABI0CabiA013001001.T) = CABI0CabiA013001001.port.Q_flow; CABI0CabiA001002001.T = CABI0CabiA001002001.port.T; CABI0CabiA001002001.der_T = der(CABI0CabiA001002001.T); CABI0CabiA001002001.C * der(CABI0CabiA001002001.T) = CABI0CabiA001002001.port.Q_flow; CABI0CabiA002002001.T = CABI0CabiA002002001.port.T; CABI0CabiA002002001.der_T = der(CABI0CabiA002002001.T); CABI0CabiA002002001.C * der(CABI0CabiA002002001.T) = CABI0CabiA002002001.port.Q_flow; CABI0CabiA003002001.T = CABI0CabiA003002001.port.T; CABI0CabiA003002001.der_T = der(CABI0CabiA003002001.T); CABI0CabiA003002001.C * der(CABI0CabiA003002001.T) = CABI0CabiA003002001.port.Q_flow; CABI0CabiA004002001.T = CABI0CabiA004002001.port.T; CABI0CabiA004002001.der_T = der(CABI0CabiA004002001.T); CABI0CabiA004002001.C * der(CABI0CabiA004002001.T) = CABI0CabiA004002001.port.Q_flow; CABI0CabiA005002001.T = CABI0CabiA005002001.port.T; CABI0CabiA005002001.der_T = der(CABI0CabiA005002001.T); CABI0CabiA005002001.C * der(CABI0CabiA005002001.T) = CABI0CabiA005002001.port.Q_flow; CABI0CabiA006002001.T = CABI0CabiA006002001.port.T; CABI0CabiA006002001.der_T = der(CABI0CabiA006002001.T); CABI0CabiA006002001.C * der(CABI0CabiA006002001.T) = CABI0CabiA006002001.port.Q_flow; CABI0CabiA007002001.T = CABI0CabiA007002001.port.T; CABI0CabiA007002001.der_T = der(CABI0CabiA007002001.T); CABI0CabiA007002001.C * der(CABI0CabiA007002001.T) = CABI0CabiA007002001.port.Q_flow; CABI0CabiA008002001.T = CABI0CabiA008002001.port.T; CABI0CabiA008002001.der_T = der(CABI0CabiA008002001.T); CABI0CabiA008002001.C * der(CABI0CabiA008002001.T) = CABI0CabiA008002001.port.Q_flow; CABI0CabiA009002001.T = CABI0CabiA009002001.port.T; CABI0CabiA009002001.der_T = der(CABI0CabiA009002001.T); CABI0CabiA009002001.C * der(CABI0CabiA009002001.T) = CABI0CabiA009002001.port.Q_flow; CABI0CabiA010002001.T = CABI0CabiA010002001.port.T; CABI0CabiA010002001.der_T = der(CABI0CabiA010002001.T); CABI0CabiA010002001.C * der(CABI0CabiA010002001.T) = CABI0CabiA010002001.port.Q_flow; CABI0CabiA011002001.T = CABI0CabiA011002001.port.T; CABI0CabiA011002001.der_T = der(CABI0CabiA011002001.T); CABI0CabiA011002001.C * der(CABI0CabiA011002001.T) = CABI0CabiA011002001.port.Q_flow; CABI0CabiA012002001.T = CABI0CabiA012002001.port.T; CABI0CabiA012002001.der_T = der(CABI0CabiA012002001.T); CABI0CabiA012002001.C * der(CABI0CabiA012002001.T) = CABI0CabiA012002001.port.Q_flow; CABI0CabiA013002001.T = CABI0CabiA013002001.port.T; CABI0CabiA013002001.der_T = der(CABI0CabiA013002001.T); CABI0CabiA013002001.C * der(CABI0CabiA013002001.T) = CABI0CabiA013002001.port.Q_flow; CABI0CabiA001003001.T = CABI0CabiA001003001.port.T; CABI0CabiA001003001.der_T = der(CABI0CabiA001003001.T); CABI0CabiA001003001.C * der(CABI0CabiA001003001.T) = CABI0CabiA001003001.port.Q_flow; CABI0CabiA002003001.T = CABI0CabiA002003001.port.T; CABI0CabiA002003001.der_T = der(CABI0CabiA002003001.T); CABI0CabiA002003001.C * der(CABI0CabiA002003001.T) = CABI0CabiA002003001.port.Q_flow; CABI0CabiA003003001.T = CABI0CabiA003003001.port.T; CABI0CabiA003003001.der_T = der(CABI0CabiA003003001.T); CABI0CabiA003003001.C * der(CABI0CabiA003003001.T) = CABI0CabiA003003001.port.Q_flow; CABI0CabiA004003001.T = CABI0CabiA004003001.port.T; CABI0CabiA004003001.der_T = der(CABI0CabiA004003001.T); CABI0CabiA004003001.C * der(CABI0CabiA004003001.T) = CABI0CabiA004003001.port.Q_flow; CABI0CabiA005003001.T = CABI0CabiA005003001.port.T; CABI0CabiA005003001.der_T = der(CABI0CabiA005003001.T); CABI0CabiA005003001.C * der(CABI0CabiA005003001.T) = CABI0CabiA005003001.port.Q_flow; CABI0CabiA006003001.T = CABI0CabiA006003001.port.T; CABI0CabiA006003001.der_T = der(CABI0CabiA006003001.T); CABI0CabiA006003001.C * der(CABI0CabiA006003001.T) = CABI0CabiA006003001.port.Q_flow; CABI0CabiA007003001.T = CABI0CabiA007003001.port.T; CABI0CabiA007003001.der_T = der(CABI0CabiA007003001.T); CABI0CabiA007003001.C * der(CABI0CabiA007003001.T) = CABI0CabiA007003001.port.Q_flow; CABI0CabiA008003001.T = CABI0CabiA008003001.port.T; CABI0CabiA008003001.der_T = der(CABI0CabiA008003001.T); CABI0CabiA008003001.C * der(CABI0CabiA008003001.T) = CABI0CabiA008003001.port.Q_flow; CABI0CabiA009003001.T = CABI0CabiA009003001.port.T; CABI0CabiA009003001.der_T = der(CABI0CabiA009003001.T); CABI0CabiA009003001.C * der(CABI0CabiA009003001.T) = CABI0CabiA009003001.port.Q_flow; CABI0CabiA010003001.T = CABI0CabiA010003001.port.T; CABI0CabiA010003001.der_T = der(CABI0CabiA010003001.T); CABI0CabiA010003001.C * der(CABI0CabiA010003001.T) = CABI0CabiA010003001.port.Q_flow; CABI0CabiA011003001.T = CABI0CabiA011003001.port.T; CABI0CabiA011003001.der_T = der(CABI0CabiA011003001.T); CABI0CabiA011003001.C * der(CABI0CabiA011003001.T) = CABI0CabiA011003001.port.Q_flow; CABI0CabiA012003001.T = CABI0CabiA012003001.port.T; CABI0CabiA012003001.der_T = der(CABI0CabiA012003001.T); CABI0CabiA012003001.C * der(CABI0CabiA012003001.T) = CABI0CabiA012003001.port.Q_flow; CABI0CabiA013003001.T = CABI0CabiA013003001.port.T; CABI0CabiA013003001.der_T = der(CABI0CabiA013003001.T); CABI0CabiA013003001.C * der(CABI0CabiA013003001.T) = CABI0CabiA013003001.port.Q_flow; CABI0CabiA001004001.T = CABI0CabiA001004001.port.T; CABI0CabiA001004001.der_T = der(CABI0CabiA001004001.T); CABI0CabiA001004001.C * der(CABI0CabiA001004001.T) = CABI0CabiA001004001.port.Q_flow; CABI0CabiA002004001.T = CABI0CabiA002004001.port.T; CABI0CabiA002004001.der_T = der(CABI0CabiA002004001.T); CABI0CabiA002004001.C * der(CABI0CabiA002004001.T) = CABI0CabiA002004001.port.Q_flow; CABI0CabiA003004001.T = CABI0CabiA003004001.port.T; CABI0CabiA003004001.der_T = der(CABI0CabiA003004001.T); CABI0CabiA003004001.C * der(CABI0CabiA003004001.T) = CABI0CabiA003004001.port.Q_flow; CABI0CabiA004004001.T = CABI0CabiA004004001.port.T; CABI0CabiA004004001.der_T = der(CABI0CabiA004004001.T); CABI0CabiA004004001.C * der(CABI0CabiA004004001.T) = CABI0CabiA004004001.port.Q_flow; CABI0CabiA005004001.T = CABI0CabiA005004001.port.T; CABI0CabiA005004001.der_T = der(CABI0CabiA005004001.T); CABI0CabiA005004001.C * der(CABI0CabiA005004001.T) = CABI0CabiA005004001.port.Q_flow; CABI0CabiA006004001.T = CABI0CabiA006004001.port.T; CABI0CabiA006004001.der_T = der(CABI0CabiA006004001.T); CABI0CabiA006004001.C * der(CABI0CabiA006004001.T) = CABI0CabiA006004001.port.Q_flow; CABI0CabiA007004001.T = CABI0CabiA007004001.port.T; CABI0CabiA007004001.der_T = der(CABI0CabiA007004001.T); CABI0CabiA007004001.C * der(CABI0CabiA007004001.T) = CABI0CabiA007004001.port.Q_flow; CABI0CabiA008004001.T = CABI0CabiA008004001.port.T; CABI0CabiA008004001.der_T = der(CABI0CabiA008004001.T); CABI0CabiA008004001.C * der(CABI0CabiA008004001.T) = CABI0CabiA008004001.port.Q_flow; CABI0CabiA009004001.T = CABI0CabiA009004001.port.T; CABI0CabiA009004001.der_T = der(CABI0CabiA009004001.T); CABI0CabiA009004001.C * der(CABI0CabiA009004001.T) = CABI0CabiA009004001.port.Q_flow; CABI0CabiA010004001.T = CABI0CabiA010004001.port.T; CABI0CabiA010004001.der_T = der(CABI0CabiA010004001.T); CABI0CabiA010004001.C * der(CABI0CabiA010004001.T) = CABI0CabiA010004001.port.Q_flow; CABI0CabiA011004001.T = CABI0CabiA011004001.port.T; CABI0CabiA011004001.der_T = der(CABI0CabiA011004001.T); CABI0CabiA011004001.C * der(CABI0CabiA011004001.T) = CABI0CabiA011004001.port.Q_flow; CABI0CabiA012004001.T = CABI0CabiA012004001.port.T; CABI0CabiA012004001.der_T = der(CABI0CabiA012004001.T); CABI0CabiA012004001.C * der(CABI0CabiA012004001.T) = CABI0CabiA012004001.port.Q_flow; CABI0CabiA013004001.T = CABI0CabiA013004001.port.T; CABI0CabiA013004001.der_T = der(CABI0CabiA013004001.T); CABI0CabiA013004001.C * der(CABI0CabiA013004001.T) = CABI0CabiA013004001.port.Q_flow; CABI0CabiA001005001.T = CABI0CabiA001005001.port.T; CABI0CabiA001005001.der_T = der(CABI0CabiA001005001.T); CABI0CabiA001005001.C * der(CABI0CabiA001005001.T) = CABI0CabiA001005001.port.Q_flow; CABI0CabiA002005001.T = CABI0CabiA002005001.port.T; CABI0CabiA002005001.der_T = der(CABI0CabiA002005001.T); CABI0CabiA002005001.C * der(CABI0CabiA002005001.T) = CABI0CabiA002005001.port.Q_flow; CABI0CabiA003005001.T = CABI0CabiA003005001.port.T; CABI0CabiA003005001.der_T = der(CABI0CabiA003005001.T); CABI0CabiA003005001.C * der(CABI0CabiA003005001.T) = CABI0CabiA003005001.port.Q_flow; CABI0CabiA004005001.T = CABI0CabiA004005001.port.T; CABI0CabiA004005001.der_T = der(CABI0CabiA004005001.T); CABI0CabiA004005001.C * der(CABI0CabiA004005001.T) = CABI0CabiA004005001.port.Q_flow; CABI0CabiA005005001.T = CABI0CabiA005005001.port.T; CABI0CabiA005005001.der_T = der(CABI0CabiA005005001.T); CABI0CabiA005005001.C * der(CABI0CabiA005005001.T) = CABI0CabiA005005001.port.Q_flow; CABI0CabiA006005001.T = CABI0CabiA006005001.port.T; CABI0CabiA006005001.der_T = der(CABI0CabiA006005001.T); CABI0CabiA006005001.C * der(CABI0CabiA006005001.T) = CABI0CabiA006005001.port.Q_flow; CABI0CabiA007005001.T = CABI0CabiA007005001.port.T; CABI0CabiA007005001.der_T = der(CABI0CabiA007005001.T); CABI0CabiA007005001.C * der(CABI0CabiA007005001.T) = CABI0CabiA007005001.port.Q_flow; CABI0CabiA008005001.T = CABI0CabiA008005001.port.T; CABI0CabiA008005001.der_T = der(CABI0CabiA008005001.T); CABI0CabiA008005001.C * der(CABI0CabiA008005001.T) = CABI0CabiA008005001.port.Q_flow; CABI0CabiA009005001.T = CABI0CabiA009005001.port.T; CABI0CabiA009005001.der_T = der(CABI0CabiA009005001.T); CABI0CabiA009005001.C * der(CABI0CabiA009005001.T) = CABI0CabiA009005001.port.Q_flow; CABI0CabiA010005001.T = CABI0CabiA010005001.port.T; CABI0CabiA010005001.der_T = der(CABI0CabiA010005001.T); CABI0CabiA010005001.C * der(CABI0CabiA010005001.T) = CABI0CabiA010005001.port.Q_flow; CABI0CabiA011005001.T = CABI0CabiA011005001.port.T; CABI0CabiA011005001.der_T = der(CABI0CabiA011005001.T); CABI0CabiA011005001.C * der(CABI0CabiA011005001.T) = CABI0CabiA011005001.port.Q_flow; CABI0CabiA012005001.T = CABI0CabiA012005001.port.T; CABI0CabiA012005001.der_T = der(CABI0CabiA012005001.T); CABI0CabiA012005001.C * der(CABI0CabiA012005001.T) = CABI0CabiA012005001.port.Q_flow; CABI0CabiA013005001.T = CABI0CabiA013005001.port.T; CABI0CabiA013005001.der_T = der(CABI0CabiA013005001.T); CABI0CabiA013005001.C * der(CABI0CabiA013005001.T) = CABI0CabiA013005001.port.Q_flow; CABI0CabiA001006001.T = CABI0CabiA001006001.port.T; CABI0CabiA001006001.der_T = der(CABI0CabiA001006001.T); CABI0CabiA001006001.C * der(CABI0CabiA001006001.T) = CABI0CabiA001006001.port.Q_flow; CABI0CabiA002006001.T = CABI0CabiA002006001.port.T; CABI0CabiA002006001.der_T = der(CABI0CabiA002006001.T); CABI0CabiA002006001.C * der(CABI0CabiA002006001.T) = CABI0CabiA002006001.port.Q_flow; CABI0CabiA003006001.T = CABI0CabiA003006001.port.T; CABI0CabiA003006001.der_T = der(CABI0CabiA003006001.T); CABI0CabiA003006001.C * der(CABI0CabiA003006001.T) = CABI0CabiA003006001.port.Q_flow; CABI0CabiA004006001.T = CABI0CabiA004006001.port.T; CABI0CabiA004006001.der_T = der(CABI0CabiA004006001.T); CABI0CabiA004006001.C * der(CABI0CabiA004006001.T) = CABI0CabiA004006001.port.Q_flow; CABI0CabiA005006001.T = CABI0CabiA005006001.port.T; CABI0CabiA005006001.der_T = der(CABI0CabiA005006001.T); CABI0CabiA005006001.C * der(CABI0CabiA005006001.T) = CABI0CabiA005006001.port.Q_flow; CABI0CabiA006006001.T = CABI0CabiA006006001.port.T; CABI0CabiA006006001.der_T = der(CABI0CabiA006006001.T); CABI0CabiA006006001.C * der(CABI0CabiA006006001.T) = CABI0CabiA006006001.port.Q_flow; CABI0CabiA007006001.T = CABI0CabiA007006001.port.T; CABI0CabiA007006001.der_T = der(CABI0CabiA007006001.T); CABI0CabiA007006001.C * der(CABI0CabiA007006001.T) = CABI0CabiA007006001.port.Q_flow; CABI0CabiA008006001.T = CABI0CabiA008006001.port.T; CABI0CabiA008006001.der_T = der(CABI0CabiA008006001.T); CABI0CabiA008006001.C * der(CABI0CabiA008006001.T) = CABI0CabiA008006001.port.Q_flow; CABI0CabiA009006001.T = CABI0CabiA009006001.port.T; CABI0CabiA009006001.der_T = der(CABI0CabiA009006001.T); CABI0CabiA009006001.C * der(CABI0CabiA009006001.T) = CABI0CabiA009006001.port.Q_flow; CABI0CabiA010006001.T = CABI0CabiA010006001.port.T; CABI0CabiA010006001.der_T = der(CABI0CabiA010006001.T); CABI0CabiA010006001.C * der(CABI0CabiA010006001.T) = CABI0CabiA010006001.port.Q_flow; CABI0CabiA011006001.T = CABI0CabiA011006001.port.T; CABI0CabiA011006001.der_T = der(CABI0CabiA011006001.T); CABI0CabiA011006001.C * der(CABI0CabiA011006001.T) = CABI0CabiA011006001.port.Q_flow; CABI0CabiA012006001.T = CABI0CabiA012006001.port.T; CABI0CabiA012006001.der_T = der(CABI0CabiA012006001.T); CABI0CabiA012006001.C * der(CABI0CabiA012006001.T) = CABI0CabiA012006001.port.Q_flow; CABI0CabiA013006001.T = CABI0CabiA013006001.port.T; CABI0CabiA013006001.der_T = der(CABI0CabiA013006001.T); CABI0CabiA013006001.C * der(CABI0CabiA013006001.T) = CABI0CabiA013006001.port.Q_flow; CABI0CabiA001007001.T = CABI0CabiA001007001.port.T; CABI0CabiA001007001.der_T = der(CABI0CabiA001007001.T); CABI0CabiA001007001.C * der(CABI0CabiA001007001.T) = CABI0CabiA001007001.port.Q_flow; CABI0CabiA002007001.T = CABI0CabiA002007001.port.T; CABI0CabiA002007001.der_T = der(CABI0CabiA002007001.T); CABI0CabiA002007001.C * der(CABI0CabiA002007001.T) = CABI0CabiA002007001.port.Q_flow; CABI0CabiA003007001.T = CABI0CabiA003007001.port.T; CABI0CabiA003007001.der_T = der(CABI0CabiA003007001.T); CABI0CabiA003007001.C * der(CABI0CabiA003007001.T) = CABI0CabiA003007001.port.Q_flow; CABI0CabiA004007001.T = CABI0CabiA004007001.port.T; CABI0CabiA004007001.der_T = der(CABI0CabiA004007001.T); CABI0CabiA004007001.C * der(CABI0CabiA004007001.T) = CABI0CabiA004007001.port.Q_flow; CABI0CabiA005007001.T = CABI0CabiA005007001.port.T; CABI0CabiA005007001.der_T = der(CABI0CabiA005007001.T); CABI0CabiA005007001.C * der(CABI0CabiA005007001.T) = CABI0CabiA005007001.port.Q_flow; CABI0CabiA006007001.T = CABI0CabiA006007001.port.T; CABI0CabiA006007001.der_T = der(CABI0CabiA006007001.T); CABI0CabiA006007001.C * der(CABI0CabiA006007001.T) = CABI0CabiA006007001.port.Q_flow; CABI0CabiA007007001.T = CABI0CabiA007007001.port.T; CABI0CabiA007007001.der_T = der(CABI0CabiA007007001.T); CABI0CabiA007007001.C * der(CABI0CabiA007007001.T) = CABI0CabiA007007001.port.Q_flow; CABI0CabiA008007001.T = CABI0CabiA008007001.port.T; CABI0CabiA008007001.der_T = der(CABI0CabiA008007001.T); CABI0CabiA008007001.C * der(CABI0CabiA008007001.T) = CABI0CabiA008007001.port.Q_flow; CABI0CabiA009007001.T = CABI0CabiA009007001.port.T; CABI0CabiA009007001.der_T = der(CABI0CabiA009007001.T); CABI0CabiA009007001.C * der(CABI0CabiA009007001.T) = CABI0CabiA009007001.port.Q_flow; CABI0CabiA010007001.T = CABI0CabiA010007001.port.T; CABI0CabiA010007001.der_T = der(CABI0CabiA010007001.T); CABI0CabiA010007001.C * der(CABI0CabiA010007001.T) = CABI0CabiA010007001.port.Q_flow; CABI0CabiA011007001.T = CABI0CabiA011007001.port.T; CABI0CabiA011007001.der_T = der(CABI0CabiA011007001.T); CABI0CabiA011007001.C * der(CABI0CabiA011007001.T) = CABI0CabiA011007001.port.Q_flow; CABI0CabiA012007001.T = CABI0CabiA012007001.port.T; CABI0CabiA012007001.der_T = der(CABI0CabiA012007001.T); CABI0CabiA012007001.C * der(CABI0CabiA012007001.T) = CABI0CabiA012007001.port.Q_flow; CABI0CabiA013007001.T = CABI0CabiA013007001.port.T; CABI0CabiA013007001.der_T = der(CABI0CabiA013007001.T); CABI0CabiA013007001.C * der(CABI0CabiA013007001.T) = CABI0CabiA013007001.port.Q_flow; CABI0CabiA001008001.T = CABI0CabiA001008001.port.T; CABI0CabiA001008001.der_T = der(CABI0CabiA001008001.T); CABI0CabiA001008001.C * der(CABI0CabiA001008001.T) = CABI0CabiA001008001.port.Q_flow; CABI0CabiA002008001.T = CABI0CabiA002008001.port.T; CABI0CabiA002008001.der_T = der(CABI0CabiA002008001.T); CABI0CabiA002008001.C * der(CABI0CabiA002008001.T) = CABI0CabiA002008001.port.Q_flow; CABI0CabiA003008001.T = CABI0CabiA003008001.port.T; CABI0CabiA003008001.der_T = der(CABI0CabiA003008001.T); CABI0CabiA003008001.C * der(CABI0CabiA003008001.T) = CABI0CabiA003008001.port.Q_flow; CABI0CabiA004008001.T = CABI0CabiA004008001.port.T; CABI0CabiA004008001.der_T = der(CABI0CabiA004008001.T); CABI0CabiA004008001.C * der(CABI0CabiA004008001.T) = CABI0CabiA004008001.port.Q_flow; CABI0CabiA005008001.T = CABI0CabiA005008001.port.T; CABI0CabiA005008001.der_T = der(CABI0CabiA005008001.T); CABI0CabiA005008001.C * der(CABI0CabiA005008001.T) = CABI0CabiA005008001.port.Q_flow; CABI0CabiA006008001.T = CABI0CabiA006008001.port.T; CABI0CabiA006008001.der_T = der(CABI0CabiA006008001.T); CABI0CabiA006008001.C * der(CABI0CabiA006008001.T) = CABI0CabiA006008001.port.Q_flow; CABI0CabiA007008001.T = CABI0CabiA007008001.port.T; CABI0CabiA007008001.der_T = der(CABI0CabiA007008001.T); CABI0CabiA007008001.C * der(CABI0CabiA007008001.T) = CABI0CabiA007008001.port.Q_flow; CABI0CabiA008008001.T = CABI0CabiA008008001.port.T; CABI0CabiA008008001.der_T = der(CABI0CabiA008008001.T); CABI0CabiA008008001.C * der(CABI0CabiA008008001.T) = CABI0CabiA008008001.port.Q_flow; CABI0CabiA009008001.T = CABI0CabiA009008001.port.T; CABI0CabiA009008001.der_T = der(CABI0CabiA009008001.T); CABI0CabiA009008001.C * der(CABI0CabiA009008001.T) = CABI0CabiA009008001.port.Q_flow; CABI0CabiA010008001.T = CABI0CabiA010008001.port.T; CABI0CabiA010008001.der_T = der(CABI0CabiA010008001.T); CABI0CabiA010008001.C * der(CABI0CabiA010008001.T) = CABI0CabiA010008001.port.Q_flow; CABI0CabiA011008001.T = CABI0CabiA011008001.port.T; CABI0CabiA011008001.der_T = der(CABI0CabiA011008001.T); CABI0CabiA011008001.C * der(CABI0CabiA011008001.T) = CABI0CabiA011008001.port.Q_flow; CABI0CabiA012008001.T = CABI0CabiA012008001.port.T; CABI0CabiA012008001.der_T = der(CABI0CabiA012008001.T); CABI0CabiA012008001.C * der(CABI0CabiA012008001.T) = CABI0CabiA012008001.port.Q_flow; CABI0CabiA013008001.T = CABI0CabiA013008001.port.T; CABI0CabiA013008001.der_T = der(CABI0CabiA013008001.T); CABI0CabiA013008001.C * der(CABI0CabiA013008001.T) = CABI0CabiA013008001.port.Q_flow; CABI0CabiA001009001.T = CABI0CabiA001009001.port.T; CABI0CabiA001009001.der_T = der(CABI0CabiA001009001.T); CABI0CabiA001009001.C * der(CABI0CabiA001009001.T) = CABI0CabiA001009001.port.Q_flow; CABI0CabiA002009001.T = CABI0CabiA002009001.port.T; CABI0CabiA002009001.der_T = der(CABI0CabiA002009001.T); CABI0CabiA002009001.C * der(CABI0CabiA002009001.T) = CABI0CabiA002009001.port.Q_flow; CABI0CabiA003009001.T = CABI0CabiA003009001.port.T; CABI0CabiA003009001.der_T = der(CABI0CabiA003009001.T); CABI0CabiA003009001.C * der(CABI0CabiA003009001.T) = CABI0CabiA003009001.port.Q_flow; CABI0CabiA004009001.T = CABI0CabiA004009001.port.T; CABI0CabiA004009001.der_T = der(CABI0CabiA004009001.T); CABI0CabiA004009001.C * der(CABI0CabiA004009001.T) = CABI0CabiA004009001.port.Q_flow; CABI0CabiA005009001.T = CABI0CabiA005009001.port.T; CABI0CabiA005009001.der_T = der(CABI0CabiA005009001.T); CABI0CabiA005009001.C * der(CABI0CabiA005009001.T) = CABI0CabiA005009001.port.Q_flow; CABI0CabiA006009001.T = CABI0CabiA006009001.port.T; CABI0CabiA006009001.der_T = der(CABI0CabiA006009001.T); CABI0CabiA006009001.C * der(CABI0CabiA006009001.T) = CABI0CabiA006009001.port.Q_flow; CABI0CabiA007009001.T = CABI0CabiA007009001.port.T; CABI0CabiA007009001.der_T = der(CABI0CabiA007009001.T); CABI0CabiA007009001.C * der(CABI0CabiA007009001.T) = CABI0CabiA007009001.port.Q_flow; CABI0CabiA008009001.T = CABI0CabiA008009001.port.T; CABI0CabiA008009001.der_T = der(CABI0CabiA008009001.T); CABI0CabiA008009001.C * der(CABI0CabiA008009001.T) = CABI0CabiA008009001.port.Q_flow; CABI0CabiA009009001.T = CABI0CabiA009009001.port.T; CABI0CabiA009009001.der_T = der(CABI0CabiA009009001.T); CABI0CabiA009009001.C * der(CABI0CabiA009009001.T) = CABI0CabiA009009001.port.Q_flow; CABI0CabiA010009001.T = CABI0CabiA010009001.port.T; CABI0CabiA010009001.der_T = der(CABI0CabiA010009001.T); CABI0CabiA010009001.C * der(CABI0CabiA010009001.T) = CABI0CabiA010009001.port.Q_flow; CABI0CabiA011009001.T = CABI0CabiA011009001.port.T; CABI0CabiA011009001.der_T = der(CABI0CabiA011009001.T); CABI0CabiA011009001.C * der(CABI0CabiA011009001.T) = CABI0CabiA011009001.port.Q_flow; CABI0CabiA012009001.T = CABI0CabiA012009001.port.T; CABI0CabiA012009001.der_T = der(CABI0CabiA012009001.T); CABI0CabiA012009001.C * der(CABI0CabiA012009001.T) = CABI0CabiA012009001.port.Q_flow; CABI0CabiA013009001.T = CABI0CabiA013009001.port.T; CABI0CabiA013009001.der_T = der(CABI0CabiA013009001.T); CABI0CabiA013009001.C * der(CABI0CabiA013009001.T) = CABI0CabiA013009001.port.Q_flow; CABI0CabiA001010001.T = CABI0CabiA001010001.port.T; CABI0CabiA001010001.der_T = der(CABI0CabiA001010001.T); CABI0CabiA001010001.C * der(CABI0CabiA001010001.T) = CABI0CabiA001010001.port.Q_flow; CABI0CabiA002010001.T = CABI0CabiA002010001.port.T; CABI0CabiA002010001.der_T = der(CABI0CabiA002010001.T); CABI0CabiA002010001.C * der(CABI0CabiA002010001.T) = CABI0CabiA002010001.port.Q_flow; CABI0CabiA003010001.T = CABI0CabiA003010001.port.T; CABI0CabiA003010001.der_T = der(CABI0CabiA003010001.T); CABI0CabiA003010001.C * der(CABI0CabiA003010001.T) = CABI0CabiA003010001.port.Q_flow; CABI0CabiA004010001.T = CABI0CabiA004010001.port.T; CABI0CabiA004010001.der_T = der(CABI0CabiA004010001.T); CABI0CabiA004010001.C * der(CABI0CabiA004010001.T) = CABI0CabiA004010001.port.Q_flow; CABI0CabiA005010001.T = CABI0CabiA005010001.port.T; CABI0CabiA005010001.der_T = der(CABI0CabiA005010001.T); CABI0CabiA005010001.C * der(CABI0CabiA005010001.T) = CABI0CabiA005010001.port.Q_flow; CABI0CabiA006010001.T = CABI0CabiA006010001.port.T; CABI0CabiA006010001.der_T = der(CABI0CabiA006010001.T); CABI0CabiA006010001.C * der(CABI0CabiA006010001.T) = CABI0CabiA006010001.port.Q_flow; CABI0CabiA007010001.T = CABI0CabiA007010001.port.T; CABI0CabiA007010001.der_T = der(CABI0CabiA007010001.T); CABI0CabiA007010001.C * der(CABI0CabiA007010001.T) = CABI0CabiA007010001.port.Q_flow; CABI0CabiA008010001.T = CABI0CabiA008010001.port.T; CABI0CabiA008010001.der_T = der(CABI0CabiA008010001.T); CABI0CabiA008010001.C * der(CABI0CabiA008010001.T) = CABI0CabiA008010001.port.Q_flow; CABI0CabiA009010001.T = CABI0CabiA009010001.port.T; CABI0CabiA009010001.der_T = der(CABI0CabiA009010001.T); CABI0CabiA009010001.C * der(CABI0CabiA009010001.T) = CABI0CabiA009010001.port.Q_flow; CABI0CabiA010010001.T = CABI0CabiA010010001.port.T; CABI0CabiA010010001.der_T = der(CABI0CabiA010010001.T); CABI0CabiA010010001.C * der(CABI0CabiA010010001.T) = CABI0CabiA010010001.port.Q_flow; CABI0CabiA011010001.T = CABI0CabiA011010001.port.T; CABI0CabiA011010001.der_T = der(CABI0CabiA011010001.T); CABI0CabiA011010001.C * der(CABI0CabiA011010001.T) = CABI0CabiA011010001.port.Q_flow; CABI0CabiA012010001.T = CABI0CabiA012010001.port.T; CABI0CabiA012010001.der_T = der(CABI0CabiA012010001.T); CABI0CabiA012010001.C * der(CABI0CabiA012010001.T) = CABI0CabiA012010001.port.Q_flow; CABI0CabiA013010001.T = CABI0CabiA013010001.port.T; CABI0CabiA013010001.der_T = der(CABI0CabiA013010001.T); CABI0CabiA013010001.C * der(CABI0CabiA013010001.T) = CABI0CabiA013010001.port.Q_flow; CABI0CabiA001011001.T = CABI0CabiA001011001.port.T; CABI0CabiA001011001.der_T = der(CABI0CabiA001011001.T); CABI0CabiA001011001.C * der(CABI0CabiA001011001.T) = CABI0CabiA001011001.port.Q_flow; CABI0CabiA002011001.T = CABI0CabiA002011001.port.T; CABI0CabiA002011001.der_T = der(CABI0CabiA002011001.T); CABI0CabiA002011001.C * der(CABI0CabiA002011001.T) = CABI0CabiA002011001.port.Q_flow; CABI0CabiA003011001.T = CABI0CabiA003011001.port.T; CABI0CabiA003011001.der_T = der(CABI0CabiA003011001.T); CABI0CabiA003011001.C * der(CABI0CabiA003011001.T) = CABI0CabiA003011001.port.Q_flow; CABI0CabiA004011001.T = CABI0CabiA004011001.port.T; CABI0CabiA004011001.der_T = der(CABI0CabiA004011001.T); CABI0CabiA004011001.C * der(CABI0CabiA004011001.T) = CABI0CabiA004011001.port.Q_flow; CABI0CabiA005011001.T = CABI0CabiA005011001.port.T; CABI0CabiA005011001.der_T = der(CABI0CabiA005011001.T); CABI0CabiA005011001.C * der(CABI0CabiA005011001.T) = CABI0CabiA005011001.port.Q_flow; CABI0CabiA006011001.T = CABI0CabiA006011001.port.T; CABI0CabiA006011001.der_T = der(CABI0CabiA006011001.T); CABI0CabiA006011001.C * der(CABI0CabiA006011001.T) = CABI0CabiA006011001.port.Q_flow; CABI0CabiA007011001.T = CABI0CabiA007011001.port.T; CABI0CabiA007011001.der_T = der(CABI0CabiA007011001.T); CABI0CabiA007011001.C * der(CABI0CabiA007011001.T) = CABI0CabiA007011001.port.Q_flow; CABI0CabiA008011001.T = CABI0CabiA008011001.port.T; CABI0CabiA008011001.der_T = der(CABI0CabiA008011001.T); CABI0CabiA008011001.C * der(CABI0CabiA008011001.T) = CABI0CabiA008011001.port.Q_flow; CABI0CabiA009011001.T = CABI0CabiA009011001.port.T; CABI0CabiA009011001.der_T = der(CABI0CabiA009011001.T); CABI0CabiA009011001.C * der(CABI0CabiA009011001.T) = CABI0CabiA009011001.port.Q_flow; CABI0CabiA010011001.T = CABI0CabiA010011001.port.T; CABI0CabiA010011001.der_T = der(CABI0CabiA010011001.T); CABI0CabiA010011001.C * der(CABI0CabiA010011001.T) = CABI0CabiA010011001.port.Q_flow; CABI0CabiA011011001.T = CABI0CabiA011011001.port.T; CABI0CabiA011011001.der_T = der(CABI0CabiA011011001.T); CABI0CabiA011011001.C * der(CABI0CabiA011011001.T) = CABI0CabiA011011001.port.Q_flow; CABI0CabiA012011001.T = CABI0CabiA012011001.port.T; CABI0CabiA012011001.der_T = der(CABI0CabiA012011001.T); CABI0CabiA012011001.C * der(CABI0CabiA012011001.T) = CABI0CabiA012011001.port.Q_flow; CABI0CabiA013011001.T = CABI0CabiA013011001.port.T; CABI0CabiA013011001.der_T = der(CABI0CabiA013011001.T); CABI0CabiA013011001.C * der(CABI0CabiA013011001.T) = CABI0CabiA013011001.port.Q_flow; CABI0CabiA001012001.T = CABI0CabiA001012001.port.T; CABI0CabiA001012001.der_T = der(CABI0CabiA001012001.T); CABI0CabiA001012001.C * der(CABI0CabiA001012001.T) = CABI0CabiA001012001.port.Q_flow; CABI0CabiA002012001.T = CABI0CabiA002012001.port.T; CABI0CabiA002012001.der_T = der(CABI0CabiA002012001.T); CABI0CabiA002012001.C * der(CABI0CabiA002012001.T) = CABI0CabiA002012001.port.Q_flow; CABI0CabiA003012001.T = CABI0CabiA003012001.port.T; CABI0CabiA003012001.der_T = der(CABI0CabiA003012001.T); CABI0CabiA003012001.C * der(CABI0CabiA003012001.T) = CABI0CabiA003012001.port.Q_flow; CABI0CabiA004012001.T = CABI0CabiA004012001.port.T; CABI0CabiA004012001.der_T = der(CABI0CabiA004012001.T); CABI0CabiA004012001.C * der(CABI0CabiA004012001.T) = CABI0CabiA004012001.port.Q_flow; CABI0CabiA005012001.T = CABI0CabiA005012001.port.T; CABI0CabiA005012001.der_T = der(CABI0CabiA005012001.T); CABI0CabiA005012001.C * der(CABI0CabiA005012001.T) = CABI0CabiA005012001.port.Q_flow; CABI0CabiA006012001.T = CABI0CabiA006012001.port.T; CABI0CabiA006012001.der_T = der(CABI0CabiA006012001.T); CABI0CabiA006012001.C * der(CABI0CabiA006012001.T) = CABI0CabiA006012001.port.Q_flow; CABI0CabiA007012001.T = CABI0CabiA007012001.port.T; CABI0CabiA007012001.der_T = der(CABI0CabiA007012001.T); CABI0CabiA007012001.C * der(CABI0CabiA007012001.T) = CABI0CabiA007012001.port.Q_flow; CABI0CabiA008012001.T = CABI0CabiA008012001.port.T; CABI0CabiA008012001.der_T = der(CABI0CabiA008012001.T); CABI0CabiA008012001.C * der(CABI0CabiA008012001.T) = CABI0CabiA008012001.port.Q_flow; CABI0CabiA009012001.T = CABI0CabiA009012001.port.T; CABI0CabiA009012001.der_T = der(CABI0CabiA009012001.T); CABI0CabiA009012001.C * der(CABI0CabiA009012001.T) = CABI0CabiA009012001.port.Q_flow; CABI0CabiA010012001.T = CABI0CabiA010012001.port.T; CABI0CabiA010012001.der_T = der(CABI0CabiA010012001.T); CABI0CabiA010012001.C * der(CABI0CabiA010012001.T) = CABI0CabiA010012001.port.Q_flow; CABI0CabiA011012001.T = CABI0CabiA011012001.port.T; CABI0CabiA011012001.der_T = der(CABI0CabiA011012001.T); CABI0CabiA011012001.C * der(CABI0CabiA011012001.T) = CABI0CabiA011012001.port.Q_flow; CABI0CabiA012012001.T = CABI0CabiA012012001.port.T; CABI0CabiA012012001.der_T = der(CABI0CabiA012012001.T); CABI0CabiA012012001.C * der(CABI0CabiA012012001.T) = CABI0CabiA012012001.port.Q_flow; CABI0CabiA013012001.T = CABI0CabiA013012001.port.T; CABI0CabiA013012001.der_T = der(CABI0CabiA013012001.T); CABI0CabiA013012001.C * der(CABI0CabiA013012001.T) = CABI0CabiA013012001.port.Q_flow; CABI0CabiA001013001.T = CABI0CabiA001013001.port.T; CABI0CabiA001013001.der_T = der(CABI0CabiA001013001.T); CABI0CabiA001013001.C * der(CABI0CabiA001013001.T) = CABI0CabiA001013001.port.Q_flow; CABI0CabiA002013001.T = CABI0CabiA002013001.port.T; CABI0CabiA002013001.der_T = der(CABI0CabiA002013001.T); CABI0CabiA002013001.C * der(CABI0CabiA002013001.T) = CABI0CabiA002013001.port.Q_flow; CABI0CabiA003013001.T = CABI0CabiA003013001.port.T; CABI0CabiA003013001.der_T = der(CABI0CabiA003013001.T); CABI0CabiA003013001.C * der(CABI0CabiA003013001.T) = CABI0CabiA003013001.port.Q_flow; CABI0CabiA004013001.T = CABI0CabiA004013001.port.T; CABI0CabiA004013001.der_T = der(CABI0CabiA004013001.T); CABI0CabiA004013001.C * der(CABI0CabiA004013001.T) = CABI0CabiA004013001.port.Q_flow; CABI0CabiA005013001.T = CABI0CabiA005013001.port.T; CABI0CabiA005013001.der_T = der(CABI0CabiA005013001.T); CABI0CabiA005013001.C * der(CABI0CabiA005013001.T) = CABI0CabiA005013001.port.Q_flow; CABI0CabiA006013001.T = CABI0CabiA006013001.port.T; CABI0CabiA006013001.der_T = der(CABI0CabiA006013001.T); CABI0CabiA006013001.C * der(CABI0CabiA006013001.T) = CABI0CabiA006013001.port.Q_flow; CABI0CabiA007013001.T = CABI0CabiA007013001.port.T; CABI0CabiA007013001.der_T = der(CABI0CabiA007013001.T); CABI0CabiA007013001.C * der(CABI0CabiA007013001.T) = CABI0CabiA007013001.port.Q_flow; CABI0CabiA008013001.T = CABI0CabiA008013001.port.T; CABI0CabiA008013001.der_T = der(CABI0CabiA008013001.T); CABI0CabiA008013001.C * der(CABI0CabiA008013001.T) = CABI0CabiA008013001.port.Q_flow; CABI0CabiA009013001.T = CABI0CabiA009013001.port.T; CABI0CabiA009013001.der_T = der(CABI0CabiA009013001.T); CABI0CabiA009013001.C * der(CABI0CabiA009013001.T) = CABI0CabiA009013001.port.Q_flow; CABI0CabiA010013001.T = CABI0CabiA010013001.port.T; CABI0CabiA010013001.der_T = der(CABI0CabiA010013001.T); CABI0CabiA010013001.C * der(CABI0CabiA010013001.T) = CABI0CabiA010013001.port.Q_flow; CABI0CabiA011013001.T = CABI0CabiA011013001.port.T; CABI0CabiA011013001.der_T = der(CABI0CabiA011013001.T); CABI0CabiA011013001.C * der(CABI0CabiA011013001.T) = CABI0CabiA011013001.port.Q_flow; CABI0CabiA012013001.T = CABI0CabiA012013001.port.T; CABI0CabiA012013001.der_T = der(CABI0CabiA012013001.T); CABI0CabiA012013001.C * der(CABI0CabiA012013001.T) = CABI0CabiA012013001.port.Q_flow; CABI0CabiA013013001.T = CABI0CabiA013013001.port.T; CABI0CabiA013013001.der_T = der(CABI0CabiA013013001.T); CABI0CabiA013013001.C * der(CABI0CabiA013013001.T) = CABI0CabiA013013001.port.Q_flow; CABI0CabiA001014001.T = CABI0CabiA001014001.port.T; CABI0CabiA001014001.der_T = der(CABI0CabiA001014001.T); CABI0CabiA001014001.C * der(CABI0CabiA001014001.T) = CABI0CabiA001014001.port.Q_flow; CABI0CabiA002014001.T = CABI0CabiA002014001.port.T; CABI0CabiA002014001.der_T = der(CABI0CabiA002014001.T); CABI0CabiA002014001.C * der(CABI0CabiA002014001.T) = CABI0CabiA002014001.port.Q_flow; CABI0CabiA003014001.T = CABI0CabiA003014001.port.T; CABI0CabiA003014001.der_T = der(CABI0CabiA003014001.T); CABI0CabiA003014001.C * der(CABI0CabiA003014001.T) = CABI0CabiA003014001.port.Q_flow; CABI0CabiA004014001.T = CABI0CabiA004014001.port.T; CABI0CabiA004014001.der_T = der(CABI0CabiA004014001.T); CABI0CabiA004014001.C * der(CABI0CabiA004014001.T) = CABI0CabiA004014001.port.Q_flow; CABI0CabiA005014001.T = CABI0CabiA005014001.port.T; CABI0CabiA005014001.der_T = der(CABI0CabiA005014001.T); CABI0CabiA005014001.C * der(CABI0CabiA005014001.T) = CABI0CabiA005014001.port.Q_flow; CABI0CabiA006014001.T = CABI0CabiA006014001.port.T; CABI0CabiA006014001.der_T = der(CABI0CabiA006014001.T); CABI0CabiA006014001.C * der(CABI0CabiA006014001.T) = CABI0CabiA006014001.port.Q_flow; CABI0CabiA007014001.T = CABI0CabiA007014001.port.T; CABI0CabiA007014001.der_T = der(CABI0CabiA007014001.T); CABI0CabiA007014001.C * der(CABI0CabiA007014001.T) = CABI0CabiA007014001.port.Q_flow; CABI0CabiA008014001.T = CABI0CabiA008014001.port.T; CABI0CabiA008014001.der_T = der(CABI0CabiA008014001.T); CABI0CabiA008014001.C * der(CABI0CabiA008014001.T) = CABI0CabiA008014001.port.Q_flow; CABI0CabiA009014001.T = CABI0CabiA009014001.port.T; CABI0CabiA009014001.der_T = der(CABI0CabiA009014001.T); CABI0CabiA009014001.C * der(CABI0CabiA009014001.T) = CABI0CabiA009014001.port.Q_flow; CABI0CabiA010014001.T = CABI0CabiA010014001.port.T; CABI0CabiA010014001.der_T = der(CABI0CabiA010014001.T); CABI0CabiA010014001.C * der(CABI0CabiA010014001.T) = CABI0CabiA010014001.port.Q_flow; CABI0CabiA011014001.T = CABI0CabiA011014001.port.T; CABI0CabiA011014001.der_T = der(CABI0CabiA011014001.T); CABI0CabiA011014001.C * der(CABI0CabiA011014001.T) = CABI0CabiA011014001.port.Q_flow; CABI0CabiA012014001.T = CABI0CabiA012014001.port.T; CABI0CabiA012014001.der_T = der(CABI0CabiA012014001.T); CABI0CabiA012014001.C * der(CABI0CabiA012014001.T) = CABI0CabiA012014001.port.Q_flow; CABI0CabiA013014001.T = CABI0CabiA013014001.port.T; CABI0CabiA013014001.der_T = der(CABI0CabiA013014001.T); CABI0CabiA013014001.C * der(CABI0CabiA013014001.T) = CABI0CabiA013014001.port.Q_flow; CABI0CabiA001015001.T = CABI0CabiA001015001.port.T; CABI0CabiA001015001.der_T = der(CABI0CabiA001015001.T); CABI0CabiA001015001.C * der(CABI0CabiA001015001.T) = CABI0CabiA001015001.port.Q_flow; CABI0CabiA002015001.T = CABI0CabiA002015001.port.T; CABI0CabiA002015001.der_T = der(CABI0CabiA002015001.T); CABI0CabiA002015001.C * der(CABI0CabiA002015001.T) = CABI0CabiA002015001.port.Q_flow; CABI0CabiA003015001.T = CABI0CabiA003015001.port.T; CABI0CabiA003015001.der_T = der(CABI0CabiA003015001.T); CABI0CabiA003015001.C * der(CABI0CabiA003015001.T) = CABI0CabiA003015001.port.Q_flow; CABI0CabiA004015001.T = CABI0CabiA004015001.port.T; CABI0CabiA004015001.der_T = der(CABI0CabiA004015001.T); CABI0CabiA004015001.C * der(CABI0CabiA004015001.T) = CABI0CabiA004015001.port.Q_flow; CABI0CabiA005015001.T = CABI0CabiA005015001.port.T; CABI0CabiA005015001.der_T = der(CABI0CabiA005015001.T); CABI0CabiA005015001.C * der(CABI0CabiA005015001.T) = CABI0CabiA005015001.port.Q_flow; CABI0CabiA006015001.T = CABI0CabiA006015001.port.T; CABI0CabiA006015001.der_T = der(CABI0CabiA006015001.T); CABI0CabiA006015001.C * der(CABI0CabiA006015001.T) = CABI0CabiA006015001.port.Q_flow; CABI0CabiA007015001.T = CABI0CabiA007015001.port.T; CABI0CabiA007015001.der_T = der(CABI0CabiA007015001.T); CABI0CabiA007015001.C * der(CABI0CabiA007015001.T) = CABI0CabiA007015001.port.Q_flow; CABI0CabiA008015001.T = CABI0CabiA008015001.port.T; CABI0CabiA008015001.der_T = der(CABI0CabiA008015001.T); CABI0CabiA008015001.C * der(CABI0CabiA008015001.T) = CABI0CabiA008015001.port.Q_flow; CABI0CabiA009015001.T = CABI0CabiA009015001.port.T; CABI0CabiA009015001.der_T = der(CABI0CabiA009015001.T); CABI0CabiA009015001.C * der(CABI0CabiA009015001.T) = CABI0CabiA009015001.port.Q_flow; CABI0CabiA010015001.T = CABI0CabiA010015001.port.T; CABI0CabiA010015001.der_T = der(CABI0CabiA010015001.T); CABI0CabiA010015001.C * der(CABI0CabiA010015001.T) = CABI0CabiA010015001.port.Q_flow; CABI0CabiA011015001.T = CABI0CabiA011015001.port.T; CABI0CabiA011015001.der_T = der(CABI0CabiA011015001.T); CABI0CabiA011015001.C * der(CABI0CabiA011015001.T) = CABI0CabiA011015001.port.Q_flow; CABI0CabiA012015001.T = CABI0CabiA012015001.port.T; CABI0CabiA012015001.der_T = der(CABI0CabiA012015001.T); CABI0CabiA012015001.C * der(CABI0CabiA012015001.T) = CABI0CabiA012015001.port.Q_flow; CABI0CabiA013015001.T = CABI0CabiA013015001.port.T; CABI0CabiA013015001.der_T = der(CABI0CabiA013015001.T); CABI0CabiA013015001.C * der(CABI0CabiA013015001.T) = CABI0CabiA013015001.port.Q_flow; CABI0CabiA001016001.T = CABI0CabiA001016001.port.T; CABI0CabiA001016001.der_T = der(CABI0CabiA001016001.T); CABI0CabiA001016001.C * der(CABI0CabiA001016001.T) = CABI0CabiA001016001.port.Q_flow; CABI0CabiA002016001.T = CABI0CabiA002016001.port.T; CABI0CabiA002016001.der_T = der(CABI0CabiA002016001.T); CABI0CabiA002016001.C * der(CABI0CabiA002016001.T) = CABI0CabiA002016001.port.Q_flow; CABI0CabiA003016001.T = CABI0CabiA003016001.port.T; CABI0CabiA003016001.der_T = der(CABI0CabiA003016001.T); CABI0CabiA003016001.C * der(CABI0CabiA003016001.T) = CABI0CabiA003016001.port.Q_flow; CABI0CabiA004016001.T = CABI0CabiA004016001.port.T; CABI0CabiA004016001.der_T = der(CABI0CabiA004016001.T); CABI0CabiA004016001.C * der(CABI0CabiA004016001.T) = CABI0CabiA004016001.port.Q_flow; CABI0CabiA005016001.T = CABI0CabiA005016001.port.T; CABI0CabiA005016001.der_T = der(CABI0CabiA005016001.T); CABI0CabiA005016001.C * der(CABI0CabiA005016001.T) = CABI0CabiA005016001.port.Q_flow; CABI0CabiA006016001.T = CABI0CabiA006016001.port.T; CABI0CabiA006016001.der_T = der(CABI0CabiA006016001.T); CABI0CabiA006016001.C * der(CABI0CabiA006016001.T) = CABI0CabiA006016001.port.Q_flow; CABI0CabiA007016001.T = CABI0CabiA007016001.port.T; CABI0CabiA007016001.der_T = der(CABI0CabiA007016001.T); CABI0CabiA007016001.C * der(CABI0CabiA007016001.T) = CABI0CabiA007016001.port.Q_flow; CABI0CabiA008016001.T = CABI0CabiA008016001.port.T; CABI0CabiA008016001.der_T = der(CABI0CabiA008016001.T); CABI0CabiA008016001.C * der(CABI0CabiA008016001.T) = CABI0CabiA008016001.port.Q_flow; CABI0CabiA009016001.T = CABI0CabiA009016001.port.T; CABI0CabiA009016001.der_T = der(CABI0CabiA009016001.T); CABI0CabiA009016001.C * der(CABI0CabiA009016001.T) = CABI0CabiA009016001.port.Q_flow; CABI0CabiA010016001.T = CABI0CabiA010016001.port.T; CABI0CabiA010016001.der_T = der(CABI0CabiA010016001.T); CABI0CabiA010016001.C * der(CABI0CabiA010016001.T) = CABI0CabiA010016001.port.Q_flow; CABI0CabiA011016001.T = CABI0CabiA011016001.port.T; CABI0CabiA011016001.der_T = der(CABI0CabiA011016001.T); CABI0CabiA011016001.C * der(CABI0CabiA011016001.T) = CABI0CabiA011016001.port.Q_flow; CABI0CabiA012016001.T = CABI0CabiA012016001.port.T; CABI0CabiA012016001.der_T = der(CABI0CabiA012016001.T); CABI0CabiA012016001.C * der(CABI0CabiA012016001.T) = CABI0CabiA012016001.port.Q_flow; CABI0CabiA013016001.T = CABI0CabiA013016001.port.T; CABI0CabiA013016001.der_T = der(CABI0CabiA013016001.T); CABI0CabiA013016001.C * der(CABI0CabiA013016001.T) = CABI0CabiA013016001.port.Q_flow; CABI0CabiA002001002.T = CABI0CabiA002001002.port.T; CABI0CabiA002001002.der_T = der(CABI0CabiA002001002.T); CABI0CabiA002001002.C * der(CABI0CabiA002001002.T) = CABI0CabiA002001002.port.Q_flow; CABI0CabiA003001002.T = CABI0CabiA003001002.port.T; CABI0CabiA003001002.der_T = der(CABI0CabiA003001002.T); CABI0CabiA003001002.C * der(CABI0CabiA003001002.T) = CABI0CabiA003001002.port.Q_flow; CABI0CabiA004001002.T = CABI0CabiA004001002.port.T; CABI0CabiA004001002.der_T = der(CABI0CabiA004001002.T); CABI0CabiA004001002.C * der(CABI0CabiA004001002.T) = CABI0CabiA004001002.port.Q_flow; CABI0CabiA005001002.T = CABI0CabiA005001002.port.T; CABI0CabiA005001002.der_T = der(CABI0CabiA005001002.T); CABI0CabiA005001002.C * der(CABI0CabiA005001002.T) = CABI0CabiA005001002.port.Q_flow; CABI0CabiA006001002.T = CABI0CabiA006001002.port.T; CABI0CabiA006001002.der_T = der(CABI0CabiA006001002.T); CABI0CabiA006001002.C * der(CABI0CabiA006001002.T) = CABI0CabiA006001002.port.Q_flow; CABI0CabiA007001002.T = CABI0CabiA007001002.port.T; CABI0CabiA007001002.der_T = der(CABI0CabiA007001002.T); CABI0CabiA007001002.C * der(CABI0CabiA007001002.T) = CABI0CabiA007001002.port.Q_flow; CABI0CabiA008001002.T = CABI0CabiA008001002.port.T; CABI0CabiA008001002.der_T = der(CABI0CabiA008001002.T); CABI0CabiA008001002.C * der(CABI0CabiA008001002.T) = CABI0CabiA008001002.port.Q_flow; CABI0CabiA009001002.T = CABI0CabiA009001002.port.T; CABI0CabiA009001002.der_T = der(CABI0CabiA009001002.T); CABI0CabiA009001002.C * der(CABI0CabiA009001002.T) = CABI0CabiA009001002.port.Q_flow; CABI0CabiA010001002.T = CABI0CabiA010001002.port.T; CABI0CabiA010001002.der_T = der(CABI0CabiA010001002.T); CABI0CabiA010001002.C * der(CABI0CabiA010001002.T) = CABI0CabiA010001002.port.Q_flow; CABI0CabiA011001002.T = CABI0CabiA011001002.port.T; CABI0CabiA011001002.der_T = der(CABI0CabiA011001002.T); CABI0CabiA011001002.C * der(CABI0CabiA011001002.T) = CABI0CabiA011001002.port.Q_flow; CABI0CabiA012001002.T = CABI0CabiA012001002.port.T; CABI0CabiA012001002.der_T = der(CABI0CabiA012001002.T); CABI0CabiA012001002.C * der(CABI0CabiA012001002.T) = CABI0CabiA012001002.port.Q_flow; CABI0CabiA013001002.T = CABI0CabiA013001002.port.T; CABI0CabiA013001002.der_T = der(CABI0CabiA013001002.T); CABI0CabiA013001002.C * der(CABI0CabiA013001002.T) = CABI0CabiA013001002.port.Q_flow; CABI0CabiA001002002.T = CABI0CabiA001002002.port.T; CABI0CabiA001002002.der_T = der(CABI0CabiA001002002.T); CABI0CabiA001002002.C * der(CABI0CabiA001002002.T) = CABI0CabiA001002002.port.Q_flow; CABI0CabiA013002002.T = CABI0CabiA013002002.port.T; CABI0CabiA013002002.der_T = der(CABI0CabiA013002002.T); CABI0CabiA013002002.C * der(CABI0CabiA013002002.T) = CABI0CabiA013002002.port.Q_flow; CABI0CabiA001003002.T = CABI0CabiA001003002.port.T; CABI0CabiA001003002.der_T = der(CABI0CabiA001003002.T); CABI0CabiA001003002.C * der(CABI0CabiA001003002.T) = CABI0CabiA001003002.port.Q_flow; CABI0CabiA013003002.T = CABI0CabiA013003002.port.T; CABI0CabiA013003002.der_T = der(CABI0CabiA013003002.T); CABI0CabiA013003002.C * der(CABI0CabiA013003002.T) = CABI0CabiA013003002.port.Q_flow; CABI0CabiA001004002.T = CABI0CabiA001004002.port.T; CABI0CabiA001004002.der_T = der(CABI0CabiA001004002.T); CABI0CabiA001004002.C * der(CABI0CabiA001004002.T) = CABI0CabiA001004002.port.Q_flow; CABI0CabiA013004002.T = CABI0CabiA013004002.port.T; CABI0CabiA013004002.der_T = der(CABI0CabiA013004002.T); CABI0CabiA013004002.C * der(CABI0CabiA013004002.T) = CABI0CabiA013004002.port.Q_flow; CABI0CabiA001005002.T = CABI0CabiA001005002.port.T; CABI0CabiA001005002.der_T = der(CABI0CabiA001005002.T); CABI0CabiA001005002.C * der(CABI0CabiA001005002.T) = CABI0CabiA001005002.port.Q_flow; CABI0CabiA013005002.T = CABI0CabiA013005002.port.T; CABI0CabiA013005002.der_T = der(CABI0CabiA013005002.T); CABI0CabiA013005002.C * der(CABI0CabiA013005002.T) = CABI0CabiA013005002.port.Q_flow; CABI0CabiA001006002.T = CABI0CabiA001006002.port.T; CABI0CabiA001006002.der_T = der(CABI0CabiA001006002.T); CABI0CabiA001006002.C * der(CABI0CabiA001006002.T) = CABI0CabiA001006002.port.Q_flow; CABI0CabiA013006002.T = CABI0CabiA013006002.port.T; CABI0CabiA013006002.der_T = der(CABI0CabiA013006002.T); CABI0CabiA013006002.C * der(CABI0CabiA013006002.T) = CABI0CabiA013006002.port.Q_flow; CABI0CabiA001007002.T = CABI0CabiA001007002.port.T; CABI0CabiA001007002.der_T = der(CABI0CabiA001007002.T); CABI0CabiA001007002.C * der(CABI0CabiA001007002.T) = CABI0CabiA001007002.port.Q_flow; CABI0CabiA013007002.T = CABI0CabiA013007002.port.T; CABI0CabiA013007002.der_T = der(CABI0CabiA013007002.T); CABI0CabiA013007002.C * der(CABI0CabiA013007002.T) = CABI0CabiA013007002.port.Q_flow; CABI0CabiA001008002.T = CABI0CabiA001008002.port.T; CABI0CabiA001008002.der_T = der(CABI0CabiA001008002.T); CABI0CabiA001008002.C * der(CABI0CabiA001008002.T) = CABI0CabiA001008002.port.Q_flow; CABI0CabiA013008002.T = CABI0CabiA013008002.port.T; CABI0CabiA013008002.der_T = der(CABI0CabiA013008002.T); CABI0CabiA013008002.C * der(CABI0CabiA013008002.T) = CABI0CabiA013008002.port.Q_flow; CABI0CabiA001009002.T = CABI0CabiA001009002.port.T; CABI0CabiA001009002.der_T = der(CABI0CabiA001009002.T); CABI0CabiA001009002.C * der(CABI0CabiA001009002.T) = CABI0CabiA001009002.port.Q_flow; CABI0CabiA013009002.T = CABI0CabiA013009002.port.T; CABI0CabiA013009002.der_T = der(CABI0CabiA013009002.T); CABI0CabiA013009002.C * der(CABI0CabiA013009002.T) = CABI0CabiA013009002.port.Q_flow; CABI0CabiA001010002.T = CABI0CabiA001010002.port.T; CABI0CabiA001010002.der_T = der(CABI0CabiA001010002.T); CABI0CabiA001010002.C * der(CABI0CabiA001010002.T) = CABI0CabiA001010002.port.Q_flow; CABI0CabiA013010002.T = CABI0CabiA013010002.port.T; CABI0CabiA013010002.der_T = der(CABI0CabiA013010002.T); CABI0CabiA013010002.C * der(CABI0CabiA013010002.T) = CABI0CabiA013010002.port.Q_flow; CABI0CabiA001011002.T = CABI0CabiA001011002.port.T; CABI0CabiA001011002.der_T = der(CABI0CabiA001011002.T); CABI0CabiA001011002.C * der(CABI0CabiA001011002.T) = CABI0CabiA001011002.port.Q_flow; CABI0CabiA013011002.T = CABI0CabiA013011002.port.T; CABI0CabiA013011002.der_T = der(CABI0CabiA013011002.T); CABI0CabiA013011002.C * der(CABI0CabiA013011002.T) = CABI0CabiA013011002.port.Q_flow; CABI0CabiA001012002.T = CABI0CabiA001012002.port.T; CABI0CabiA001012002.der_T = der(CABI0CabiA001012002.T); CABI0CabiA001012002.C * der(CABI0CabiA001012002.T) = CABI0CabiA001012002.port.Q_flow; CABI0CabiA013012002.T = CABI0CabiA013012002.port.T; CABI0CabiA013012002.der_T = der(CABI0CabiA013012002.T); CABI0CabiA013012002.C * der(CABI0CabiA013012002.T) = CABI0CabiA013012002.port.Q_flow; CABI0CabiA001013002.T = CABI0CabiA001013002.port.T; CABI0CabiA001013002.der_T = der(CABI0CabiA001013002.T); CABI0CabiA001013002.C * der(CABI0CabiA001013002.T) = CABI0CabiA001013002.port.Q_flow; CABI0CabiA013013002.T = CABI0CabiA013013002.port.T; CABI0CabiA013013002.der_T = der(CABI0CabiA013013002.T); CABI0CabiA013013002.C * der(CABI0CabiA013013002.T) = CABI0CabiA013013002.port.Q_flow; CABI0CabiA001014002.T = CABI0CabiA001014002.port.T; CABI0CabiA001014002.der_T = der(CABI0CabiA001014002.T); CABI0CabiA001014002.C * der(CABI0CabiA001014002.T) = CABI0CabiA001014002.port.Q_flow; CABI0CabiA013014002.T = CABI0CabiA013014002.port.T; CABI0CabiA013014002.der_T = der(CABI0CabiA013014002.T); CABI0CabiA013014002.C * der(CABI0CabiA013014002.T) = CABI0CabiA013014002.port.Q_flow; CABI0CabiA001015002.T = CABI0CabiA001015002.port.T; CABI0CabiA001015002.der_T = der(CABI0CabiA001015002.T); CABI0CabiA001015002.C * der(CABI0CabiA001015002.T) = CABI0CabiA001015002.port.Q_flow; CABI0CabiA013015002.T = CABI0CabiA013015002.port.T; CABI0CabiA013015002.der_T = der(CABI0CabiA013015002.T); CABI0CabiA013015002.C * der(CABI0CabiA013015002.T) = CABI0CabiA013015002.port.Q_flow; CABI0CabiA001016002.T = CABI0CabiA001016002.port.T; CABI0CabiA001016002.der_T = der(CABI0CabiA001016002.T); CABI0CabiA001016002.C * der(CABI0CabiA001016002.T) = CABI0CabiA001016002.port.Q_flow; CABI0CabiA002016002.T = CABI0CabiA002016002.port.T; CABI0CabiA002016002.der_T = der(CABI0CabiA002016002.T); CABI0CabiA002016002.C * der(CABI0CabiA002016002.T) = CABI0CabiA002016002.port.Q_flow; CABI0CabiA003016002.T = CABI0CabiA003016002.port.T; CABI0CabiA003016002.der_T = der(CABI0CabiA003016002.T); CABI0CabiA003016002.C * der(CABI0CabiA003016002.T) = CABI0CabiA003016002.port.Q_flow; CABI0CabiA004016002.T = CABI0CabiA004016002.port.T; CABI0CabiA004016002.der_T = der(CABI0CabiA004016002.T); CABI0CabiA004016002.C * der(CABI0CabiA004016002.T) = CABI0CabiA004016002.port.Q_flow; CABI0CabiA005016002.T = CABI0CabiA005016002.port.T; CABI0CabiA005016002.der_T = der(CABI0CabiA005016002.T); CABI0CabiA005016002.C * der(CABI0CabiA005016002.T) = CABI0CabiA005016002.port.Q_flow; CABI0CabiA006016002.T = CABI0CabiA006016002.port.T; CABI0CabiA006016002.der_T = der(CABI0CabiA006016002.T); CABI0CabiA006016002.C * der(CABI0CabiA006016002.T) = CABI0CabiA006016002.port.Q_flow; CABI0CabiA007016002.T = CABI0CabiA007016002.port.T; CABI0CabiA007016002.der_T = der(CABI0CabiA007016002.T); CABI0CabiA007016002.C * der(CABI0CabiA007016002.T) = CABI0CabiA007016002.port.Q_flow; CABI0CabiA008016002.T = CABI0CabiA008016002.port.T; CABI0CabiA008016002.der_T = der(CABI0CabiA008016002.T); CABI0CabiA008016002.C * der(CABI0CabiA008016002.T) = CABI0CabiA008016002.port.Q_flow; CABI0CabiA009016002.T = CABI0CabiA009016002.port.T; CABI0CabiA009016002.der_T = der(CABI0CabiA009016002.T); CABI0CabiA009016002.C * der(CABI0CabiA009016002.T) = CABI0CabiA009016002.port.Q_flow; CABI0CabiA010016002.T = CABI0CabiA010016002.port.T; CABI0CabiA010016002.der_T = der(CABI0CabiA010016002.T); CABI0CabiA010016002.C * der(CABI0CabiA010016002.T) = CABI0CabiA010016002.port.Q_flow; CABI0CabiA011016002.T = CABI0CabiA011016002.port.T; CABI0CabiA011016002.der_T = der(CABI0CabiA011016002.T); CABI0CabiA011016002.C * der(CABI0CabiA011016002.T) = CABI0CabiA011016002.port.Q_flow; CABI0CabiA012016002.T = CABI0CabiA012016002.port.T; CABI0CabiA012016002.der_T = der(CABI0CabiA012016002.T); CABI0CabiA012016002.C * der(CABI0CabiA012016002.T) = CABI0CabiA012016002.port.Q_flow; CABI0CabiA013016002.T = CABI0CabiA013016002.port.T; CABI0CabiA013016002.der_T = der(CABI0CabiA013016002.T); CABI0CabiA013016002.C * der(CABI0CabiA013016002.T) = CABI0CabiA013016002.port.Q_flow; CABI0CabiA001001005.T = CABI0CabiA001001005.port.T; CABI0CabiA001001005.der_T = der(CABI0CabiA001001005.T); CABI0CabiA001001005.C * der(CABI0CabiA001001005.T) = CABI0CabiA001001005.port.Q_flow; CABI0CabiA002001005.T = CABI0CabiA002001005.port.T; CABI0CabiA002001005.der_T = der(CABI0CabiA002001005.T); CABI0CabiA002001005.C * der(CABI0CabiA002001005.T) = CABI0CabiA002001005.port.Q_flow; CABI0CabiA003001005.T = CABI0CabiA003001005.port.T; CABI0CabiA003001005.der_T = der(CABI0CabiA003001005.T); CABI0CabiA003001005.C * der(CABI0CabiA003001005.T) = CABI0CabiA003001005.port.Q_flow; CABI0CabiA004001005.T = CABI0CabiA004001005.port.T; CABI0CabiA004001005.der_T = der(CABI0CabiA004001005.T); CABI0CabiA004001005.C * der(CABI0CabiA004001005.T) = CABI0CabiA004001005.port.Q_flow; CABI0CabiA005001005.T = CABI0CabiA005001005.port.T; CABI0CabiA005001005.der_T = der(CABI0CabiA005001005.T); CABI0CabiA005001005.C * der(CABI0CabiA005001005.T) = CABI0CabiA005001005.port.Q_flow; CABI0CabiA006001005.T = CABI0CabiA006001005.port.T; CABI0CabiA006001005.der_T = der(CABI0CabiA006001005.T); CABI0CabiA006001005.C * der(CABI0CabiA006001005.T) = CABI0CabiA006001005.port.Q_flow; CABI0CabiA007001005.T = CABI0CabiA007001005.port.T; CABI0CabiA007001005.der_T = der(CABI0CabiA007001005.T); CABI0CabiA007001005.C * der(CABI0CabiA007001005.T) = CABI0CabiA007001005.port.Q_flow; CABI0CabiA008001005.T = CABI0CabiA008001005.port.T; CABI0CabiA008001005.der_T = der(CABI0CabiA008001005.T); CABI0CabiA008001005.C * der(CABI0CabiA008001005.T) = CABI0CabiA008001005.port.Q_flow; CABI0CabiA009001005.T = CABI0CabiA009001005.port.T; CABI0CabiA009001005.der_T = der(CABI0CabiA009001005.T); CABI0CabiA009001005.C * der(CABI0CabiA009001005.T) = CABI0CabiA009001005.port.Q_flow; CABI0CabiA010001005.T = CABI0CabiA010001005.port.T; CABI0CabiA010001005.der_T = der(CABI0CabiA010001005.T); CABI0CabiA010001005.C * der(CABI0CabiA010001005.T) = CABI0CabiA010001005.port.Q_flow; CABI0CabiA011001005.T = CABI0CabiA011001005.port.T; CABI0CabiA011001005.der_T = der(CABI0CabiA011001005.T); CABI0CabiA011001005.C * der(CABI0CabiA011001005.T) = CABI0CabiA011001005.port.Q_flow; CABI0CabiA012001005.T = CABI0CabiA012001005.port.T; CABI0CabiA012001005.der_T = der(CABI0CabiA012001005.T); CABI0CabiA012001005.C * der(CABI0CabiA012001005.T) = CABI0CabiA012001005.port.Q_flow; CABI0CabiA013001005.T = CABI0CabiA013001005.port.T; CABI0CabiA013001005.der_T = der(CABI0CabiA013001005.T); CABI0CabiA013001005.C * der(CABI0CabiA013001005.T) = CABI0CabiA013001005.port.Q_flow; CABI0CabiA001002005.T = CABI0CabiA001002005.port.T; CABI0CabiA001002005.der_T = der(CABI0CabiA001002005.T); CABI0CabiA001002005.C * der(CABI0CabiA001002005.T) = CABI0CabiA001002005.port.Q_flow; CABI0CabiA013002005.T = CABI0CabiA013002005.port.T; CABI0CabiA013002005.der_T = der(CABI0CabiA013002005.T); CABI0CabiA013002005.C * der(CABI0CabiA013002005.T) = CABI0CabiA013002005.port.Q_flow; CABI0CabiA001003005.T = CABI0CabiA001003005.port.T; CABI0CabiA001003005.der_T = der(CABI0CabiA001003005.T); CABI0CabiA001003005.C * der(CABI0CabiA001003005.T) = CABI0CabiA001003005.port.Q_flow; CABI0CabiA013003005.T = CABI0CabiA013003005.port.T; CABI0CabiA013003005.der_T = der(CABI0CabiA013003005.T); CABI0CabiA013003005.C * der(CABI0CabiA013003005.T) = CABI0CabiA013003005.port.Q_flow; CABI0CabiA001004005.T = CABI0CabiA001004005.port.T; CABI0CabiA001004005.der_T = der(CABI0CabiA001004005.T); CABI0CabiA001004005.C * der(CABI0CabiA001004005.T) = CABI0CabiA001004005.port.Q_flow; CABI0CabiA013004005.T = CABI0CabiA013004005.port.T; CABI0CabiA013004005.der_T = der(CABI0CabiA013004005.T); CABI0CabiA013004005.C * der(CABI0CabiA013004005.T) = CABI0CabiA013004005.port.Q_flow; CABI0CabiA001005005.T = CABI0CabiA001005005.port.T; CABI0CabiA001005005.der_T = der(CABI0CabiA001005005.T); CABI0CabiA001005005.C * der(CABI0CabiA001005005.T) = CABI0CabiA001005005.port.Q_flow; CABI0CabiA013005005.T = CABI0CabiA013005005.port.T; CABI0CabiA013005005.der_T = der(CABI0CabiA013005005.T); CABI0CabiA013005005.C * der(CABI0CabiA013005005.T) = CABI0CabiA013005005.port.Q_flow; CABI0CabiA001006005.T = CABI0CabiA001006005.port.T; CABI0CabiA001006005.der_T = der(CABI0CabiA001006005.T); CABI0CabiA001006005.C * der(CABI0CabiA001006005.T) = CABI0CabiA001006005.port.Q_flow; CABI0CabiA013006005.T = CABI0CabiA013006005.port.T; CABI0CabiA013006005.der_T = der(CABI0CabiA013006005.T); CABI0CabiA013006005.C * der(CABI0CabiA013006005.T) = CABI0CabiA013006005.port.Q_flow; CABI0CabiA001007005.T = CABI0CabiA001007005.port.T; CABI0CabiA001007005.der_T = der(CABI0CabiA001007005.T); CABI0CabiA001007005.C * der(CABI0CabiA001007005.T) = CABI0CabiA001007005.port.Q_flow; CABI0CabiA013007005.T = CABI0CabiA013007005.port.T; CABI0CabiA013007005.der_T = der(CABI0CabiA013007005.T); CABI0CabiA013007005.C * der(CABI0CabiA013007005.T) = CABI0CabiA013007005.port.Q_flow; CABI0CabiA001008005.T = CABI0CabiA001008005.port.T; CABI0CabiA001008005.der_T = der(CABI0CabiA001008005.T); CABI0CabiA001008005.C * der(CABI0CabiA001008005.T) = CABI0CabiA001008005.port.Q_flow; CABI0CabiA013008005.T = CABI0CabiA013008005.port.T; CABI0CabiA013008005.der_T = der(CABI0CabiA013008005.T); CABI0CabiA013008005.C * der(CABI0CabiA013008005.T) = CABI0CabiA013008005.port.Q_flow; CABI0CabiA001009005.T = CABI0CabiA001009005.port.T; CABI0CabiA001009005.der_T = der(CABI0CabiA001009005.T); CABI0CabiA001009005.C * der(CABI0CabiA001009005.T) = CABI0CabiA001009005.port.Q_flow; CABI0CabiA013009005.T = CABI0CabiA013009005.port.T; CABI0CabiA013009005.der_T = der(CABI0CabiA013009005.T); CABI0CabiA013009005.C * der(CABI0CabiA013009005.T) = CABI0CabiA013009005.port.Q_flow; CABI0CabiA001010005.T = CABI0CabiA001010005.port.T; CABI0CabiA001010005.der_T = der(CABI0CabiA001010005.T); CABI0CabiA001010005.C * der(CABI0CabiA001010005.T) = CABI0CabiA001010005.port.Q_flow; CABI0CabiA013010005.T = CABI0CabiA013010005.port.T; CABI0CabiA013010005.der_T = der(CABI0CabiA013010005.T); CABI0CabiA013010005.C * der(CABI0CabiA013010005.T) = CABI0CabiA013010005.port.Q_flow; CABI0CabiA001011005.T = CABI0CabiA001011005.port.T; CABI0CabiA001011005.der_T = der(CABI0CabiA001011005.T); CABI0CabiA001011005.C * der(CABI0CabiA001011005.T) = CABI0CabiA001011005.port.Q_flow; CABI0CabiA013011005.T = CABI0CabiA013011005.port.T; CABI0CabiA013011005.der_T = der(CABI0CabiA013011005.T); CABI0CabiA013011005.C * der(CABI0CabiA013011005.T) = CABI0CabiA013011005.port.Q_flow; CABI0CabiA001012005.T = CABI0CabiA001012005.port.T; CABI0CabiA001012005.der_T = der(CABI0CabiA001012005.T); CABI0CabiA001012005.C * der(CABI0CabiA001012005.T) = CABI0CabiA001012005.port.Q_flow; CABI0CabiA013012005.T = CABI0CabiA013012005.port.T; CABI0CabiA013012005.der_T = der(CABI0CabiA013012005.T); CABI0CabiA013012005.C * der(CABI0CabiA013012005.T) = CABI0CabiA013012005.port.Q_flow; CABI0CabiA001013005.T = CABI0CabiA001013005.port.T; CABI0CabiA001013005.der_T = der(CABI0CabiA001013005.T); CABI0CabiA001013005.C * der(CABI0CabiA001013005.T) = CABI0CabiA001013005.port.Q_flow; CABI0CabiA013013005.T = CABI0CabiA013013005.port.T; CABI0CabiA013013005.der_T = der(CABI0CabiA013013005.T); CABI0CabiA013013005.C * der(CABI0CabiA013013005.T) = CABI0CabiA013013005.port.Q_flow; CABI0CabiA001014005.T = CABI0CabiA001014005.port.T; CABI0CabiA001014005.der_T = der(CABI0CabiA001014005.T); CABI0CabiA001014005.C * der(CABI0CabiA001014005.T) = CABI0CabiA001014005.port.Q_flow; CABI0CabiA013014005.T = CABI0CabiA013014005.port.T; CABI0CabiA013014005.der_T = der(CABI0CabiA013014005.T); CABI0CabiA013014005.C * der(CABI0CabiA013014005.T) = CABI0CabiA013014005.port.Q_flow; CABI0CabiA001015005.T = CABI0CabiA001015005.port.T; CABI0CabiA001015005.der_T = der(CABI0CabiA001015005.T); CABI0CabiA001015005.C * der(CABI0CabiA001015005.T) = CABI0CabiA001015005.port.Q_flow; CABI0CabiA013015005.T = CABI0CabiA013015005.port.T; CABI0CabiA013015005.der_T = der(CABI0CabiA013015005.T); CABI0CabiA013015005.C * der(CABI0CabiA013015005.T) = CABI0CabiA013015005.port.Q_flow; CABI0CabiA001016005.T = CABI0CabiA001016005.port.T; CABI0CabiA001016005.der_T = der(CABI0CabiA001016005.T); CABI0CabiA001016005.C * der(CABI0CabiA001016005.T) = CABI0CabiA001016005.port.Q_flow; CABI0CabiA002016005.T = CABI0CabiA002016005.port.T; CABI0CabiA002016005.der_T = der(CABI0CabiA002016005.T); CABI0CabiA002016005.C * der(CABI0CabiA002016005.T) = CABI0CabiA002016005.port.Q_flow; CABI0CabiA003016005.T = CABI0CabiA003016005.port.T; CABI0CabiA003016005.der_T = der(CABI0CabiA003016005.T); CABI0CabiA003016005.C * der(CABI0CabiA003016005.T) = CABI0CabiA003016005.port.Q_flow; CABI0CabiA004016005.T = CABI0CabiA004016005.port.T; CABI0CabiA004016005.der_T = der(CABI0CabiA004016005.T); CABI0CabiA004016005.C * der(CABI0CabiA004016005.T) = CABI0CabiA004016005.port.Q_flow; CABI0CabiA005016005.T = CABI0CabiA005016005.port.T; CABI0CabiA005016005.der_T = der(CABI0CabiA005016005.T); CABI0CabiA005016005.C * der(CABI0CabiA005016005.T) = CABI0CabiA005016005.port.Q_flow; CABI0CabiA006016005.T = CABI0CabiA006016005.port.T; CABI0CabiA006016005.der_T = der(CABI0CabiA006016005.T); CABI0CabiA006016005.C * der(CABI0CabiA006016005.T) = CABI0CabiA006016005.port.Q_flow; CABI0CabiA007016005.T = CABI0CabiA007016005.port.T; CABI0CabiA007016005.der_T = der(CABI0CabiA007016005.T); CABI0CabiA007016005.C * der(CABI0CabiA007016005.T) = CABI0CabiA007016005.port.Q_flow; CABI0CabiA008016005.T = CABI0CabiA008016005.port.T; CABI0CabiA008016005.der_T = der(CABI0CabiA008016005.T); CABI0CabiA008016005.C * der(CABI0CabiA008016005.T) = CABI0CabiA008016005.port.Q_flow; CABI0CabiA009016005.T = CABI0CabiA009016005.port.T; CABI0CabiA009016005.der_T = der(CABI0CabiA009016005.T); CABI0CabiA009016005.C * der(CABI0CabiA009016005.T) = CABI0CabiA009016005.port.Q_flow; CABI0CabiA010016005.T = CABI0CabiA010016005.port.T; CABI0CabiA010016005.der_T = der(CABI0CabiA010016005.T); CABI0CabiA010016005.C * der(CABI0CabiA010016005.T) = CABI0CabiA010016005.port.Q_flow; CABI0CabiA011016005.T = CABI0CabiA011016005.port.T; CABI0CabiA011016005.der_T = der(CABI0CabiA011016005.T); CABI0CabiA011016005.C * der(CABI0CabiA011016005.T) = CABI0CabiA011016005.port.Q_flow; CABI0CabiA012016005.T = CABI0CabiA012016005.port.T; CABI0CabiA012016005.der_T = der(CABI0CabiA012016005.T); CABI0CabiA012016005.C * der(CABI0CabiA012016005.T) = CABI0CabiA012016005.port.Q_flow; CABI0CabiA013016005.T = CABI0CabiA013016005.port.T; CABI0CabiA013016005.der_T = der(CABI0CabiA013016005.T); CABI0CabiA013016005.C * der(CABI0CabiA013016005.T) = CABI0CabiA013016005.port.Q_flow; CABI0CabiA001001004.T = CABI0CabiA001001004.port.T; CABI0CabiA001001004.der_T = der(CABI0CabiA001001004.T); CABI0CabiA001001004.C * der(CABI0CabiA001001004.T) = CABI0CabiA001001004.port.Q_flow; CABI0CabiA002001004.T = CABI0CabiA002001004.port.T; CABI0CabiA002001004.der_T = der(CABI0CabiA002001004.T); CABI0CabiA002001004.C * der(CABI0CabiA002001004.T) = CABI0CabiA002001004.port.Q_flow; CABI0CabiA003001004.T = CABI0CabiA003001004.port.T; CABI0CabiA003001004.der_T = der(CABI0CabiA003001004.T); CABI0CabiA003001004.C * der(CABI0CabiA003001004.T) = CABI0CabiA003001004.port.Q_flow; CABI0CabiA004001004.T = CABI0CabiA004001004.port.T; CABI0CabiA004001004.der_T = der(CABI0CabiA004001004.T); CABI0CabiA004001004.C * der(CABI0CabiA004001004.T) = CABI0CabiA004001004.port.Q_flow; CABI0CabiA005001004.T = CABI0CabiA005001004.port.T; CABI0CabiA005001004.der_T = der(CABI0CabiA005001004.T); CABI0CabiA005001004.C * der(CABI0CabiA005001004.T) = CABI0CabiA005001004.port.Q_flow; CABI0CabiA006001004.T = CABI0CabiA006001004.port.T; CABI0CabiA006001004.der_T = der(CABI0CabiA006001004.T); CABI0CabiA006001004.C * der(CABI0CabiA006001004.T) = CABI0CabiA006001004.port.Q_flow; CABI0CabiA007001004.T = CABI0CabiA007001004.port.T; CABI0CabiA007001004.der_T = der(CABI0CabiA007001004.T); CABI0CabiA007001004.C * der(CABI0CabiA007001004.T) = CABI0CabiA007001004.port.Q_flow; CABI0CabiA008001004.T = CABI0CabiA008001004.port.T; CABI0CabiA008001004.der_T = der(CABI0CabiA008001004.T); CABI0CabiA008001004.C * der(CABI0CabiA008001004.T) = CABI0CabiA008001004.port.Q_flow; CABI0CabiA009001004.T = CABI0CabiA009001004.port.T; CABI0CabiA009001004.der_T = der(CABI0CabiA009001004.T); CABI0CabiA009001004.C * der(CABI0CabiA009001004.T) = CABI0CabiA009001004.port.Q_flow; CABI0CabiA010001004.T = CABI0CabiA010001004.port.T; CABI0CabiA010001004.der_T = der(CABI0CabiA010001004.T); CABI0CabiA010001004.C * der(CABI0CabiA010001004.T) = CABI0CabiA010001004.port.Q_flow; CABI0CabiA011001004.T = CABI0CabiA011001004.port.T; CABI0CabiA011001004.der_T = der(CABI0CabiA011001004.T); CABI0CabiA011001004.C * der(CABI0CabiA011001004.T) = CABI0CabiA011001004.port.Q_flow; CABI0CabiA012001004.T = CABI0CabiA012001004.port.T; CABI0CabiA012001004.der_T = der(CABI0CabiA012001004.T); CABI0CabiA012001004.C * der(CABI0CabiA012001004.T) = CABI0CabiA012001004.port.Q_flow; CABI0CabiA013001004.T = CABI0CabiA013001004.port.T; CABI0CabiA013001004.der_T = der(CABI0CabiA013001004.T); CABI0CabiA013001004.C * der(CABI0CabiA013001004.T) = CABI0CabiA013001004.port.Q_flow; CABI0CabiA001002004.T = CABI0CabiA001002004.port.T; CABI0CabiA001002004.der_T = der(CABI0CabiA001002004.T); CABI0CabiA001002004.C * der(CABI0CabiA001002004.T) = CABI0CabiA001002004.port.Q_flow; CABI0CabiA013002004.T = CABI0CabiA013002004.port.T; CABI0CabiA013002004.der_T = der(CABI0CabiA013002004.T); CABI0CabiA013002004.C * der(CABI0CabiA013002004.T) = CABI0CabiA013002004.port.Q_flow; CABI0CabiA001003004.T = CABI0CabiA001003004.port.T; CABI0CabiA001003004.der_T = der(CABI0CabiA001003004.T); CABI0CabiA001003004.C * der(CABI0CabiA001003004.T) = CABI0CabiA001003004.port.Q_flow; CABI0CabiA013003004.T = CABI0CabiA013003004.port.T; CABI0CabiA013003004.der_T = der(CABI0CabiA013003004.T); CABI0CabiA013003004.C * der(CABI0CabiA013003004.T) = CABI0CabiA013003004.port.Q_flow; CABI0CabiA001004004.T = CABI0CabiA001004004.port.T; CABI0CabiA001004004.der_T = der(CABI0CabiA001004004.T); CABI0CabiA001004004.C * der(CABI0CabiA001004004.T) = CABI0CabiA001004004.port.Q_flow; CABI0CabiA013004004.T = CABI0CabiA013004004.port.T; CABI0CabiA013004004.der_T = der(CABI0CabiA013004004.T); CABI0CabiA013004004.C * der(CABI0CabiA013004004.T) = CABI0CabiA013004004.port.Q_flow; CABI0CabiA001005004.T = CABI0CabiA001005004.port.T; CABI0CabiA001005004.der_T = der(CABI0CabiA001005004.T); CABI0CabiA001005004.C * der(CABI0CabiA001005004.T) = CABI0CabiA001005004.port.Q_flow; CABI0CabiA013005004.T = CABI0CabiA013005004.port.T; CABI0CabiA013005004.der_T = der(CABI0CabiA013005004.T); CABI0CabiA013005004.C * der(CABI0CabiA013005004.T) = CABI0CabiA013005004.port.Q_flow; CABI0CabiA001006004.T = CABI0CabiA001006004.port.T; CABI0CabiA001006004.der_T = der(CABI0CabiA001006004.T); CABI0CabiA001006004.C * der(CABI0CabiA001006004.T) = CABI0CabiA001006004.port.Q_flow; CABI0CabiA013006004.T = CABI0CabiA013006004.port.T; CABI0CabiA013006004.der_T = der(CABI0CabiA013006004.T); CABI0CabiA013006004.C * der(CABI0CabiA013006004.T) = CABI0CabiA013006004.port.Q_flow; CABI0CabiA001007004.T = CABI0CabiA001007004.port.T; CABI0CabiA001007004.der_T = der(CABI0CabiA001007004.T); CABI0CabiA001007004.C * der(CABI0CabiA001007004.T) = CABI0CabiA001007004.port.Q_flow; CABI0CabiA013007004.T = CABI0CabiA013007004.port.T; CABI0CabiA013007004.der_T = der(CABI0CabiA013007004.T); CABI0CabiA013007004.C * der(CABI0CabiA013007004.T) = CABI0CabiA013007004.port.Q_flow; CABI0CabiA001008004.T = CABI0CabiA001008004.port.T; CABI0CabiA001008004.der_T = der(CABI0CabiA001008004.T); CABI0CabiA001008004.C * der(CABI0CabiA001008004.T) = CABI0CabiA001008004.port.Q_flow; CABI0CabiA013008004.T = CABI0CabiA013008004.port.T; CABI0CabiA013008004.der_T = der(CABI0CabiA013008004.T); CABI0CabiA013008004.C * der(CABI0CabiA013008004.T) = CABI0CabiA013008004.port.Q_flow; CABI0CabiA001009004.T = CABI0CabiA001009004.port.T; CABI0CabiA001009004.der_T = der(CABI0CabiA001009004.T); CABI0CabiA001009004.C * der(CABI0CabiA001009004.T) = CABI0CabiA001009004.port.Q_flow; CABI0CabiA013009004.T = CABI0CabiA013009004.port.T; CABI0CabiA013009004.der_T = der(CABI0CabiA013009004.T); CABI0CabiA013009004.C * der(CABI0CabiA013009004.T) = CABI0CabiA013009004.port.Q_flow; CABI0CabiA001010004.T = CABI0CabiA001010004.port.T; CABI0CabiA001010004.der_T = der(CABI0CabiA001010004.T); CABI0CabiA001010004.C * der(CABI0CabiA001010004.T) = CABI0CabiA001010004.port.Q_flow; CABI0CabiA013010004.T = CABI0CabiA013010004.port.T; CABI0CabiA013010004.der_T = der(CABI0CabiA013010004.T); CABI0CabiA013010004.C * der(CABI0CabiA013010004.T) = CABI0CabiA013010004.port.Q_flow; CABI0CabiA001011004.T = CABI0CabiA001011004.port.T; CABI0CabiA001011004.der_T = der(CABI0CabiA001011004.T); CABI0CabiA001011004.C * der(CABI0CabiA001011004.T) = CABI0CabiA001011004.port.Q_flow; CABI0CabiA013011004.T = CABI0CabiA013011004.port.T; CABI0CabiA013011004.der_T = der(CABI0CabiA013011004.T); CABI0CabiA013011004.C * der(CABI0CabiA013011004.T) = CABI0CabiA013011004.port.Q_flow; CABI0CabiA001012004.T = CABI0CabiA001012004.port.T; CABI0CabiA001012004.der_T = der(CABI0CabiA001012004.T); CABI0CabiA001012004.C * der(CABI0CabiA001012004.T) = CABI0CabiA001012004.port.Q_flow; CABI0CabiA013012004.T = CABI0CabiA013012004.port.T; CABI0CabiA013012004.der_T = der(CABI0CabiA013012004.T); CABI0CabiA013012004.C * der(CABI0CabiA013012004.T) = CABI0CabiA013012004.port.Q_flow; CABI0CabiA001013004.T = CABI0CabiA001013004.port.T; CABI0CabiA001013004.der_T = der(CABI0CabiA001013004.T); CABI0CabiA001013004.C * der(CABI0CabiA001013004.T) = CABI0CabiA001013004.port.Q_flow; CABI0CabiA013013004.T = CABI0CabiA013013004.port.T; CABI0CabiA013013004.der_T = der(CABI0CabiA013013004.T); CABI0CabiA013013004.C * der(CABI0CabiA013013004.T) = CABI0CabiA013013004.port.Q_flow; CABI0CabiA001014004.T = CABI0CabiA001014004.port.T; CABI0CabiA001014004.der_T = der(CABI0CabiA001014004.T); CABI0CabiA001014004.C * der(CABI0CabiA001014004.T) = CABI0CabiA001014004.port.Q_flow; CABI0CabiA013014004.T = CABI0CabiA013014004.port.T; CABI0CabiA013014004.der_T = der(CABI0CabiA013014004.T); CABI0CabiA013014004.C * der(CABI0CabiA013014004.T) = CABI0CabiA013014004.port.Q_flow; CABI0CabiA001015004.T = CABI0CabiA001015004.port.T; CABI0CabiA001015004.der_T = der(CABI0CabiA001015004.T); CABI0CabiA001015004.C * der(CABI0CabiA001015004.T) = CABI0CabiA001015004.port.Q_flow; CABI0CabiA013015004.T = CABI0CabiA013015004.port.T; CABI0CabiA013015004.der_T = der(CABI0CabiA013015004.T); CABI0CabiA013015004.C * der(CABI0CabiA013015004.T) = CABI0CabiA013015004.port.Q_flow; CABI0CabiA001016004.T = CABI0CabiA001016004.port.T; CABI0CabiA001016004.der_T = der(CABI0CabiA001016004.T); CABI0CabiA001016004.C * der(CABI0CabiA001016004.T) = CABI0CabiA001016004.port.Q_flow; CABI0CabiA002016004.T = CABI0CabiA002016004.port.T; CABI0CabiA002016004.der_T = der(CABI0CabiA002016004.T); CABI0CabiA002016004.C * der(CABI0CabiA002016004.T) = CABI0CabiA002016004.port.Q_flow; CABI0CabiA003016004.T = CABI0CabiA003016004.port.T; CABI0CabiA003016004.der_T = der(CABI0CabiA003016004.T); CABI0CabiA003016004.C * der(CABI0CabiA003016004.T) = CABI0CabiA003016004.port.Q_flow; CABI0CabiA004016004.T = CABI0CabiA004016004.port.T; CABI0CabiA004016004.der_T = der(CABI0CabiA004016004.T); CABI0CabiA004016004.C * der(CABI0CabiA004016004.T) = CABI0CabiA004016004.port.Q_flow; CABI0CabiA005016004.T = CABI0CabiA005016004.port.T; CABI0CabiA005016004.der_T = der(CABI0CabiA005016004.T); CABI0CabiA005016004.C * der(CABI0CabiA005016004.T) = CABI0CabiA005016004.port.Q_flow; CABI0CabiA006016004.T = CABI0CabiA006016004.port.T; CABI0CabiA006016004.der_T = der(CABI0CabiA006016004.T); CABI0CabiA006016004.C * der(CABI0CabiA006016004.T) = CABI0CabiA006016004.port.Q_flow; CABI0CabiA007016004.T = CABI0CabiA007016004.port.T; CABI0CabiA007016004.der_T = der(CABI0CabiA007016004.T); CABI0CabiA007016004.C * der(CABI0CabiA007016004.T) = CABI0CabiA007016004.port.Q_flow; CABI0CabiA008016004.T = CABI0CabiA008016004.port.T; CABI0CabiA008016004.der_T = der(CABI0CabiA008016004.T); CABI0CabiA008016004.C * der(CABI0CabiA008016004.T) = CABI0CabiA008016004.port.Q_flow; CABI0CabiA009016004.T = CABI0CabiA009016004.port.T; CABI0CabiA009016004.der_T = der(CABI0CabiA009016004.T); CABI0CabiA009016004.C * der(CABI0CabiA009016004.T) = CABI0CabiA009016004.port.Q_flow; CABI0CabiA010016004.T = CABI0CabiA010016004.port.T; CABI0CabiA010016004.der_T = der(CABI0CabiA010016004.T); CABI0CabiA010016004.C * der(CABI0CabiA010016004.T) = CABI0CabiA010016004.port.Q_flow; CABI0CabiA011016004.T = CABI0CabiA011016004.port.T; CABI0CabiA011016004.der_T = der(CABI0CabiA011016004.T); CABI0CabiA011016004.C * der(CABI0CabiA011016004.T) = CABI0CabiA011016004.port.Q_flow; CABI0CabiA012016004.T = CABI0CabiA012016004.port.T; CABI0CabiA012016004.der_T = der(CABI0CabiA012016004.T); CABI0CabiA012016004.C * der(CABI0CabiA012016004.T) = CABI0CabiA012016004.port.Q_flow; CABI0CabiA013016004.T = CABI0CabiA013016004.port.T; CABI0CabiA013016004.der_T = der(CABI0CabiA013016004.T); CABI0CabiA013016004.C * der(CABI0CabiA013016004.T) = CABI0CabiA013016004.port.Q_flow; CABI0CabiA001001003.T = CABI0CabiA001001003.port.T; CABI0CabiA001001003.der_T = der(CABI0CabiA001001003.T); CABI0CabiA001001003.C * der(CABI0CabiA001001003.T) = CABI0CabiA001001003.port.Q_flow; CABI0CabiA002001003.T = CABI0CabiA002001003.port.T; CABI0CabiA002001003.der_T = der(CABI0CabiA002001003.T); CABI0CabiA002001003.C * der(CABI0CabiA002001003.T) = CABI0CabiA002001003.port.Q_flow; CABI0CabiA003001003.T = CABI0CabiA003001003.port.T; CABI0CabiA003001003.der_T = der(CABI0CabiA003001003.T); CABI0CabiA003001003.C * der(CABI0CabiA003001003.T) = CABI0CabiA003001003.port.Q_flow; CABI0CabiA004001003.T = CABI0CabiA004001003.port.T; CABI0CabiA004001003.der_T = der(CABI0CabiA004001003.T); CABI0CabiA004001003.C * der(CABI0CabiA004001003.T) = CABI0CabiA004001003.port.Q_flow; CABI0CabiA005001003.T = CABI0CabiA005001003.port.T; CABI0CabiA005001003.der_T = der(CABI0CabiA005001003.T); CABI0CabiA005001003.C * der(CABI0CabiA005001003.T) = CABI0CabiA005001003.port.Q_flow; CABI0CabiA006001003.T = CABI0CabiA006001003.port.T; CABI0CabiA006001003.der_T = der(CABI0CabiA006001003.T); CABI0CabiA006001003.C * der(CABI0CabiA006001003.T) = CABI0CabiA006001003.port.Q_flow; CABI0CabiA007001003.T = CABI0CabiA007001003.port.T; CABI0CabiA007001003.der_T = der(CABI0CabiA007001003.T); CABI0CabiA007001003.C * der(CABI0CabiA007001003.T) = CABI0CabiA007001003.port.Q_flow; CABI0CabiA008001003.T = CABI0CabiA008001003.port.T; CABI0CabiA008001003.der_T = der(CABI0CabiA008001003.T); CABI0CabiA008001003.C * der(CABI0CabiA008001003.T) = CABI0CabiA008001003.port.Q_flow; CABI0CabiA009001003.T = CABI0CabiA009001003.port.T; CABI0CabiA009001003.der_T = der(CABI0CabiA009001003.T); CABI0CabiA009001003.C * der(CABI0CabiA009001003.T) = CABI0CabiA009001003.port.Q_flow; CABI0CabiA010001003.T = CABI0CabiA010001003.port.T; CABI0CabiA010001003.der_T = der(CABI0CabiA010001003.T); CABI0CabiA010001003.C * der(CABI0CabiA010001003.T) = CABI0CabiA010001003.port.Q_flow; CABI0CabiA011001003.T = CABI0CabiA011001003.port.T; CABI0CabiA011001003.der_T = der(CABI0CabiA011001003.T); CABI0CabiA011001003.C * der(CABI0CabiA011001003.T) = CABI0CabiA011001003.port.Q_flow; CABI0CabiA012001003.T = CABI0CabiA012001003.port.T; CABI0CabiA012001003.der_T = der(CABI0CabiA012001003.T); CABI0CabiA012001003.C * der(CABI0CabiA012001003.T) = CABI0CabiA012001003.port.Q_flow; CABI0CabiA013001003.T = CABI0CabiA013001003.port.T; CABI0CabiA013001003.der_T = der(CABI0CabiA013001003.T); CABI0CabiA013001003.C * der(CABI0CabiA013001003.T) = CABI0CabiA013001003.port.Q_flow; CABI0CabiA001002003.T = CABI0CabiA001002003.port.T; CABI0CabiA001002003.der_T = der(CABI0CabiA001002003.T); CABI0CabiA001002003.C * der(CABI0CabiA001002003.T) = CABI0CabiA001002003.port.Q_flow; CABI0CabiA013002003.T = CABI0CabiA013002003.port.T; CABI0CabiA013002003.der_T = der(CABI0CabiA013002003.T); CABI0CabiA013002003.C * der(CABI0CabiA013002003.T) = CABI0CabiA013002003.port.Q_flow; CABI0CabiA001003003.T = CABI0CabiA001003003.port.T; CABI0CabiA001003003.der_T = der(CABI0CabiA001003003.T); CABI0CabiA001003003.C * der(CABI0CabiA001003003.T) = CABI0CabiA001003003.port.Q_flow; CABI0CabiA013003003.T = CABI0CabiA013003003.port.T; CABI0CabiA013003003.der_T = der(CABI0CabiA013003003.T); CABI0CabiA013003003.C * der(CABI0CabiA013003003.T) = CABI0CabiA013003003.port.Q_flow; CABI0CabiA001004003.T = CABI0CabiA001004003.port.T; CABI0CabiA001004003.der_T = der(CABI0CabiA001004003.T); CABI0CabiA001004003.C * der(CABI0CabiA001004003.T) = CABI0CabiA001004003.port.Q_flow; CABI0CabiA013004003.T = CABI0CabiA013004003.port.T; CABI0CabiA013004003.der_T = der(CABI0CabiA013004003.T); CABI0CabiA013004003.C * der(CABI0CabiA013004003.T) = CABI0CabiA013004003.port.Q_flow; CABI0CabiA001005003.T = CABI0CabiA001005003.port.T; CABI0CabiA001005003.der_T = der(CABI0CabiA001005003.T); CABI0CabiA001005003.C * der(CABI0CabiA001005003.T) = CABI0CabiA001005003.port.Q_flow; CABI0CabiA013005003.T = CABI0CabiA013005003.port.T; CABI0CabiA013005003.der_T = der(CABI0CabiA013005003.T); CABI0CabiA013005003.C * der(CABI0CabiA013005003.T) = CABI0CabiA013005003.port.Q_flow; CABI0CabiA001006003.T = CABI0CabiA001006003.port.T; CABI0CabiA001006003.der_T = der(CABI0CabiA001006003.T); CABI0CabiA001006003.C * der(CABI0CabiA001006003.T) = CABI0CabiA001006003.port.Q_flow; CABI0CabiA013006003.T = CABI0CabiA013006003.port.T; CABI0CabiA013006003.der_T = der(CABI0CabiA013006003.T); CABI0CabiA013006003.C * der(CABI0CabiA013006003.T) = CABI0CabiA013006003.port.Q_flow; CABI0CabiA001007003.T = CABI0CabiA001007003.port.T; CABI0CabiA001007003.der_T = der(CABI0CabiA001007003.T); CABI0CabiA001007003.C * der(CABI0CabiA001007003.T) = CABI0CabiA001007003.port.Q_flow; CABI0CabiA013007003.T = CABI0CabiA013007003.port.T; CABI0CabiA013007003.der_T = der(CABI0CabiA013007003.T); CABI0CabiA013007003.C * der(CABI0CabiA013007003.T) = CABI0CabiA013007003.port.Q_flow; CABI0CabiA001008003.T = CABI0CabiA001008003.port.T; CABI0CabiA001008003.der_T = der(CABI0CabiA001008003.T); CABI0CabiA001008003.C * der(CABI0CabiA001008003.T) = CABI0CabiA001008003.port.Q_flow; CABI0CabiA013008003.T = CABI0CabiA013008003.port.T; CABI0CabiA013008003.der_T = der(CABI0CabiA013008003.T); CABI0CabiA013008003.C * der(CABI0CabiA013008003.T) = CABI0CabiA013008003.port.Q_flow; CABI0CabiA001009003.T = CABI0CabiA001009003.port.T; CABI0CabiA001009003.der_T = der(CABI0CabiA001009003.T); CABI0CabiA001009003.C * der(CABI0CabiA001009003.T) = CABI0CabiA001009003.port.Q_flow; CABI0CabiA013009003.T = CABI0CabiA013009003.port.T; CABI0CabiA013009003.der_T = der(CABI0CabiA013009003.T); CABI0CabiA013009003.C * der(CABI0CabiA013009003.T) = CABI0CabiA013009003.port.Q_flow; CABI0CabiA001010003.T = CABI0CabiA001010003.port.T; CABI0CabiA001010003.der_T = der(CABI0CabiA001010003.T); CABI0CabiA001010003.C * der(CABI0CabiA001010003.T) = CABI0CabiA001010003.port.Q_flow; CABI0CabiA013010003.T = CABI0CabiA013010003.port.T; CABI0CabiA013010003.der_T = der(CABI0CabiA013010003.T); CABI0CabiA013010003.C * der(CABI0CabiA013010003.T) = CABI0CabiA013010003.port.Q_flow; CABI0CabiA001011003.T = CABI0CabiA001011003.port.T; CABI0CabiA001011003.der_T = der(CABI0CabiA001011003.T); CABI0CabiA001011003.C * der(CABI0CabiA001011003.T) = CABI0CabiA001011003.port.Q_flow; CABI0CabiA013011003.T = CABI0CabiA013011003.port.T; CABI0CabiA013011003.der_T = der(CABI0CabiA013011003.T); CABI0CabiA013011003.C * der(CABI0CabiA013011003.T) = CABI0CabiA013011003.port.Q_flow; CABI0CabiA001012003.T = CABI0CabiA001012003.port.T; CABI0CabiA001012003.der_T = der(CABI0CabiA001012003.T); CABI0CabiA001012003.C * der(CABI0CabiA001012003.T) = CABI0CabiA001012003.port.Q_flow; CABI0CabiA013012003.T = CABI0CabiA013012003.port.T; CABI0CabiA013012003.der_T = der(CABI0CabiA013012003.T); CABI0CabiA013012003.C * der(CABI0CabiA013012003.T) = CABI0CabiA013012003.port.Q_flow; CABI0CabiA001013003.T = CABI0CabiA001013003.port.T; CABI0CabiA001013003.der_T = der(CABI0CabiA001013003.T); CABI0CabiA001013003.C * der(CABI0CabiA001013003.T) = CABI0CabiA001013003.port.Q_flow; CABI0CabiA013013003.T = CABI0CabiA013013003.port.T; CABI0CabiA013013003.der_T = der(CABI0CabiA013013003.T); CABI0CabiA013013003.C * der(CABI0CabiA013013003.T) = CABI0CabiA013013003.port.Q_flow; CABI0CabiA001014003.T = CABI0CabiA001014003.port.T; CABI0CabiA001014003.der_T = der(CABI0CabiA001014003.T); CABI0CabiA001014003.C * der(CABI0CabiA001014003.T) = CABI0CabiA001014003.port.Q_flow; CABI0CabiA013014003.T = CABI0CabiA013014003.port.T; CABI0CabiA013014003.der_T = der(CABI0CabiA013014003.T); CABI0CabiA013014003.C * der(CABI0CabiA013014003.T) = CABI0CabiA013014003.port.Q_flow; CABI0CabiA001015003.T = CABI0CabiA001015003.port.T; CABI0CabiA001015003.der_T = der(CABI0CabiA001015003.T); CABI0CabiA001015003.C * der(CABI0CabiA001015003.T) = CABI0CabiA001015003.port.Q_flow; CABI0CabiA013015003.T = CABI0CabiA013015003.port.T; CABI0CabiA013015003.der_T = der(CABI0CabiA013015003.T); CABI0CabiA013015003.C * der(CABI0CabiA013015003.T) = CABI0CabiA013015003.port.Q_flow; CABI0CabiA001016003.T = CABI0CabiA001016003.port.T; CABI0CabiA001016003.der_T = der(CABI0CabiA001016003.T); CABI0CabiA001016003.C * der(CABI0CabiA001016003.T) = CABI0CabiA001016003.port.Q_flow; CABI0CabiA002016003.T = CABI0CabiA002016003.port.T; CABI0CabiA002016003.der_T = der(CABI0CabiA002016003.T); CABI0CabiA002016003.C * der(CABI0CabiA002016003.T) = CABI0CabiA002016003.port.Q_flow; CABI0CabiA003016003.T = CABI0CabiA003016003.port.T; CABI0CabiA003016003.der_T = der(CABI0CabiA003016003.T); CABI0CabiA003016003.C * der(CABI0CabiA003016003.T) = CABI0CabiA003016003.port.Q_flow; CABI0CabiA004016003.T = CABI0CabiA004016003.port.T; CABI0CabiA004016003.der_T = der(CABI0CabiA004016003.T); CABI0CabiA004016003.C * der(CABI0CabiA004016003.T) = CABI0CabiA004016003.port.Q_flow; CABI0CabiA005016003.T = CABI0CabiA005016003.port.T; CABI0CabiA005016003.der_T = der(CABI0CabiA005016003.T); CABI0CabiA005016003.C * der(CABI0CabiA005016003.T) = CABI0CabiA005016003.port.Q_flow; CABI0CabiA006016003.T = CABI0CabiA006016003.port.T; CABI0CabiA006016003.der_T = der(CABI0CabiA006016003.T); CABI0CabiA006016003.C * der(CABI0CabiA006016003.T) = CABI0CabiA006016003.port.Q_flow; CABI0CabiA007016003.T = CABI0CabiA007016003.port.T; CABI0CabiA007016003.der_T = der(CABI0CabiA007016003.T); CABI0CabiA007016003.C * der(CABI0CabiA007016003.T) = CABI0CabiA007016003.port.Q_flow; CABI0CabiA008016003.T = CABI0CabiA008016003.port.T; CABI0CabiA008016003.der_T = der(CABI0CabiA008016003.T); CABI0CabiA008016003.C * der(CABI0CabiA008016003.T) = CABI0CabiA008016003.port.Q_flow; CABI0CabiA009016003.T = CABI0CabiA009016003.port.T; CABI0CabiA009016003.der_T = der(CABI0CabiA009016003.T); CABI0CabiA009016003.C * der(CABI0CabiA009016003.T) = CABI0CabiA009016003.port.Q_flow; CABI0CabiA010016003.T = CABI0CabiA010016003.port.T; CABI0CabiA010016003.der_T = der(CABI0CabiA010016003.T); CABI0CabiA010016003.C * der(CABI0CabiA010016003.T) = CABI0CabiA010016003.port.Q_flow; CABI0CabiA011016003.T = CABI0CabiA011016003.port.T; CABI0CabiA011016003.der_T = der(CABI0CabiA011016003.T); CABI0CabiA011016003.C * der(CABI0CabiA011016003.T) = CABI0CabiA011016003.port.Q_flow; CABI0CabiA012016003.T = CABI0CabiA012016003.port.T; CABI0CabiA012016003.der_T = der(CABI0CabiA012016003.T); CABI0CabiA012016003.C * der(CABI0CabiA012016003.T) = CABI0CabiA012016003.port.Q_flow; CABI0CabiA013016003.T = CABI0CabiA013016003.port.T; CABI0CabiA013016003.der_T = der(CABI0CabiA013016003.T); CABI0CabiA013016003.C * der(CABI0CabiA013016003.T) = CABI0CabiA013016003.port.Q_flow; CABI0CabiA001001002.T = CABI0CabiA001001002.port.T; CABI0CabiA001001002.der_T = der(CABI0CabiA001001002.T); CABI0CabiA001001002.C * der(CABI0CabiA001001002.T) = CABI0CabiA001001002.port.Q_flow; CABI0CabiA001001006.T = CABI0CabiA001001006.port.T; CABI0CabiA001001006.der_T = der(CABI0CabiA001001006.T); CABI0CabiA001001006.C * der(CABI0CabiA001001006.T) = CABI0CabiA001001006.port.Q_flow; CABI0CabiA002001006.T = CABI0CabiA002001006.port.T; CABI0CabiA002001006.der_T = der(CABI0CabiA002001006.T); CABI0CabiA002001006.C * der(CABI0CabiA002001006.T) = CABI0CabiA002001006.port.Q_flow; CABI0CabiA003001006.T = CABI0CabiA003001006.port.T; CABI0CabiA003001006.der_T = der(CABI0CabiA003001006.T); CABI0CabiA003001006.C * der(CABI0CabiA003001006.T) = CABI0CabiA003001006.port.Q_flow; CABI0CabiA004001006.T = CABI0CabiA004001006.port.T; CABI0CabiA004001006.der_T = der(CABI0CabiA004001006.T); CABI0CabiA004001006.C * der(CABI0CabiA004001006.T) = CABI0CabiA004001006.port.Q_flow; CABI0CabiA005001006.T = CABI0CabiA005001006.port.T; CABI0CabiA005001006.der_T = der(CABI0CabiA005001006.T); CABI0CabiA005001006.C * der(CABI0CabiA005001006.T) = CABI0CabiA005001006.port.Q_flow; CABI0CabiA006001006.T = CABI0CabiA006001006.port.T; CABI0CabiA006001006.der_T = der(CABI0CabiA006001006.T); CABI0CabiA006001006.C * der(CABI0CabiA006001006.T) = CABI0CabiA006001006.port.Q_flow; CABI0CabiA007001006.T = CABI0CabiA007001006.port.T; CABI0CabiA007001006.der_T = der(CABI0CabiA007001006.T); CABI0CabiA007001006.C * der(CABI0CabiA007001006.T) = CABI0CabiA007001006.port.Q_flow; CABI0CabiA008001006.T = CABI0CabiA008001006.port.T; CABI0CabiA008001006.der_T = der(CABI0CabiA008001006.T); CABI0CabiA008001006.C * der(CABI0CabiA008001006.T) = CABI0CabiA008001006.port.Q_flow; CABI0CabiA009001006.T = CABI0CabiA009001006.port.T; CABI0CabiA009001006.der_T = der(CABI0CabiA009001006.T); CABI0CabiA009001006.C * der(CABI0CabiA009001006.T) = CABI0CabiA009001006.port.Q_flow; CABI0CabiA010001006.T = CABI0CabiA010001006.port.T; CABI0CabiA010001006.der_T = der(CABI0CabiA010001006.T); CABI0CabiA010001006.C * der(CABI0CabiA010001006.T) = CABI0CabiA010001006.port.Q_flow; CABI0CabiA011001006.T = CABI0CabiA011001006.port.T; CABI0CabiA011001006.der_T = der(CABI0CabiA011001006.T); CABI0CabiA011001006.C * der(CABI0CabiA011001006.T) = CABI0CabiA011001006.port.Q_flow; CABI0CabiA012001006.T = CABI0CabiA012001006.port.T; CABI0CabiA012001006.der_T = der(CABI0CabiA012001006.T); CABI0CabiA012001006.C * der(CABI0CabiA012001006.T) = CABI0CabiA012001006.port.Q_flow; CABI0CabiA013001006.T = CABI0CabiA013001006.port.T; CABI0CabiA013001006.der_T = der(CABI0CabiA013001006.T); CABI0CabiA013001006.C * der(CABI0CabiA013001006.T) = CABI0CabiA013001006.port.Q_flow; CABI0CabiA001002006.T = CABI0CabiA001002006.port.T; CABI0CabiA001002006.der_T = der(CABI0CabiA001002006.T); CABI0CabiA001002006.C * der(CABI0CabiA001002006.T) = CABI0CabiA001002006.port.Q_flow; CABI0CabiA013002006.T = CABI0CabiA013002006.port.T; CABI0CabiA013002006.der_T = der(CABI0CabiA013002006.T); CABI0CabiA013002006.C * der(CABI0CabiA013002006.T) = CABI0CabiA013002006.port.Q_flow; CABI0CabiA001003006.T = CABI0CabiA001003006.port.T; CABI0CabiA001003006.der_T = der(CABI0CabiA001003006.T); CABI0CabiA001003006.C * der(CABI0CabiA001003006.T) = CABI0CabiA001003006.port.Q_flow; CABI0CabiA013003006.T = CABI0CabiA013003006.port.T; CABI0CabiA013003006.der_T = der(CABI0CabiA013003006.T); CABI0CabiA013003006.C * der(CABI0CabiA013003006.T) = CABI0CabiA013003006.port.Q_flow; CABI0CabiA001004006.T = CABI0CabiA001004006.port.T; CABI0CabiA001004006.der_T = der(CABI0CabiA001004006.T); CABI0CabiA001004006.C * der(CABI0CabiA001004006.T) = CABI0CabiA001004006.port.Q_flow; CABI0CabiA013004006.T = CABI0CabiA013004006.port.T; CABI0CabiA013004006.der_T = der(CABI0CabiA013004006.T); CABI0CabiA013004006.C * der(CABI0CabiA013004006.T) = CABI0CabiA013004006.port.Q_flow; CABI0CabiA001005006.T = CABI0CabiA001005006.port.T; CABI0CabiA001005006.der_T = der(CABI0CabiA001005006.T); CABI0CabiA001005006.C * der(CABI0CabiA001005006.T) = CABI0CabiA001005006.port.Q_flow; CABI0CabiA013005006.T = CABI0CabiA013005006.port.T; CABI0CabiA013005006.der_T = der(CABI0CabiA013005006.T); CABI0CabiA013005006.C * der(CABI0CabiA013005006.T) = CABI0CabiA013005006.port.Q_flow; CABI0CabiA001006006.T = CABI0CabiA001006006.port.T; CABI0CabiA001006006.der_T = der(CABI0CabiA001006006.T); CABI0CabiA001006006.C * der(CABI0CabiA001006006.T) = CABI0CabiA001006006.port.Q_flow; CABI0CabiA013006006.T = CABI0CabiA013006006.port.T; CABI0CabiA013006006.der_T = der(CABI0CabiA013006006.T); CABI0CabiA013006006.C * der(CABI0CabiA013006006.T) = CABI0CabiA013006006.port.Q_flow; CABI0CabiA001007006.T = CABI0CabiA001007006.port.T; CABI0CabiA001007006.der_T = der(CABI0CabiA001007006.T); CABI0CabiA001007006.C * der(CABI0CabiA001007006.T) = CABI0CabiA001007006.port.Q_flow; CABI0CabiA013007006.T = CABI0CabiA013007006.port.T; CABI0CabiA013007006.der_T = der(CABI0CabiA013007006.T); CABI0CabiA013007006.C * der(CABI0CabiA013007006.T) = CABI0CabiA013007006.port.Q_flow; CABI0CabiA001008006.T = CABI0CabiA001008006.port.T; CABI0CabiA001008006.der_T = der(CABI0CabiA001008006.T); CABI0CabiA001008006.C * der(CABI0CabiA001008006.T) = CABI0CabiA001008006.port.Q_flow; CABI0CabiA013008006.T = CABI0CabiA013008006.port.T; CABI0CabiA013008006.der_T = der(CABI0CabiA013008006.T); CABI0CabiA013008006.C * der(CABI0CabiA013008006.T) = CABI0CabiA013008006.port.Q_flow; CABI0CabiA001009006.T = CABI0CabiA001009006.port.T; CABI0CabiA001009006.der_T = der(CABI0CabiA001009006.T); CABI0CabiA001009006.C * der(CABI0CabiA001009006.T) = CABI0CabiA001009006.port.Q_flow; CABI0CabiA013009006.T = CABI0CabiA013009006.port.T; CABI0CabiA013009006.der_T = der(CABI0CabiA013009006.T); CABI0CabiA013009006.C * der(CABI0CabiA013009006.T) = CABI0CabiA013009006.port.Q_flow; CABI0CabiA001010006.T = CABI0CabiA001010006.port.T; CABI0CabiA001010006.der_T = der(CABI0CabiA001010006.T); CABI0CabiA001010006.C * der(CABI0CabiA001010006.T) = CABI0CabiA001010006.port.Q_flow; CABI0CabiA013010006.T = CABI0CabiA013010006.port.T; CABI0CabiA013010006.der_T = der(CABI0CabiA013010006.T); CABI0CabiA013010006.C * der(CABI0CabiA013010006.T) = CABI0CabiA013010006.port.Q_flow; CABI0CabiA001011006.T = CABI0CabiA001011006.port.T; CABI0CabiA001011006.der_T = der(CABI0CabiA001011006.T); CABI0CabiA001011006.C * der(CABI0CabiA001011006.T) = CABI0CabiA001011006.port.Q_flow; CABI0CabiA013011006.T = CABI0CabiA013011006.port.T; CABI0CabiA013011006.der_T = der(CABI0CabiA013011006.T); CABI0CabiA013011006.C * der(CABI0CabiA013011006.T) = CABI0CabiA013011006.port.Q_flow; CABI0CabiA001012006.T = CABI0CabiA001012006.port.T; CABI0CabiA001012006.der_T = der(CABI0CabiA001012006.T); CABI0CabiA001012006.C * der(CABI0CabiA001012006.T) = CABI0CabiA001012006.port.Q_flow; CABI0CabiA013012006.T = CABI0CabiA013012006.port.T; CABI0CabiA013012006.der_T = der(CABI0CabiA013012006.T); CABI0CabiA013012006.C * der(CABI0CabiA013012006.T) = CABI0CabiA013012006.port.Q_flow; CABI0CabiA001013006.T = CABI0CabiA001013006.port.T; CABI0CabiA001013006.der_T = der(CABI0CabiA001013006.T); CABI0CabiA001013006.C * der(CABI0CabiA001013006.T) = CABI0CabiA001013006.port.Q_flow; CABI0CabiA013013006.T = CABI0CabiA013013006.port.T; CABI0CabiA013013006.der_T = der(CABI0CabiA013013006.T); CABI0CabiA013013006.C * der(CABI0CabiA013013006.T) = CABI0CabiA013013006.port.Q_flow; CABI0CabiA001014006.T = CABI0CabiA001014006.port.T; CABI0CabiA001014006.der_T = der(CABI0CabiA001014006.T); CABI0CabiA001014006.C * der(CABI0CabiA001014006.T) = CABI0CabiA001014006.port.Q_flow; CABI0CabiA013014006.T = CABI0CabiA013014006.port.T; CABI0CabiA013014006.der_T = der(CABI0CabiA013014006.T); CABI0CabiA013014006.C * der(CABI0CabiA013014006.T) = CABI0CabiA013014006.port.Q_flow; CABI0CabiA001015006.T = CABI0CabiA001015006.port.T; CABI0CabiA001015006.der_T = der(CABI0CabiA001015006.T); CABI0CabiA001015006.C * der(CABI0CabiA001015006.T) = CABI0CabiA001015006.port.Q_flow; CABI0CabiA013015006.T = CABI0CabiA013015006.port.T; CABI0CabiA013015006.der_T = der(CABI0CabiA013015006.T); CABI0CabiA013015006.C * der(CABI0CabiA013015006.T) = CABI0CabiA013015006.port.Q_flow; CABI0CabiA001016006.T = CABI0CabiA001016006.port.T; CABI0CabiA001016006.der_T = der(CABI0CabiA001016006.T); CABI0CabiA001016006.C * der(CABI0CabiA001016006.T) = CABI0CabiA001016006.port.Q_flow; CABI0CabiA002016006.T = CABI0CabiA002016006.port.T; CABI0CabiA002016006.der_T = der(CABI0CabiA002016006.T); CABI0CabiA002016006.C * der(CABI0CabiA002016006.T) = CABI0CabiA002016006.port.Q_flow; CABI0CabiA003016006.T = CABI0CabiA003016006.port.T; CABI0CabiA003016006.der_T = der(CABI0CabiA003016006.T); CABI0CabiA003016006.C * der(CABI0CabiA003016006.T) = CABI0CabiA003016006.port.Q_flow; CABI0CabiA004016006.T = CABI0CabiA004016006.port.T; CABI0CabiA004016006.der_T = der(CABI0CabiA004016006.T); CABI0CabiA004016006.C * der(CABI0CabiA004016006.T) = CABI0CabiA004016006.port.Q_flow; CABI0CabiA005016006.T = CABI0CabiA005016006.port.T; CABI0CabiA005016006.der_T = der(CABI0CabiA005016006.T); CABI0CabiA005016006.C * der(CABI0CabiA005016006.T) = CABI0CabiA005016006.port.Q_flow; CABI0CabiA006016006.T = CABI0CabiA006016006.port.T; CABI0CabiA006016006.der_T = der(CABI0CabiA006016006.T); CABI0CabiA006016006.C * der(CABI0CabiA006016006.T) = CABI0CabiA006016006.port.Q_flow; CABI0CabiA007016006.T = CABI0CabiA007016006.port.T; CABI0CabiA007016006.der_T = der(CABI0CabiA007016006.T); CABI0CabiA007016006.C * der(CABI0CabiA007016006.T) = CABI0CabiA007016006.port.Q_flow; CABI0CabiA008016006.T = CABI0CabiA008016006.port.T; CABI0CabiA008016006.der_T = der(CABI0CabiA008016006.T); CABI0CabiA008016006.C * der(CABI0CabiA008016006.T) = CABI0CabiA008016006.port.Q_flow; CABI0CabiA009016006.T = CABI0CabiA009016006.port.T; CABI0CabiA009016006.der_T = der(CABI0CabiA009016006.T); CABI0CabiA009016006.C * der(CABI0CabiA009016006.T) = CABI0CabiA009016006.port.Q_flow; CABI0CabiA010016006.T = CABI0CabiA010016006.port.T; CABI0CabiA010016006.der_T = der(CABI0CabiA010016006.T); CABI0CabiA010016006.C * der(CABI0CabiA010016006.T) = CABI0CabiA010016006.port.Q_flow; CABI0CabiA011016006.T = CABI0CabiA011016006.port.T; CABI0CabiA011016006.der_T = der(CABI0CabiA011016006.T); CABI0CabiA011016006.C * der(CABI0CabiA011016006.T) = CABI0CabiA011016006.port.Q_flow; CABI0CabiA012016006.T = CABI0CabiA012016006.port.T; CABI0CabiA012016006.der_T = der(CABI0CabiA012016006.T); CABI0CabiA012016006.C * der(CABI0CabiA012016006.T) = CABI0CabiA012016006.port.Q_flow; CABI0CabiA013016006.T = CABI0CabiA013016006.port.T; CABI0CabiA013016006.der_T = der(CABI0CabiA013016006.T); CABI0CabiA013016006.C * der(CABI0CabiA013016006.T) = CABI0CabiA013016006.port.Q_flow; CABI0CabiA001001007.T = CABI0CabiA001001007.port.T; CABI0CabiA001001007.der_T = der(CABI0CabiA001001007.T); CABI0CabiA001001007.C * der(CABI0CabiA001001007.T) = CABI0CabiA001001007.port.Q_flow; CABI0CabiA002001007.T = CABI0CabiA002001007.port.T; CABI0CabiA002001007.der_T = der(CABI0CabiA002001007.T); CABI0CabiA002001007.C * der(CABI0CabiA002001007.T) = CABI0CabiA002001007.port.Q_flow; CABI0CabiA003001007.T = CABI0CabiA003001007.port.T; CABI0CabiA003001007.der_T = der(CABI0CabiA003001007.T); CABI0CabiA003001007.C * der(CABI0CabiA003001007.T) = CABI0CabiA003001007.port.Q_flow; CABI0CabiA004001007.T = CABI0CabiA004001007.port.T; CABI0CabiA004001007.der_T = der(CABI0CabiA004001007.T); CABI0CabiA004001007.C * der(CABI0CabiA004001007.T) = CABI0CabiA004001007.port.Q_flow; CABI0CabiA005001007.T = CABI0CabiA005001007.port.T; CABI0CabiA005001007.der_T = der(CABI0CabiA005001007.T); CABI0CabiA005001007.C * der(CABI0CabiA005001007.T) = CABI0CabiA005001007.port.Q_flow; CABI0CabiA006001007.T = CABI0CabiA006001007.port.T; CABI0CabiA006001007.der_T = der(CABI0CabiA006001007.T); CABI0CabiA006001007.C * der(CABI0CabiA006001007.T) = CABI0CabiA006001007.port.Q_flow; CABI0CabiA007001007.T = CABI0CabiA007001007.port.T; CABI0CabiA007001007.der_T = der(CABI0CabiA007001007.T); CABI0CabiA007001007.C * der(CABI0CabiA007001007.T) = CABI0CabiA007001007.port.Q_flow; CABI0CabiA008001007.T = CABI0CabiA008001007.port.T; CABI0CabiA008001007.der_T = der(CABI0CabiA008001007.T); CABI0CabiA008001007.C * der(CABI0CabiA008001007.T) = CABI0CabiA008001007.port.Q_flow; CABI0CabiA009001007.T = CABI0CabiA009001007.port.T; CABI0CabiA009001007.der_T = der(CABI0CabiA009001007.T); CABI0CabiA009001007.C * der(CABI0CabiA009001007.T) = CABI0CabiA009001007.port.Q_flow; CABI0CabiA010001007.T = CABI0CabiA010001007.port.T; CABI0CabiA010001007.der_T = der(CABI0CabiA010001007.T); CABI0CabiA010001007.C * der(CABI0CabiA010001007.T) = CABI0CabiA010001007.port.Q_flow; CABI0CabiA011001007.T = CABI0CabiA011001007.port.T; CABI0CabiA011001007.der_T = der(CABI0CabiA011001007.T); CABI0CabiA011001007.C * der(CABI0CabiA011001007.T) = CABI0CabiA011001007.port.Q_flow; CABI0CabiA012001007.T = CABI0CabiA012001007.port.T; CABI0CabiA012001007.der_T = der(CABI0CabiA012001007.T); CABI0CabiA012001007.C * der(CABI0CabiA012001007.T) = CABI0CabiA012001007.port.Q_flow; CABI0CabiA013001007.T = CABI0CabiA013001007.port.T; CABI0CabiA013001007.der_T = der(CABI0CabiA013001007.T); CABI0CabiA013001007.C * der(CABI0CabiA013001007.T) = CABI0CabiA013001007.port.Q_flow; CABI0CabiA001002007.T = CABI0CabiA001002007.port.T; CABI0CabiA001002007.der_T = der(CABI0CabiA001002007.T); CABI0CabiA001002007.C * der(CABI0CabiA001002007.T) = CABI0CabiA001002007.port.Q_flow; CABI0CabiA013002007.T = CABI0CabiA013002007.port.T; CABI0CabiA013002007.der_T = der(CABI0CabiA013002007.T); CABI0CabiA013002007.C * der(CABI0CabiA013002007.T) = CABI0CabiA013002007.port.Q_flow; CABI0CabiA001003007.T = CABI0CabiA001003007.port.T; CABI0CabiA001003007.der_T = der(CABI0CabiA001003007.T); CABI0CabiA001003007.C * der(CABI0CabiA001003007.T) = CABI0CabiA001003007.port.Q_flow; CABI0CabiA013003007.T = CABI0CabiA013003007.port.T; CABI0CabiA013003007.der_T = der(CABI0CabiA013003007.T); CABI0CabiA013003007.C * der(CABI0CabiA013003007.T) = CABI0CabiA013003007.port.Q_flow; CABI0CabiA001004007.T = CABI0CabiA001004007.port.T; CABI0CabiA001004007.der_T = der(CABI0CabiA001004007.T); CABI0CabiA001004007.C * der(CABI0CabiA001004007.T) = CABI0CabiA001004007.port.Q_flow; CABI0CabiA013004007.T = CABI0CabiA013004007.port.T; CABI0CabiA013004007.der_T = der(CABI0CabiA013004007.T); CABI0CabiA013004007.C * der(CABI0CabiA013004007.T) = CABI0CabiA013004007.port.Q_flow; CABI0CabiA001005007.T = CABI0CabiA001005007.port.T; CABI0CabiA001005007.der_T = der(CABI0CabiA001005007.T); CABI0CabiA001005007.C * der(CABI0CabiA001005007.T) = CABI0CabiA001005007.port.Q_flow; CABI0CabiA013005007.T = CABI0CabiA013005007.port.T; CABI0CabiA013005007.der_T = der(CABI0CabiA013005007.T); CABI0CabiA013005007.C * der(CABI0CabiA013005007.T) = CABI0CabiA013005007.port.Q_flow; CABI0CabiA001006007.T = CABI0CabiA001006007.port.T; CABI0CabiA001006007.der_T = der(CABI0CabiA001006007.T); CABI0CabiA001006007.C * der(CABI0CabiA001006007.T) = CABI0CabiA001006007.port.Q_flow; CABI0CabiA013006007.T = CABI0CabiA013006007.port.T; CABI0CabiA013006007.der_T = der(CABI0CabiA013006007.T); CABI0CabiA013006007.C * der(CABI0CabiA013006007.T) = CABI0CabiA013006007.port.Q_flow; CABI0CabiA001007007.T = CABI0CabiA001007007.port.T; CABI0CabiA001007007.der_T = der(CABI0CabiA001007007.T); CABI0CabiA001007007.C * der(CABI0CabiA001007007.T) = CABI0CabiA001007007.port.Q_flow; CABI0CabiA013007007.T = CABI0CabiA013007007.port.T; CABI0CabiA013007007.der_T = der(CABI0CabiA013007007.T); CABI0CabiA013007007.C * der(CABI0CabiA013007007.T) = CABI0CabiA013007007.port.Q_flow; CABI0CabiA001008007.T = CABI0CabiA001008007.port.T; CABI0CabiA001008007.der_T = der(CABI0CabiA001008007.T); CABI0CabiA001008007.C * der(CABI0CabiA001008007.T) = CABI0CabiA001008007.port.Q_flow; CABI0CabiA013008007.T = CABI0CabiA013008007.port.T; CABI0CabiA013008007.der_T = der(CABI0CabiA013008007.T); CABI0CabiA013008007.C * der(CABI0CabiA013008007.T) = CABI0CabiA013008007.port.Q_flow; CABI0CabiA001009007.T = CABI0CabiA001009007.port.T; CABI0CabiA001009007.der_T = der(CABI0CabiA001009007.T); CABI0CabiA001009007.C * der(CABI0CabiA001009007.T) = CABI0CabiA001009007.port.Q_flow; CABI0CabiA013009007.T = CABI0CabiA013009007.port.T; CABI0CabiA013009007.der_T = der(CABI0CabiA013009007.T); CABI0CabiA013009007.C * der(CABI0CabiA013009007.T) = CABI0CabiA013009007.port.Q_flow; CABI0CabiA001010007.T = CABI0CabiA001010007.port.T; CABI0CabiA001010007.der_T = der(CABI0CabiA001010007.T); CABI0CabiA001010007.C * der(CABI0CabiA001010007.T) = CABI0CabiA001010007.port.Q_flow; CABI0CabiA013010007.T = CABI0CabiA013010007.port.T; CABI0CabiA013010007.der_T = der(CABI0CabiA013010007.T); CABI0CabiA013010007.C * der(CABI0CabiA013010007.T) = CABI0CabiA013010007.port.Q_flow; CABI0CabiA001011007.T = CABI0CabiA001011007.port.T; CABI0CabiA001011007.der_T = der(CABI0CabiA001011007.T); CABI0CabiA001011007.C * der(CABI0CabiA001011007.T) = CABI0CabiA001011007.port.Q_flow; CABI0CabiA013011007.T = CABI0CabiA013011007.port.T; CABI0CabiA013011007.der_T = der(CABI0CabiA013011007.T); CABI0CabiA013011007.C * der(CABI0CabiA013011007.T) = CABI0CabiA013011007.port.Q_flow; CABI0CabiA001012007.T = CABI0CabiA001012007.port.T; CABI0CabiA001012007.der_T = der(CABI0CabiA001012007.T); CABI0CabiA001012007.C * der(CABI0CabiA001012007.T) = CABI0CabiA001012007.port.Q_flow; CABI0CabiA013012007.T = CABI0CabiA013012007.port.T; CABI0CabiA013012007.der_T = der(CABI0CabiA013012007.T); CABI0CabiA013012007.C * der(CABI0CabiA013012007.T) = CABI0CabiA013012007.port.Q_flow; CABI0CabiA001013007.T = CABI0CabiA001013007.port.T; CABI0CabiA001013007.der_T = der(CABI0CabiA001013007.T); CABI0CabiA001013007.C * der(CABI0CabiA001013007.T) = CABI0CabiA001013007.port.Q_flow; CABI0CabiA013013007.T = CABI0CabiA013013007.port.T; CABI0CabiA013013007.der_T = der(CABI0CabiA013013007.T); CABI0CabiA013013007.C * der(CABI0CabiA013013007.T) = CABI0CabiA013013007.port.Q_flow; CABI0CabiA001014007.T = CABI0CabiA001014007.port.T; CABI0CabiA001014007.der_T = der(CABI0CabiA001014007.T); CABI0CabiA001014007.C * der(CABI0CabiA001014007.T) = CABI0CabiA001014007.port.Q_flow; CABI0CabiA013014007.T = CABI0CabiA013014007.port.T; CABI0CabiA013014007.der_T = der(CABI0CabiA013014007.T); CABI0CabiA013014007.C * der(CABI0CabiA013014007.T) = CABI0CabiA013014007.port.Q_flow; CABI0CabiA001015007.T = CABI0CabiA001015007.port.T; CABI0CabiA001015007.der_T = der(CABI0CabiA001015007.T); CABI0CabiA001015007.C * der(CABI0CabiA001015007.T) = CABI0CabiA001015007.port.Q_flow; CABI0CabiA013015007.T = CABI0CabiA013015007.port.T; CABI0CabiA013015007.der_T = der(CABI0CabiA013015007.T); CABI0CabiA013015007.C * der(CABI0CabiA013015007.T) = CABI0CabiA013015007.port.Q_flow; CABI0CabiA001016007.T = CABI0CabiA001016007.port.T; CABI0CabiA001016007.der_T = der(CABI0CabiA001016007.T); CABI0CabiA001016007.C * der(CABI0CabiA001016007.T) = CABI0CabiA001016007.port.Q_flow; CABI0CabiA002016007.T = CABI0CabiA002016007.port.T; CABI0CabiA002016007.der_T = der(CABI0CabiA002016007.T); CABI0CabiA002016007.C * der(CABI0CabiA002016007.T) = CABI0CabiA002016007.port.Q_flow; CABI0CabiA003016007.T = CABI0CabiA003016007.port.T; CABI0CabiA003016007.der_T = der(CABI0CabiA003016007.T); CABI0CabiA003016007.C * der(CABI0CabiA003016007.T) = CABI0CabiA003016007.port.Q_flow; CABI0CabiA004016007.T = CABI0CabiA004016007.port.T; CABI0CabiA004016007.der_T = der(CABI0CabiA004016007.T); CABI0CabiA004016007.C * der(CABI0CabiA004016007.T) = CABI0CabiA004016007.port.Q_flow; CABI0CabiA005016007.T = CABI0CabiA005016007.port.T; CABI0CabiA005016007.der_T = der(CABI0CabiA005016007.T); CABI0CabiA005016007.C * der(CABI0CabiA005016007.T) = CABI0CabiA005016007.port.Q_flow; CABI0CabiA006016007.T = CABI0CabiA006016007.port.T; CABI0CabiA006016007.der_T = der(CABI0CabiA006016007.T); CABI0CabiA006016007.C * der(CABI0CabiA006016007.T) = CABI0CabiA006016007.port.Q_flow; CABI0CabiA007016007.T = CABI0CabiA007016007.port.T; CABI0CabiA007016007.der_T = der(CABI0CabiA007016007.T); CABI0CabiA007016007.C * der(CABI0CabiA007016007.T) = CABI0CabiA007016007.port.Q_flow; CABI0CabiA008016007.T = CABI0CabiA008016007.port.T; CABI0CabiA008016007.der_T = der(CABI0CabiA008016007.T); CABI0CabiA008016007.C * der(CABI0CabiA008016007.T) = CABI0CabiA008016007.port.Q_flow; CABI0CabiA009016007.T = CABI0CabiA009016007.port.T; CABI0CabiA009016007.der_T = der(CABI0CabiA009016007.T); CABI0CabiA009016007.C * der(CABI0CabiA009016007.T) = CABI0CabiA009016007.port.Q_flow; CABI0CabiA010016007.T = CABI0CabiA010016007.port.T; CABI0CabiA010016007.der_T = der(CABI0CabiA010016007.T); CABI0CabiA010016007.C * der(CABI0CabiA010016007.T) = CABI0CabiA010016007.port.Q_flow; CABI0CabiA011016007.T = CABI0CabiA011016007.port.T; CABI0CabiA011016007.der_T = der(CABI0CabiA011016007.T); CABI0CabiA011016007.C * der(CABI0CabiA011016007.T) = CABI0CabiA011016007.port.Q_flow; CABI0CabiA012016007.T = CABI0CabiA012016007.port.T; CABI0CabiA012016007.der_T = der(CABI0CabiA012016007.T); CABI0CabiA012016007.C * der(CABI0CabiA012016007.T) = CABI0CabiA012016007.port.Q_flow; CABI0CabiA013016007.T = CABI0CabiA013016007.port.T; CABI0CabiA013016007.der_T = der(CABI0CabiA013016007.T); CABI0CabiA013016007.C * der(CABI0CabiA013016007.T) = CABI0CabiA013016007.port.Q_flow; CABI0CabiA001001008.T = CABI0CabiA001001008.port.T; CABI0CabiA001001008.der_T = der(CABI0CabiA001001008.T); CABI0CabiA001001008.C * der(CABI0CabiA001001008.T) = CABI0CabiA001001008.port.Q_flow; CABI0CabiA002001008.T = CABI0CabiA002001008.port.T; CABI0CabiA002001008.der_T = der(CABI0CabiA002001008.T); CABI0CabiA002001008.C * der(CABI0CabiA002001008.T) = CABI0CabiA002001008.port.Q_flow; CABI0CabiA003001008.T = CABI0CabiA003001008.port.T; CABI0CabiA003001008.der_T = der(CABI0CabiA003001008.T); CABI0CabiA003001008.C * der(CABI0CabiA003001008.T) = CABI0CabiA003001008.port.Q_flow; CABI0CabiA004001008.T = CABI0CabiA004001008.port.T; CABI0CabiA004001008.der_T = der(CABI0CabiA004001008.T); CABI0CabiA004001008.C * der(CABI0CabiA004001008.T) = CABI0CabiA004001008.port.Q_flow; CABI0CabiA005001008.T = CABI0CabiA005001008.port.T; CABI0CabiA005001008.der_T = der(CABI0CabiA005001008.T); CABI0CabiA005001008.C * der(CABI0CabiA005001008.T) = CABI0CabiA005001008.port.Q_flow; CABI0CabiA006001008.T = CABI0CabiA006001008.port.T; CABI0CabiA006001008.der_T = der(CABI0CabiA006001008.T); CABI0CabiA006001008.C * der(CABI0CabiA006001008.T) = CABI0CabiA006001008.port.Q_flow; CABI0CabiA007001008.T = CABI0CabiA007001008.port.T; CABI0CabiA007001008.der_T = der(CABI0CabiA007001008.T); CABI0CabiA007001008.C * der(CABI0CabiA007001008.T) = CABI0CabiA007001008.port.Q_flow; CABI0CabiA008001008.T = CABI0CabiA008001008.port.T; CABI0CabiA008001008.der_T = der(CABI0CabiA008001008.T); CABI0CabiA008001008.C * der(CABI0CabiA008001008.T) = CABI0CabiA008001008.port.Q_flow; CABI0CabiA009001008.T = CABI0CabiA009001008.port.T; CABI0CabiA009001008.der_T = der(CABI0CabiA009001008.T); CABI0CabiA009001008.C * der(CABI0CabiA009001008.T) = CABI0CabiA009001008.port.Q_flow; CABI0CabiA010001008.T = CABI0CabiA010001008.port.T; CABI0CabiA010001008.der_T = der(CABI0CabiA010001008.T); CABI0CabiA010001008.C * der(CABI0CabiA010001008.T) = CABI0CabiA010001008.port.Q_flow; CABI0CabiA011001008.T = CABI0CabiA011001008.port.T; CABI0CabiA011001008.der_T = der(CABI0CabiA011001008.T); CABI0CabiA011001008.C * der(CABI0CabiA011001008.T) = CABI0CabiA011001008.port.Q_flow; CABI0CabiA012001008.T = CABI0CabiA012001008.port.T; CABI0CabiA012001008.der_T = der(CABI0CabiA012001008.T); CABI0CabiA012001008.C * der(CABI0CabiA012001008.T) = CABI0CabiA012001008.port.Q_flow; CABI0CabiA013001008.T = CABI0CabiA013001008.port.T; CABI0CabiA013001008.der_T = der(CABI0CabiA013001008.T); CABI0CabiA013001008.C * der(CABI0CabiA013001008.T) = CABI0CabiA013001008.port.Q_flow; CABI0CabiA001002008.T = CABI0CabiA001002008.port.T; CABI0CabiA001002008.der_T = der(CABI0CabiA001002008.T); CABI0CabiA001002008.C * der(CABI0CabiA001002008.T) = CABI0CabiA001002008.port.Q_flow; CABI0CabiA002002008.T = CABI0CabiA002002008.port.T; CABI0CabiA002002008.der_T = der(CABI0CabiA002002008.T); CABI0CabiA002002008.C * der(CABI0CabiA002002008.T) = CABI0CabiA002002008.port.Q_flow; CABI0CabiA003002008.T = CABI0CabiA003002008.port.T; CABI0CabiA003002008.der_T = der(CABI0CabiA003002008.T); CABI0CabiA003002008.C * der(CABI0CabiA003002008.T) = CABI0CabiA003002008.port.Q_flow; CABI0CabiA004002008.T = CABI0CabiA004002008.port.T; CABI0CabiA004002008.der_T = der(CABI0CabiA004002008.T); CABI0CabiA004002008.C * der(CABI0CabiA004002008.T) = CABI0CabiA004002008.port.Q_flow; CABI0CabiA005002008.T = CABI0CabiA005002008.port.T; CABI0CabiA005002008.der_T = der(CABI0CabiA005002008.T); CABI0CabiA005002008.C * der(CABI0CabiA005002008.T) = CABI0CabiA005002008.port.Q_flow; CABI0CabiA006002008.T = CABI0CabiA006002008.port.T; CABI0CabiA006002008.der_T = der(CABI0CabiA006002008.T); CABI0CabiA006002008.C * der(CABI0CabiA006002008.T) = CABI0CabiA006002008.port.Q_flow; CABI0CabiA007002008.T = CABI0CabiA007002008.port.T; CABI0CabiA007002008.der_T = der(CABI0CabiA007002008.T); CABI0CabiA007002008.C * der(CABI0CabiA007002008.T) = CABI0CabiA007002008.port.Q_flow; CABI0CabiA008002008.T = CABI0CabiA008002008.port.T; CABI0CabiA008002008.der_T = der(CABI0CabiA008002008.T); CABI0CabiA008002008.C * der(CABI0CabiA008002008.T) = CABI0CabiA008002008.port.Q_flow; CABI0CabiA009002008.T = CABI0CabiA009002008.port.T; CABI0CabiA009002008.der_T = der(CABI0CabiA009002008.T); CABI0CabiA009002008.C * der(CABI0CabiA009002008.T) = CABI0CabiA009002008.port.Q_flow; CABI0CabiA010002008.T = CABI0CabiA010002008.port.T; CABI0CabiA010002008.der_T = der(CABI0CabiA010002008.T); CABI0CabiA010002008.C * der(CABI0CabiA010002008.T) = CABI0CabiA010002008.port.Q_flow; CABI0CabiA011002008.T = CABI0CabiA011002008.port.T; CABI0CabiA011002008.der_T = der(CABI0CabiA011002008.T); CABI0CabiA011002008.C * der(CABI0CabiA011002008.T) = CABI0CabiA011002008.port.Q_flow; CABI0CabiA012002008.T = CABI0CabiA012002008.port.T; CABI0CabiA012002008.der_T = der(CABI0CabiA012002008.T); CABI0CabiA012002008.C * der(CABI0CabiA012002008.T) = CABI0CabiA012002008.port.Q_flow; CABI0CabiA013002008.T = CABI0CabiA013002008.port.T; CABI0CabiA013002008.der_T = der(CABI0CabiA013002008.T); CABI0CabiA013002008.C * der(CABI0CabiA013002008.T) = CABI0CabiA013002008.port.Q_flow; CABI0CabiA001003008.T = CABI0CabiA001003008.port.T; CABI0CabiA001003008.der_T = der(CABI0CabiA001003008.T); CABI0CabiA001003008.C * der(CABI0CabiA001003008.T) = CABI0CabiA001003008.port.Q_flow; CABI0CabiA002003008.T = CABI0CabiA002003008.port.T; CABI0CabiA002003008.der_T = der(CABI0CabiA002003008.T); CABI0CabiA002003008.C * der(CABI0CabiA002003008.T) = CABI0CabiA002003008.port.Q_flow; CABI0CabiA003003008.T = CABI0CabiA003003008.port.T; CABI0CabiA003003008.der_T = der(CABI0CabiA003003008.T); CABI0CabiA003003008.C * der(CABI0CabiA003003008.T) = CABI0CabiA003003008.port.Q_flow; CABI0CabiA004003008.T = CABI0CabiA004003008.port.T; CABI0CabiA004003008.der_T = der(CABI0CabiA004003008.T); CABI0CabiA004003008.C * der(CABI0CabiA004003008.T) = CABI0CabiA004003008.port.Q_flow; CABI0CabiA005003008.T = CABI0CabiA005003008.port.T; CABI0CabiA005003008.der_T = der(CABI0CabiA005003008.T); CABI0CabiA005003008.C * der(CABI0CabiA005003008.T) = CABI0CabiA005003008.port.Q_flow; CABI0CabiA006003008.T = CABI0CabiA006003008.port.T; CABI0CabiA006003008.der_T = der(CABI0CabiA006003008.T); CABI0CabiA006003008.C * der(CABI0CabiA006003008.T) = CABI0CabiA006003008.port.Q_flow; CABI0CabiA007003008.T = CABI0CabiA007003008.port.T; CABI0CabiA007003008.der_T = der(CABI0CabiA007003008.T); CABI0CabiA007003008.C * der(CABI0CabiA007003008.T) = CABI0CabiA007003008.port.Q_flow; CABI0CabiA008003008.T = CABI0CabiA008003008.port.T; CABI0CabiA008003008.der_T = der(CABI0CabiA008003008.T); CABI0CabiA008003008.C * der(CABI0CabiA008003008.T) = CABI0CabiA008003008.port.Q_flow; CABI0CabiA009003008.T = CABI0CabiA009003008.port.T; CABI0CabiA009003008.der_T = der(CABI0CabiA009003008.T); CABI0CabiA009003008.C * der(CABI0CabiA009003008.T) = CABI0CabiA009003008.port.Q_flow; CABI0CabiA010003008.T = CABI0CabiA010003008.port.T; CABI0CabiA010003008.der_T = der(CABI0CabiA010003008.T); CABI0CabiA010003008.C * der(CABI0CabiA010003008.T) = CABI0CabiA010003008.port.Q_flow; CABI0CabiA011003008.T = CABI0CabiA011003008.port.T; CABI0CabiA011003008.der_T = der(CABI0CabiA011003008.T); CABI0CabiA011003008.C * der(CABI0CabiA011003008.T) = CABI0CabiA011003008.port.Q_flow; CABI0CabiA012003008.T = CABI0CabiA012003008.port.T; CABI0CabiA012003008.der_T = der(CABI0CabiA012003008.T); CABI0CabiA012003008.C * der(CABI0CabiA012003008.T) = CABI0CabiA012003008.port.Q_flow; CABI0CabiA013003008.T = CABI0CabiA013003008.port.T; CABI0CabiA013003008.der_T = der(CABI0CabiA013003008.T); CABI0CabiA013003008.C * der(CABI0CabiA013003008.T) = CABI0CabiA013003008.port.Q_flow; CABI0CabiA001004008.T = CABI0CabiA001004008.port.T; CABI0CabiA001004008.der_T = der(CABI0CabiA001004008.T); CABI0CabiA001004008.C * der(CABI0CabiA001004008.T) = CABI0CabiA001004008.port.Q_flow; CABI0CabiA002004008.T = CABI0CabiA002004008.port.T; CABI0CabiA002004008.der_T = der(CABI0CabiA002004008.T); CABI0CabiA002004008.C * der(CABI0CabiA002004008.T) = CABI0CabiA002004008.port.Q_flow; CABI0CabiA003004008.T = CABI0CabiA003004008.port.T; CABI0CabiA003004008.der_T = der(CABI0CabiA003004008.T); CABI0CabiA003004008.C * der(CABI0CabiA003004008.T) = CABI0CabiA003004008.port.Q_flow; CABI0CabiA004004008.T = CABI0CabiA004004008.port.T; CABI0CabiA004004008.der_T = der(CABI0CabiA004004008.T); CABI0CabiA004004008.C * der(CABI0CabiA004004008.T) = CABI0CabiA004004008.port.Q_flow; CABI0CabiA005004008.T = CABI0CabiA005004008.port.T; CABI0CabiA005004008.der_T = der(CABI0CabiA005004008.T); CABI0CabiA005004008.C * der(CABI0CabiA005004008.T) = CABI0CabiA005004008.port.Q_flow; CABI0CabiA006004008.T = CABI0CabiA006004008.port.T; CABI0CabiA006004008.der_T = der(CABI0CabiA006004008.T); CABI0CabiA006004008.C * der(CABI0CabiA006004008.T) = CABI0CabiA006004008.port.Q_flow; CABI0CabiA007004008.T = CABI0CabiA007004008.port.T; CABI0CabiA007004008.der_T = der(CABI0CabiA007004008.T); CABI0CabiA007004008.C * der(CABI0CabiA007004008.T) = CABI0CabiA007004008.port.Q_flow; CABI0CabiA008004008.T = CABI0CabiA008004008.port.T; CABI0CabiA008004008.der_T = der(CABI0CabiA008004008.T); CABI0CabiA008004008.C * der(CABI0CabiA008004008.T) = CABI0CabiA008004008.port.Q_flow; CABI0CabiA009004008.T = CABI0CabiA009004008.port.T; CABI0CabiA009004008.der_T = der(CABI0CabiA009004008.T); CABI0CabiA009004008.C * der(CABI0CabiA009004008.T) = CABI0CabiA009004008.port.Q_flow; CABI0CabiA010004008.T = CABI0CabiA010004008.port.T; CABI0CabiA010004008.der_T = der(CABI0CabiA010004008.T); CABI0CabiA010004008.C * der(CABI0CabiA010004008.T) = CABI0CabiA010004008.port.Q_flow; CABI0CabiA011004008.T = CABI0CabiA011004008.port.T; CABI0CabiA011004008.der_T = der(CABI0CabiA011004008.T); CABI0CabiA011004008.C * der(CABI0CabiA011004008.T) = CABI0CabiA011004008.port.Q_flow; CABI0CabiA012004008.T = CABI0CabiA012004008.port.T; CABI0CabiA012004008.der_T = der(CABI0CabiA012004008.T); CABI0CabiA012004008.C * der(CABI0CabiA012004008.T) = CABI0CabiA012004008.port.Q_flow; CABI0CabiA013004008.T = CABI0CabiA013004008.port.T; CABI0CabiA013004008.der_T = der(CABI0CabiA013004008.T); CABI0CabiA013004008.C * der(CABI0CabiA013004008.T) = CABI0CabiA013004008.port.Q_flow; CABI0CabiA001005008.T = CABI0CabiA001005008.port.T; CABI0CabiA001005008.der_T = der(CABI0CabiA001005008.T); CABI0CabiA001005008.C * der(CABI0CabiA001005008.T) = CABI0CabiA001005008.port.Q_flow; CABI0CabiA002005008.T = CABI0CabiA002005008.port.T; CABI0CabiA002005008.der_T = der(CABI0CabiA002005008.T); CABI0CabiA002005008.C * der(CABI0CabiA002005008.T) = CABI0CabiA002005008.port.Q_flow; CABI0CabiA003005008.T = CABI0CabiA003005008.port.T; CABI0CabiA003005008.der_T = der(CABI0CabiA003005008.T); CABI0CabiA003005008.C * der(CABI0CabiA003005008.T) = CABI0CabiA003005008.port.Q_flow; CABI0CabiA004005008.T = CABI0CabiA004005008.port.T; CABI0CabiA004005008.der_T = der(CABI0CabiA004005008.T); CABI0CabiA004005008.C * der(CABI0CabiA004005008.T) = CABI0CabiA004005008.port.Q_flow; CABI0CabiA005005008.T = CABI0CabiA005005008.port.T; CABI0CabiA005005008.der_T = der(CABI0CabiA005005008.T); CABI0CabiA005005008.C * der(CABI0CabiA005005008.T) = CABI0CabiA005005008.port.Q_flow; CABI0CabiA006005008.T = CABI0CabiA006005008.port.T; CABI0CabiA006005008.der_T = der(CABI0CabiA006005008.T); CABI0CabiA006005008.C * der(CABI0CabiA006005008.T) = CABI0CabiA006005008.port.Q_flow; CABI0CabiA007005008.T = CABI0CabiA007005008.port.T; CABI0CabiA007005008.der_T = der(CABI0CabiA007005008.T); CABI0CabiA007005008.C * der(CABI0CabiA007005008.T) = CABI0CabiA007005008.port.Q_flow; CABI0CabiA008005008.T = CABI0CabiA008005008.port.T; CABI0CabiA008005008.der_T = der(CABI0CabiA008005008.T); CABI0CabiA008005008.C * der(CABI0CabiA008005008.T) = CABI0CabiA008005008.port.Q_flow; CABI0CabiA009005008.T = CABI0CabiA009005008.port.T; CABI0CabiA009005008.der_T = der(CABI0CabiA009005008.T); CABI0CabiA009005008.C * der(CABI0CabiA009005008.T) = CABI0CabiA009005008.port.Q_flow; CABI0CabiA010005008.T = CABI0CabiA010005008.port.T; CABI0CabiA010005008.der_T = der(CABI0CabiA010005008.T); CABI0CabiA010005008.C * der(CABI0CabiA010005008.T) = CABI0CabiA010005008.port.Q_flow; CABI0CabiA011005008.T = CABI0CabiA011005008.port.T; CABI0CabiA011005008.der_T = der(CABI0CabiA011005008.T); CABI0CabiA011005008.C * der(CABI0CabiA011005008.T) = CABI0CabiA011005008.port.Q_flow; CABI0CabiA012005008.T = CABI0CabiA012005008.port.T; CABI0CabiA012005008.der_T = der(CABI0CabiA012005008.T); CABI0CabiA012005008.C * der(CABI0CabiA012005008.T) = CABI0CabiA012005008.port.Q_flow; CABI0CabiA013005008.T = CABI0CabiA013005008.port.T; CABI0CabiA013005008.der_T = der(CABI0CabiA013005008.T); CABI0CabiA013005008.C * der(CABI0CabiA013005008.T) = CABI0CabiA013005008.port.Q_flow; CABI0CabiA001006008.T = CABI0CabiA001006008.port.T; CABI0CabiA001006008.der_T = der(CABI0CabiA001006008.T); CABI0CabiA001006008.C * der(CABI0CabiA001006008.T) = CABI0CabiA001006008.port.Q_flow; CABI0CabiA002006008.T = CABI0CabiA002006008.port.T; CABI0CabiA002006008.der_T = der(CABI0CabiA002006008.T); CABI0CabiA002006008.C * der(CABI0CabiA002006008.T) = CABI0CabiA002006008.port.Q_flow; CABI0CabiA003006008.T = CABI0CabiA003006008.port.T; CABI0CabiA003006008.der_T = der(CABI0CabiA003006008.T); CABI0CabiA003006008.C * der(CABI0CabiA003006008.T) = CABI0CabiA003006008.port.Q_flow; CABI0CabiA004006008.T = CABI0CabiA004006008.port.T; CABI0CabiA004006008.der_T = der(CABI0CabiA004006008.T); CABI0CabiA004006008.C * der(CABI0CabiA004006008.T) = CABI0CabiA004006008.port.Q_flow; CABI0CabiA005006008.T = CABI0CabiA005006008.port.T; CABI0CabiA005006008.der_T = der(CABI0CabiA005006008.T); CABI0CabiA005006008.C * der(CABI0CabiA005006008.T) = CABI0CabiA005006008.port.Q_flow; CABI0CabiA006006008.T = CABI0CabiA006006008.port.T; CABI0CabiA006006008.der_T = der(CABI0CabiA006006008.T); CABI0CabiA006006008.C * der(CABI0CabiA006006008.T) = CABI0CabiA006006008.port.Q_flow; CABI0CabiA007006008.T = CABI0CabiA007006008.port.T; CABI0CabiA007006008.der_T = der(CABI0CabiA007006008.T); CABI0CabiA007006008.C * der(CABI0CabiA007006008.T) = CABI0CabiA007006008.port.Q_flow; CABI0CabiA008006008.T = CABI0CabiA008006008.port.T; CABI0CabiA008006008.der_T = der(CABI0CabiA008006008.T); CABI0CabiA008006008.C * der(CABI0CabiA008006008.T) = CABI0CabiA008006008.port.Q_flow; CABI0CabiA009006008.T = CABI0CabiA009006008.port.T; CABI0CabiA009006008.der_T = der(CABI0CabiA009006008.T); CABI0CabiA009006008.C * der(CABI0CabiA009006008.T) = CABI0CabiA009006008.port.Q_flow; CABI0CabiA010006008.T = CABI0CabiA010006008.port.T; CABI0CabiA010006008.der_T = der(CABI0CabiA010006008.T); CABI0CabiA010006008.C * der(CABI0CabiA010006008.T) = CABI0CabiA010006008.port.Q_flow; CABI0CabiA011006008.T = CABI0CabiA011006008.port.T; CABI0CabiA011006008.der_T = der(CABI0CabiA011006008.T); CABI0CabiA011006008.C * der(CABI0CabiA011006008.T) = CABI0CabiA011006008.port.Q_flow; CABI0CabiA012006008.T = CABI0CabiA012006008.port.T; CABI0CabiA012006008.der_T = der(CABI0CabiA012006008.T); CABI0CabiA012006008.C * der(CABI0CabiA012006008.T) = CABI0CabiA012006008.port.Q_flow; CABI0CabiA013006008.T = CABI0CabiA013006008.port.T; CABI0CabiA013006008.der_T = der(CABI0CabiA013006008.T); CABI0CabiA013006008.C * der(CABI0CabiA013006008.T) = CABI0CabiA013006008.port.Q_flow; CABI0CabiA001007008.T = CABI0CabiA001007008.port.T; CABI0CabiA001007008.der_T = der(CABI0CabiA001007008.T); CABI0CabiA001007008.C * der(CABI0CabiA001007008.T) = CABI0CabiA001007008.port.Q_flow; CABI0CabiA002007008.T = CABI0CabiA002007008.port.T; CABI0CabiA002007008.der_T = der(CABI0CabiA002007008.T); CABI0CabiA002007008.C * der(CABI0CabiA002007008.T) = CABI0CabiA002007008.port.Q_flow; CABI0CabiA003007008.T = CABI0CabiA003007008.port.T; CABI0CabiA003007008.der_T = der(CABI0CabiA003007008.T); CABI0CabiA003007008.C * der(CABI0CabiA003007008.T) = CABI0CabiA003007008.port.Q_flow; CABI0CabiA004007008.T = CABI0CabiA004007008.port.T; CABI0CabiA004007008.der_T = der(CABI0CabiA004007008.T); CABI0CabiA004007008.C * der(CABI0CabiA004007008.T) = CABI0CabiA004007008.port.Q_flow; CABI0CabiA005007008.T = CABI0CabiA005007008.port.T; CABI0CabiA005007008.der_T = der(CABI0CabiA005007008.T); CABI0CabiA005007008.C * der(CABI0CabiA005007008.T) = CABI0CabiA005007008.port.Q_flow; CABI0CabiA006007008.T = CABI0CabiA006007008.port.T; CABI0CabiA006007008.der_T = der(CABI0CabiA006007008.T); CABI0CabiA006007008.C * der(CABI0CabiA006007008.T) = CABI0CabiA006007008.port.Q_flow; CABI0CabiA007007008.T = CABI0CabiA007007008.port.T; CABI0CabiA007007008.der_T = der(CABI0CabiA007007008.T); CABI0CabiA007007008.C * der(CABI0CabiA007007008.T) = CABI0CabiA007007008.port.Q_flow; CABI0CabiA008007008.T = CABI0CabiA008007008.port.T; CABI0CabiA008007008.der_T = der(CABI0CabiA008007008.T); CABI0CabiA008007008.C * der(CABI0CabiA008007008.T) = CABI0CabiA008007008.port.Q_flow; CABI0CabiA009007008.T = CABI0CabiA009007008.port.T; CABI0CabiA009007008.der_T = der(CABI0CabiA009007008.T); CABI0CabiA009007008.C * der(CABI0CabiA009007008.T) = CABI0CabiA009007008.port.Q_flow; CABI0CabiA010007008.T = CABI0CabiA010007008.port.T; CABI0CabiA010007008.der_T = der(CABI0CabiA010007008.T); CABI0CabiA010007008.C * der(CABI0CabiA010007008.T) = CABI0CabiA010007008.port.Q_flow; CABI0CabiA011007008.T = CABI0CabiA011007008.port.T; CABI0CabiA011007008.der_T = der(CABI0CabiA011007008.T); CABI0CabiA011007008.C * der(CABI0CabiA011007008.T) = CABI0CabiA011007008.port.Q_flow; CABI0CabiA012007008.T = CABI0CabiA012007008.port.T; CABI0CabiA012007008.der_T = der(CABI0CabiA012007008.T); CABI0CabiA012007008.C * der(CABI0CabiA012007008.T) = CABI0CabiA012007008.port.Q_flow; CABI0CabiA013007008.T = CABI0CabiA013007008.port.T; CABI0CabiA013007008.der_T = der(CABI0CabiA013007008.T); CABI0CabiA013007008.C * der(CABI0CabiA013007008.T) = CABI0CabiA013007008.port.Q_flow; CABI0CabiA001008008.T = CABI0CabiA001008008.port.T; CABI0CabiA001008008.der_T = der(CABI0CabiA001008008.T); CABI0CabiA001008008.C * der(CABI0CabiA001008008.T) = CABI0CabiA001008008.port.Q_flow; CABI0CabiA002008008.T = CABI0CabiA002008008.port.T; CABI0CabiA002008008.der_T = der(CABI0CabiA002008008.T); CABI0CabiA002008008.C * der(CABI0CabiA002008008.T) = CABI0CabiA002008008.port.Q_flow; CABI0CabiA003008008.T = CABI0CabiA003008008.port.T; CABI0CabiA003008008.der_T = der(CABI0CabiA003008008.T); CABI0CabiA003008008.C * der(CABI0CabiA003008008.T) = CABI0CabiA003008008.port.Q_flow; CABI0CabiA004008008.T = CABI0CabiA004008008.port.T; CABI0CabiA004008008.der_T = der(CABI0CabiA004008008.T); CABI0CabiA004008008.C * der(CABI0CabiA004008008.T) = CABI0CabiA004008008.port.Q_flow; CABI0CabiA005008008.T = CABI0CabiA005008008.port.T; CABI0CabiA005008008.der_T = der(CABI0CabiA005008008.T); CABI0CabiA005008008.C * der(CABI0CabiA005008008.T) = CABI0CabiA005008008.port.Q_flow; CABI0CabiA006008008.T = CABI0CabiA006008008.port.T; CABI0CabiA006008008.der_T = der(CABI0CabiA006008008.T); CABI0CabiA006008008.C * der(CABI0CabiA006008008.T) = CABI0CabiA006008008.port.Q_flow; CABI0CabiA007008008.T = CABI0CabiA007008008.port.T; CABI0CabiA007008008.der_T = der(CABI0CabiA007008008.T); CABI0CabiA007008008.C * der(CABI0CabiA007008008.T) = CABI0CabiA007008008.port.Q_flow; CABI0CabiA008008008.T = CABI0CabiA008008008.port.T; CABI0CabiA008008008.der_T = der(CABI0CabiA008008008.T); CABI0CabiA008008008.C * der(CABI0CabiA008008008.T) = CABI0CabiA008008008.port.Q_flow; CABI0CabiA009008008.T = CABI0CabiA009008008.port.T; CABI0CabiA009008008.der_T = der(CABI0CabiA009008008.T); CABI0CabiA009008008.C * der(CABI0CabiA009008008.T) = CABI0CabiA009008008.port.Q_flow; CABI0CabiA010008008.T = CABI0CabiA010008008.port.T; CABI0CabiA010008008.der_T = der(CABI0CabiA010008008.T); CABI0CabiA010008008.C * der(CABI0CabiA010008008.T) = CABI0CabiA010008008.port.Q_flow; CABI0CabiA011008008.T = CABI0CabiA011008008.port.T; CABI0CabiA011008008.der_T = der(CABI0CabiA011008008.T); CABI0CabiA011008008.C * der(CABI0CabiA011008008.T) = CABI0CabiA011008008.port.Q_flow; CABI0CabiA012008008.T = CABI0CabiA012008008.port.T; CABI0CabiA012008008.der_T = der(CABI0CabiA012008008.T); CABI0CabiA012008008.C * der(CABI0CabiA012008008.T) = CABI0CabiA012008008.port.Q_flow; CABI0CabiA013008008.T = CABI0CabiA013008008.port.T; CABI0CabiA013008008.der_T = der(CABI0CabiA013008008.T); CABI0CabiA013008008.C * der(CABI0CabiA013008008.T) = CABI0CabiA013008008.port.Q_flow; CABI0CabiA001009008.T = CABI0CabiA001009008.port.T; CABI0CabiA001009008.der_T = der(CABI0CabiA001009008.T); CABI0CabiA001009008.C * der(CABI0CabiA001009008.T) = CABI0CabiA001009008.port.Q_flow; CABI0CabiA002009008.T = CABI0CabiA002009008.port.T; CABI0CabiA002009008.der_T = der(CABI0CabiA002009008.T); CABI0CabiA002009008.C * der(CABI0CabiA002009008.T) = CABI0CabiA002009008.port.Q_flow; CABI0CabiA003009008.T = CABI0CabiA003009008.port.T; CABI0CabiA003009008.der_T = der(CABI0CabiA003009008.T); CABI0CabiA003009008.C * der(CABI0CabiA003009008.T) = CABI0CabiA003009008.port.Q_flow; CABI0CabiA004009008.T = CABI0CabiA004009008.port.T; CABI0CabiA004009008.der_T = der(CABI0CabiA004009008.T); CABI0CabiA004009008.C * der(CABI0CabiA004009008.T) = CABI0CabiA004009008.port.Q_flow; CABI0CabiA005009008.T = CABI0CabiA005009008.port.T; CABI0CabiA005009008.der_T = der(CABI0CabiA005009008.T); CABI0CabiA005009008.C * der(CABI0CabiA005009008.T) = CABI0CabiA005009008.port.Q_flow; CABI0CabiA006009008.T = CABI0CabiA006009008.port.T; CABI0CabiA006009008.der_T = der(CABI0CabiA006009008.T); CABI0CabiA006009008.C * der(CABI0CabiA006009008.T) = CABI0CabiA006009008.port.Q_flow; CABI0CabiA007009008.T = CABI0CabiA007009008.port.T; CABI0CabiA007009008.der_T = der(CABI0CabiA007009008.T); CABI0CabiA007009008.C * der(CABI0CabiA007009008.T) = CABI0CabiA007009008.port.Q_flow; CABI0CabiA008009008.T = CABI0CabiA008009008.port.T; CABI0CabiA008009008.der_T = der(CABI0CabiA008009008.T); CABI0CabiA008009008.C * der(CABI0CabiA008009008.T) = CABI0CabiA008009008.port.Q_flow; CABI0CabiA009009008.T = CABI0CabiA009009008.port.T; CABI0CabiA009009008.der_T = der(CABI0CabiA009009008.T); CABI0CabiA009009008.C * der(CABI0CabiA009009008.T) = CABI0CabiA009009008.port.Q_flow; CABI0CabiA010009008.T = CABI0CabiA010009008.port.T; CABI0CabiA010009008.der_T = der(CABI0CabiA010009008.T); CABI0CabiA010009008.C * der(CABI0CabiA010009008.T) = CABI0CabiA010009008.port.Q_flow; CABI0CabiA011009008.T = CABI0CabiA011009008.port.T; CABI0CabiA011009008.der_T = der(CABI0CabiA011009008.T); CABI0CabiA011009008.C * der(CABI0CabiA011009008.T) = CABI0CabiA011009008.port.Q_flow; CABI0CabiA012009008.T = CABI0CabiA012009008.port.T; CABI0CabiA012009008.der_T = der(CABI0CabiA012009008.T); CABI0CabiA012009008.C * der(CABI0CabiA012009008.T) = CABI0CabiA012009008.port.Q_flow; CABI0CabiA013009008.T = CABI0CabiA013009008.port.T; CABI0CabiA013009008.der_T = der(CABI0CabiA013009008.T); CABI0CabiA013009008.C * der(CABI0CabiA013009008.T) = CABI0CabiA013009008.port.Q_flow; CABI0CabiA001010008.T = CABI0CabiA001010008.port.T; CABI0CabiA001010008.der_T = der(CABI0CabiA001010008.T); CABI0CabiA001010008.C * der(CABI0CabiA001010008.T) = CABI0CabiA001010008.port.Q_flow; CABI0CabiA002010008.T = CABI0CabiA002010008.port.T; CABI0CabiA002010008.der_T = der(CABI0CabiA002010008.T); CABI0CabiA002010008.C * der(CABI0CabiA002010008.T) = CABI0CabiA002010008.port.Q_flow; CABI0CabiA003010008.T = CABI0CabiA003010008.port.T; CABI0CabiA003010008.der_T = der(CABI0CabiA003010008.T); CABI0CabiA003010008.C * der(CABI0CabiA003010008.T) = CABI0CabiA003010008.port.Q_flow; CABI0CabiA004010008.T = CABI0CabiA004010008.port.T; CABI0CabiA004010008.der_T = der(CABI0CabiA004010008.T); CABI0CabiA004010008.C * der(CABI0CabiA004010008.T) = CABI0CabiA004010008.port.Q_flow; CABI0CabiA005010008.T = CABI0CabiA005010008.port.T; CABI0CabiA005010008.der_T = der(CABI0CabiA005010008.T); CABI0CabiA005010008.C * der(CABI0CabiA005010008.T) = CABI0CabiA005010008.port.Q_flow; CABI0CabiA006010008.T = CABI0CabiA006010008.port.T; CABI0CabiA006010008.der_T = der(CABI0CabiA006010008.T); CABI0CabiA006010008.C * der(CABI0CabiA006010008.T) = CABI0CabiA006010008.port.Q_flow; CABI0CabiA007010008.T = CABI0CabiA007010008.port.T; CABI0CabiA007010008.der_T = der(CABI0CabiA007010008.T); CABI0CabiA007010008.C * der(CABI0CabiA007010008.T) = CABI0CabiA007010008.port.Q_flow; CABI0CabiA008010008.T = CABI0CabiA008010008.port.T; CABI0CabiA008010008.der_T = der(CABI0CabiA008010008.T); CABI0CabiA008010008.C * der(CABI0CabiA008010008.T) = CABI0CabiA008010008.port.Q_flow; CABI0CabiA009010008.T = CABI0CabiA009010008.port.T; CABI0CabiA009010008.der_T = der(CABI0CabiA009010008.T); CABI0CabiA009010008.C * der(CABI0CabiA009010008.T) = CABI0CabiA009010008.port.Q_flow; CABI0CabiA010010008.T = CABI0CabiA010010008.port.T; CABI0CabiA010010008.der_T = der(CABI0CabiA010010008.T); CABI0CabiA010010008.C * der(CABI0CabiA010010008.T) = CABI0CabiA010010008.port.Q_flow; CABI0CabiA011010008.T = CABI0CabiA011010008.port.T; CABI0CabiA011010008.der_T = der(CABI0CabiA011010008.T); CABI0CabiA011010008.C * der(CABI0CabiA011010008.T) = CABI0CabiA011010008.port.Q_flow; CABI0CabiA012010008.T = CABI0CabiA012010008.port.T; CABI0CabiA012010008.der_T = der(CABI0CabiA012010008.T); CABI0CabiA012010008.C * der(CABI0CabiA012010008.T) = CABI0CabiA012010008.port.Q_flow; CABI0CabiA013010008.T = CABI0CabiA013010008.port.T; CABI0CabiA013010008.der_T = der(CABI0CabiA013010008.T); CABI0CabiA013010008.C * der(CABI0CabiA013010008.T) = CABI0CabiA013010008.port.Q_flow; CABI0CabiA001011008.T = CABI0CabiA001011008.port.T; CABI0CabiA001011008.der_T = der(CABI0CabiA001011008.T); CABI0CabiA001011008.C * der(CABI0CabiA001011008.T) = CABI0CabiA001011008.port.Q_flow; CABI0CabiA002011008.T = CABI0CabiA002011008.port.T; CABI0CabiA002011008.der_T = der(CABI0CabiA002011008.T); CABI0CabiA002011008.C * der(CABI0CabiA002011008.T) = CABI0CabiA002011008.port.Q_flow; CABI0CabiA003011008.T = CABI0CabiA003011008.port.T; CABI0CabiA003011008.der_T = der(CABI0CabiA003011008.T); CABI0CabiA003011008.C * der(CABI0CabiA003011008.T) = CABI0CabiA003011008.port.Q_flow; CABI0CabiA004011008.T = CABI0CabiA004011008.port.T; CABI0CabiA004011008.der_T = der(CABI0CabiA004011008.T); CABI0CabiA004011008.C * der(CABI0CabiA004011008.T) = CABI0CabiA004011008.port.Q_flow; CABI0CabiA005011008.T = CABI0CabiA005011008.port.T; CABI0CabiA005011008.der_T = der(CABI0CabiA005011008.T); CABI0CabiA005011008.C * der(CABI0CabiA005011008.T) = CABI0CabiA005011008.port.Q_flow; CABI0CabiA006011008.T = CABI0CabiA006011008.port.T; CABI0CabiA006011008.der_T = der(CABI0CabiA006011008.T); CABI0CabiA006011008.C * der(CABI0CabiA006011008.T) = CABI0CabiA006011008.port.Q_flow; CABI0CabiA007011008.T = CABI0CabiA007011008.port.T; CABI0CabiA007011008.der_T = der(CABI0CabiA007011008.T); CABI0CabiA007011008.C * der(CABI0CabiA007011008.T) = CABI0CabiA007011008.port.Q_flow; CABI0CabiA008011008.T = CABI0CabiA008011008.port.T; CABI0CabiA008011008.der_T = der(CABI0CabiA008011008.T); CABI0CabiA008011008.C * der(CABI0CabiA008011008.T) = CABI0CabiA008011008.port.Q_flow; CABI0CabiA009011008.T = CABI0CabiA009011008.port.T; CABI0CabiA009011008.der_T = der(CABI0CabiA009011008.T); CABI0CabiA009011008.C * der(CABI0CabiA009011008.T) = CABI0CabiA009011008.port.Q_flow; CABI0CabiA010011008.T = CABI0CabiA010011008.port.T; CABI0CabiA010011008.der_T = der(CABI0CabiA010011008.T); CABI0CabiA010011008.C * der(CABI0CabiA010011008.T) = CABI0CabiA010011008.port.Q_flow; CABI0CabiA011011008.T = CABI0CabiA011011008.port.T; CABI0CabiA011011008.der_T = der(CABI0CabiA011011008.T); CABI0CabiA011011008.C * der(CABI0CabiA011011008.T) = CABI0CabiA011011008.port.Q_flow; CABI0CabiA012011008.T = CABI0CabiA012011008.port.T; CABI0CabiA012011008.der_T = der(CABI0CabiA012011008.T); CABI0CabiA012011008.C * der(CABI0CabiA012011008.T) = CABI0CabiA012011008.port.Q_flow; CABI0CabiA013011008.T = CABI0CabiA013011008.port.T; CABI0CabiA013011008.der_T = der(CABI0CabiA013011008.T); CABI0CabiA013011008.C * der(CABI0CabiA013011008.T) = CABI0CabiA013011008.port.Q_flow; CABI0CabiA001012008.T = CABI0CabiA001012008.port.T; CABI0CabiA001012008.der_T = der(CABI0CabiA001012008.T); CABI0CabiA001012008.C * der(CABI0CabiA001012008.T) = CABI0CabiA001012008.port.Q_flow; CABI0CabiA002012008.T = CABI0CabiA002012008.port.T; CABI0CabiA002012008.der_T = der(CABI0CabiA002012008.T); CABI0CabiA002012008.C * der(CABI0CabiA002012008.T) = CABI0CabiA002012008.port.Q_flow; CABI0CabiA003012008.T = CABI0CabiA003012008.port.T; CABI0CabiA003012008.der_T = der(CABI0CabiA003012008.T); CABI0CabiA003012008.C * der(CABI0CabiA003012008.T) = CABI0CabiA003012008.port.Q_flow; CABI0CabiA004012008.T = CABI0CabiA004012008.port.T; CABI0CabiA004012008.der_T = der(CABI0CabiA004012008.T); CABI0CabiA004012008.C * der(CABI0CabiA004012008.T) = CABI0CabiA004012008.port.Q_flow; CABI0CabiA005012008.T = CABI0CabiA005012008.port.T; CABI0CabiA005012008.der_T = der(CABI0CabiA005012008.T); CABI0CabiA005012008.C * der(CABI0CabiA005012008.T) = CABI0CabiA005012008.port.Q_flow; CABI0CabiA006012008.T = CABI0CabiA006012008.port.T; CABI0CabiA006012008.der_T = der(CABI0CabiA006012008.T); CABI0CabiA006012008.C * der(CABI0CabiA006012008.T) = CABI0CabiA006012008.port.Q_flow; CABI0CabiA007012008.T = CABI0CabiA007012008.port.T; CABI0CabiA007012008.der_T = der(CABI0CabiA007012008.T); CABI0CabiA007012008.C * der(CABI0CabiA007012008.T) = CABI0CabiA007012008.port.Q_flow; CABI0CabiA008012008.T = CABI0CabiA008012008.port.T; CABI0CabiA008012008.der_T = der(CABI0CabiA008012008.T); CABI0CabiA008012008.C * der(CABI0CabiA008012008.T) = CABI0CabiA008012008.port.Q_flow; CABI0CabiA009012008.T = CABI0CabiA009012008.port.T; CABI0CabiA009012008.der_T = der(CABI0CabiA009012008.T); CABI0CabiA009012008.C * der(CABI0CabiA009012008.T) = CABI0CabiA009012008.port.Q_flow; CABI0CabiA010012008.T = CABI0CabiA010012008.port.T; CABI0CabiA010012008.der_T = der(CABI0CabiA010012008.T); CABI0CabiA010012008.C * der(CABI0CabiA010012008.T) = CABI0CabiA010012008.port.Q_flow; CABI0CabiA011012008.T = CABI0CabiA011012008.port.T; CABI0CabiA011012008.der_T = der(CABI0CabiA011012008.T); CABI0CabiA011012008.C * der(CABI0CabiA011012008.T) = CABI0CabiA011012008.port.Q_flow; CABI0CabiA012012008.T = CABI0CabiA012012008.port.T; CABI0CabiA012012008.der_T = der(CABI0CabiA012012008.T); CABI0CabiA012012008.C * der(CABI0CabiA012012008.T) = CABI0CabiA012012008.port.Q_flow; CABI0CabiA013012008.T = CABI0CabiA013012008.port.T; CABI0CabiA013012008.der_T = der(CABI0CabiA013012008.T); CABI0CabiA013012008.C * der(CABI0CabiA013012008.T) = CABI0CabiA013012008.port.Q_flow; CABI0CabiA001013008.T = CABI0CabiA001013008.port.T; CABI0CabiA001013008.der_T = der(CABI0CabiA001013008.T); CABI0CabiA001013008.C * der(CABI0CabiA001013008.T) = CABI0CabiA001013008.port.Q_flow; CABI0CabiA002013008.T = CABI0CabiA002013008.port.T; CABI0CabiA002013008.der_T = der(CABI0CabiA002013008.T); CABI0CabiA002013008.C * der(CABI0CabiA002013008.T) = CABI0CabiA002013008.port.Q_flow; CABI0CabiA003013008.T = CABI0CabiA003013008.port.T; CABI0CabiA003013008.der_T = der(CABI0CabiA003013008.T); CABI0CabiA003013008.C * der(CABI0CabiA003013008.T) = CABI0CabiA003013008.port.Q_flow; CABI0CabiA004013008.T = CABI0CabiA004013008.port.T; CABI0CabiA004013008.der_T = der(CABI0CabiA004013008.T); CABI0CabiA004013008.C * der(CABI0CabiA004013008.T) = CABI0CabiA004013008.port.Q_flow; CABI0CabiA005013008.T = CABI0CabiA005013008.port.T; CABI0CabiA005013008.der_T = der(CABI0CabiA005013008.T); CABI0CabiA005013008.C * der(CABI0CabiA005013008.T) = CABI0CabiA005013008.port.Q_flow; CABI0CabiA006013008.T = CABI0CabiA006013008.port.T; CABI0CabiA006013008.der_T = der(CABI0CabiA006013008.T); CABI0CabiA006013008.C * der(CABI0CabiA006013008.T) = CABI0CabiA006013008.port.Q_flow; CABI0CabiA007013008.T = CABI0CabiA007013008.port.T; CABI0CabiA007013008.der_T = der(CABI0CabiA007013008.T); CABI0CabiA007013008.C * der(CABI0CabiA007013008.T) = CABI0CabiA007013008.port.Q_flow; CABI0CabiA008013008.T = CABI0CabiA008013008.port.T; CABI0CabiA008013008.der_T = der(CABI0CabiA008013008.T); CABI0CabiA008013008.C * der(CABI0CabiA008013008.T) = CABI0CabiA008013008.port.Q_flow; CABI0CabiA009013008.T = CABI0CabiA009013008.port.T; CABI0CabiA009013008.der_T = der(CABI0CabiA009013008.T); CABI0CabiA009013008.C * der(CABI0CabiA009013008.T) = CABI0CabiA009013008.port.Q_flow; CABI0CabiA010013008.T = CABI0CabiA010013008.port.T; CABI0CabiA010013008.der_T = der(CABI0CabiA010013008.T); CABI0CabiA010013008.C * der(CABI0CabiA010013008.T) = CABI0CabiA010013008.port.Q_flow; CABI0CabiA011013008.T = CABI0CabiA011013008.port.T; CABI0CabiA011013008.der_T = der(CABI0CabiA011013008.T); CABI0CabiA011013008.C * der(CABI0CabiA011013008.T) = CABI0CabiA011013008.port.Q_flow; CABI0CabiA012013008.T = CABI0CabiA012013008.port.T; CABI0CabiA012013008.der_T = der(CABI0CabiA012013008.T); CABI0CabiA012013008.C * der(CABI0CabiA012013008.T) = CABI0CabiA012013008.port.Q_flow; CABI0CabiA013013008.T = CABI0CabiA013013008.port.T; CABI0CabiA013013008.der_T = der(CABI0CabiA013013008.T); CABI0CabiA013013008.C * der(CABI0CabiA013013008.T) = CABI0CabiA013013008.port.Q_flow; CABI0CabiA001014008.T = CABI0CabiA001014008.port.T; CABI0CabiA001014008.der_T = der(CABI0CabiA001014008.T); CABI0CabiA001014008.C * der(CABI0CabiA001014008.T) = CABI0CabiA001014008.port.Q_flow; CABI0CabiA002014008.T = CABI0CabiA002014008.port.T; CABI0CabiA002014008.der_T = der(CABI0CabiA002014008.T); CABI0CabiA002014008.C * der(CABI0CabiA002014008.T) = CABI0CabiA002014008.port.Q_flow; CABI0CabiA003014008.T = CABI0CabiA003014008.port.T; CABI0CabiA003014008.der_T = der(CABI0CabiA003014008.T); CABI0CabiA003014008.C * der(CABI0CabiA003014008.T) = CABI0CabiA003014008.port.Q_flow; CABI0CabiA004014008.T = CABI0CabiA004014008.port.T; CABI0CabiA004014008.der_T = der(CABI0CabiA004014008.T); CABI0CabiA004014008.C * der(CABI0CabiA004014008.T) = CABI0CabiA004014008.port.Q_flow; CABI0CabiA005014008.T = CABI0CabiA005014008.port.T; CABI0CabiA005014008.der_T = der(CABI0CabiA005014008.T); CABI0CabiA005014008.C * der(CABI0CabiA005014008.T) = CABI0CabiA005014008.port.Q_flow; CABI0CabiA006014008.T = CABI0CabiA006014008.port.T; CABI0CabiA006014008.der_T = der(CABI0CabiA006014008.T); CABI0CabiA006014008.C * der(CABI0CabiA006014008.T) = CABI0CabiA006014008.port.Q_flow; CABI0CabiA007014008.T = CABI0CabiA007014008.port.T; CABI0CabiA007014008.der_T = der(CABI0CabiA007014008.T); CABI0CabiA007014008.C * der(CABI0CabiA007014008.T) = CABI0CabiA007014008.port.Q_flow; CABI0CabiA008014008.T = CABI0CabiA008014008.port.T; CABI0CabiA008014008.der_T = der(CABI0CabiA008014008.T); CABI0CabiA008014008.C * der(CABI0CabiA008014008.T) = CABI0CabiA008014008.port.Q_flow; CABI0CabiA009014008.T = CABI0CabiA009014008.port.T; CABI0CabiA009014008.der_T = der(CABI0CabiA009014008.T); CABI0CabiA009014008.C * der(CABI0CabiA009014008.T) = CABI0CabiA009014008.port.Q_flow; CABI0CabiA010014008.T = CABI0CabiA010014008.port.T; CABI0CabiA010014008.der_T = der(CABI0CabiA010014008.T); CABI0CabiA010014008.C * der(CABI0CabiA010014008.T) = CABI0CabiA010014008.port.Q_flow; CABI0CabiA011014008.T = CABI0CabiA011014008.port.T; CABI0CabiA011014008.der_T = der(CABI0CabiA011014008.T); CABI0CabiA011014008.C * der(CABI0CabiA011014008.T) = CABI0CabiA011014008.port.Q_flow; CABI0CabiA012014008.T = CABI0CabiA012014008.port.T; CABI0CabiA012014008.der_T = der(CABI0CabiA012014008.T); CABI0CabiA012014008.C * der(CABI0CabiA012014008.T) = CABI0CabiA012014008.port.Q_flow; CABI0CabiA013014008.T = CABI0CabiA013014008.port.T; CABI0CabiA013014008.der_T = der(CABI0CabiA013014008.T); CABI0CabiA013014008.C * der(CABI0CabiA013014008.T) = CABI0CabiA013014008.port.Q_flow; CABI0CabiA001015008.T = CABI0CabiA001015008.port.T; CABI0CabiA001015008.der_T = der(CABI0CabiA001015008.T); CABI0CabiA001015008.C * der(CABI0CabiA001015008.T) = CABI0CabiA001015008.port.Q_flow; CABI0CabiA002015008.T = CABI0CabiA002015008.port.T; CABI0CabiA002015008.der_T = der(CABI0CabiA002015008.T); CABI0CabiA002015008.C * der(CABI0CabiA002015008.T) = CABI0CabiA002015008.port.Q_flow; CABI0CabiA003015008.T = CABI0CabiA003015008.port.T; CABI0CabiA003015008.der_T = der(CABI0CabiA003015008.T); CABI0CabiA003015008.C * der(CABI0CabiA003015008.T) = CABI0CabiA003015008.port.Q_flow; CABI0CabiA004015008.T = CABI0CabiA004015008.port.T; CABI0CabiA004015008.der_T = der(CABI0CabiA004015008.T); CABI0CabiA004015008.C * der(CABI0CabiA004015008.T) = CABI0CabiA004015008.port.Q_flow; CABI0CabiA005015008.T = CABI0CabiA005015008.port.T; CABI0CabiA005015008.der_T = der(CABI0CabiA005015008.T); CABI0CabiA005015008.C * der(CABI0CabiA005015008.T) = CABI0CabiA005015008.port.Q_flow; CABI0CabiA006015008.T = CABI0CabiA006015008.port.T; CABI0CabiA006015008.der_T = der(CABI0CabiA006015008.T); CABI0CabiA006015008.C * der(CABI0CabiA006015008.T) = CABI0CabiA006015008.port.Q_flow; CABI0CabiA007015008.T = CABI0CabiA007015008.port.T; CABI0CabiA007015008.der_T = der(CABI0CabiA007015008.T); CABI0CabiA007015008.C * der(CABI0CabiA007015008.T) = CABI0CabiA007015008.port.Q_flow; CABI0CabiA008015008.T = CABI0CabiA008015008.port.T; CABI0CabiA008015008.der_T = der(CABI0CabiA008015008.T); CABI0CabiA008015008.C * der(CABI0CabiA008015008.T) = CABI0CabiA008015008.port.Q_flow; CABI0CabiA009015008.T = CABI0CabiA009015008.port.T; CABI0CabiA009015008.der_T = der(CABI0CabiA009015008.T); CABI0CabiA009015008.C * der(CABI0CabiA009015008.T) = CABI0CabiA009015008.port.Q_flow; CABI0CabiA010015008.T = CABI0CabiA010015008.port.T; CABI0CabiA010015008.der_T = der(CABI0CabiA010015008.T); CABI0CabiA010015008.C * der(CABI0CabiA010015008.T) = CABI0CabiA010015008.port.Q_flow; CABI0CabiA011015008.T = CABI0CabiA011015008.port.T; CABI0CabiA011015008.der_T = der(CABI0CabiA011015008.T); CABI0CabiA011015008.C * der(CABI0CabiA011015008.T) = CABI0CabiA011015008.port.Q_flow; CABI0CabiA012015008.T = CABI0CabiA012015008.port.T; CABI0CabiA012015008.der_T = der(CABI0CabiA012015008.T); CABI0CabiA012015008.C * der(CABI0CabiA012015008.T) = CABI0CabiA012015008.port.Q_flow; CABI0CabiA013015008.T = CABI0CabiA013015008.port.T; CABI0CabiA013015008.der_T = der(CABI0CabiA013015008.T); CABI0CabiA013015008.C * der(CABI0CabiA013015008.T) = CABI0CabiA013015008.port.Q_flow; CABI0CabiA001016008.T = CABI0CabiA001016008.port.T; CABI0CabiA001016008.der_T = der(CABI0CabiA001016008.T); CABI0CabiA001016008.C * der(CABI0CabiA001016008.T) = CABI0CabiA001016008.port.Q_flow; CABI0CabiA002016008.T = CABI0CabiA002016008.port.T; CABI0CabiA002016008.der_T = der(CABI0CabiA002016008.T); CABI0CabiA002016008.C * der(CABI0CabiA002016008.T) = CABI0CabiA002016008.port.Q_flow; CABI0CabiA003016008.T = CABI0CabiA003016008.port.T; CABI0CabiA003016008.der_T = der(CABI0CabiA003016008.T); CABI0CabiA003016008.C * der(CABI0CabiA003016008.T) = CABI0CabiA003016008.port.Q_flow; CABI0CabiA004016008.T = CABI0CabiA004016008.port.T; CABI0CabiA004016008.der_T = der(CABI0CabiA004016008.T); CABI0CabiA004016008.C * der(CABI0CabiA004016008.T) = CABI0CabiA004016008.port.Q_flow; CABI0CabiA005016008.T = CABI0CabiA005016008.port.T; CABI0CabiA005016008.der_T = der(CABI0CabiA005016008.T); CABI0CabiA005016008.C * der(CABI0CabiA005016008.T) = CABI0CabiA005016008.port.Q_flow; CABI0CabiA006016008.T = CABI0CabiA006016008.port.T; CABI0CabiA006016008.der_T = der(CABI0CabiA006016008.T); CABI0CabiA006016008.C * der(CABI0CabiA006016008.T) = CABI0CabiA006016008.port.Q_flow; CABI0CabiA007016008.T = CABI0CabiA007016008.port.T; CABI0CabiA007016008.der_T = der(CABI0CabiA007016008.T); CABI0CabiA007016008.C * der(CABI0CabiA007016008.T) = CABI0CabiA007016008.port.Q_flow; CABI0CabiA008016008.T = CABI0CabiA008016008.port.T; CABI0CabiA008016008.der_T = der(CABI0CabiA008016008.T); CABI0CabiA008016008.C * der(CABI0CabiA008016008.T) = CABI0CabiA008016008.port.Q_flow; CABI0CabiA009016008.T = CABI0CabiA009016008.port.T; CABI0CabiA009016008.der_T = der(CABI0CabiA009016008.T); CABI0CabiA009016008.C * der(CABI0CabiA009016008.T) = CABI0CabiA009016008.port.Q_flow; CABI0CabiA010016008.T = CABI0CabiA010016008.port.T; CABI0CabiA010016008.der_T = der(CABI0CabiA010016008.T); CABI0CabiA010016008.C * der(CABI0CabiA010016008.T) = CABI0CabiA010016008.port.Q_flow; CABI0CabiA011016008.T = CABI0CabiA011016008.port.T; CABI0CabiA011016008.der_T = der(CABI0CabiA011016008.T); CABI0CabiA011016008.C * der(CABI0CabiA011016008.T) = CABI0CabiA011016008.port.Q_flow; CABI0CabiA012016008.T = CABI0CabiA012016008.port.T; CABI0CabiA012016008.der_T = der(CABI0CabiA012016008.T); CABI0CabiA012016008.C * der(CABI0CabiA012016008.T) = CABI0CabiA012016008.port.Q_flow; CABI0CabiA013016008.T = CABI0CabiA013016008.port.T; CABI0CabiA013016008.der_T = der(CABI0CabiA013016008.T); CABI0CabiA013016008.C * der(CABI0CabiA013016008.T) = CABI0CabiA013016008.port.Q_flow; GS0CabiA004005002.T = GS0CabiA004005002.port.T; GS0CabiA004005002.der_T = der(GS0CabiA004005002.T); GS0CabiA004005002.C * der(GS0CabiA004005002.T) = GS0CabiA004005002.port.Q_flow; GS0CabiA005005002.T = GS0CabiA005005002.port.T; GS0CabiA005005002.der_T = der(GS0CabiA005005002.T); GS0CabiA005005002.C * der(GS0CabiA005005002.T) = GS0CabiA005005002.port.Q_flow; GS0CabiA006005002.T = GS0CabiA006005002.port.T; GS0CabiA006005002.der_T = der(GS0CabiA006005002.T); GS0CabiA006005002.C * der(GS0CabiA006005002.T) = GS0CabiA006005002.port.Q_flow; GS0CabiA007005002.T = GS0CabiA007005002.port.T; GS0CabiA007005002.der_T = der(GS0CabiA007005002.T); GS0CabiA007005002.C * der(GS0CabiA007005002.T) = GS0CabiA007005002.port.Q_flow; GS0CabiA008005002.T = GS0CabiA008005002.port.T; GS0CabiA008005002.der_T = der(GS0CabiA008005002.T); GS0CabiA008005002.C * der(GS0CabiA008005002.T) = GS0CabiA008005002.port.Q_flow; GS0CabiA009005002.T = GS0CabiA009005002.port.T; GS0CabiA009005002.der_T = der(GS0CabiA009005002.T); GS0CabiA009005002.C * der(GS0CabiA009005002.T) = GS0CabiA009005002.port.Q_flow; GS0CabiA010005002.T = GS0CabiA010005002.port.T; GS0CabiA010005002.der_T = der(GS0CabiA010005002.T); GS0CabiA010005002.C * der(GS0CabiA010005002.T) = GS0CabiA010005002.port.Q_flow; GS0CabiA011005002.T = GS0CabiA011005002.port.T; GS0CabiA011005002.der_T = der(GS0CabiA011005002.T); GS0CabiA011005002.C * der(GS0CabiA011005002.T) = GS0CabiA011005002.port.Q_flow; GS0CabiA004006002.T = GS0CabiA004006002.port.T; GS0CabiA004006002.der_T = der(GS0CabiA004006002.T); GS0CabiA004006002.C * der(GS0CabiA004006002.T) = GS0CabiA004006002.port.Q_flow; GS0CabiA005006002.T = GS0CabiA005006002.port.T; GS0CabiA005006002.der_T = der(GS0CabiA005006002.T); GS0CabiA005006002.C * der(GS0CabiA005006002.T) = GS0CabiA005006002.port.Q_flow; GS0CabiA006006002.T = GS0CabiA006006002.port.T; GS0CabiA006006002.der_T = der(GS0CabiA006006002.T); GS0CabiA006006002.C * der(GS0CabiA006006002.T) = GS0CabiA006006002.port.Q_flow; GS0CabiA007006002.T = GS0CabiA007006002.port.T; GS0CabiA007006002.der_T = der(GS0CabiA007006002.T); GS0CabiA007006002.C * der(GS0CabiA007006002.T) = GS0CabiA007006002.port.Q_flow; GS0CabiA008006002.T = GS0CabiA008006002.port.T; GS0CabiA008006002.der_T = der(GS0CabiA008006002.T); GS0CabiA008006002.C * der(GS0CabiA008006002.T) = GS0CabiA008006002.port.Q_flow; GS0CabiA009006002.T = GS0CabiA009006002.port.T; GS0CabiA009006002.der_T = der(GS0CabiA009006002.T); GS0CabiA009006002.C * der(GS0CabiA009006002.T) = GS0CabiA009006002.port.Q_flow; GS0CabiA010006002.T = GS0CabiA010006002.port.T; GS0CabiA010006002.der_T = der(GS0CabiA010006002.T); GS0CabiA010006002.C * der(GS0CabiA010006002.T) = GS0CabiA010006002.port.Q_flow; GS0CabiA011006002.T = GS0CabiA011006002.port.T; GS0CabiA011006002.der_T = der(GS0CabiA011006002.T); GS0CabiA011006002.C * der(GS0CabiA011006002.T) = GS0CabiA011006002.port.Q_flow; GS0CabiA004007002.T = GS0CabiA004007002.port.T; GS0CabiA004007002.der_T = der(GS0CabiA004007002.T); GS0CabiA004007002.C * der(GS0CabiA004007002.T) = GS0CabiA004007002.port.Q_flow; GS0CabiA005007002.T = GS0CabiA005007002.port.T; GS0CabiA005007002.der_T = der(GS0CabiA005007002.T); GS0CabiA005007002.C * der(GS0CabiA005007002.T) = GS0CabiA005007002.port.Q_flow; GS0CabiA006007002.T = GS0CabiA006007002.port.T; GS0CabiA006007002.der_T = der(GS0CabiA006007002.T); GS0CabiA006007002.C * der(GS0CabiA006007002.T) = GS0CabiA006007002.port.Q_flow; GS0CabiA007007002.T = GS0CabiA007007002.port.T; GS0CabiA007007002.der_T = der(GS0CabiA007007002.T); GS0CabiA007007002.C * der(GS0CabiA007007002.T) = GS0CabiA007007002.port.Q_flow; GS0CabiA008007002.T = GS0CabiA008007002.port.T; GS0CabiA008007002.der_T = der(GS0CabiA008007002.T); GS0CabiA008007002.C * der(GS0CabiA008007002.T) = GS0CabiA008007002.port.Q_flow; GS0CabiA009007002.T = GS0CabiA009007002.port.T; GS0CabiA009007002.der_T = der(GS0CabiA009007002.T); GS0CabiA009007002.C * der(GS0CabiA009007002.T) = GS0CabiA009007002.port.Q_flow; GS0CabiA010007002.T = GS0CabiA010007002.port.T; GS0CabiA010007002.der_T = der(GS0CabiA010007002.T); GS0CabiA010007002.C * der(GS0CabiA010007002.T) = GS0CabiA010007002.port.Q_flow; GS0CabiA011007002.T = GS0CabiA011007002.port.T; GS0CabiA011007002.der_T = der(GS0CabiA011007002.T); GS0CabiA011007002.C * der(GS0CabiA011007002.T) = GS0CabiA011007002.port.Q_flow; GS0CabiA004008002.T = GS0CabiA004008002.port.T; GS0CabiA004008002.der_T = der(GS0CabiA004008002.T); GS0CabiA004008002.C * der(GS0CabiA004008002.T) = GS0CabiA004008002.port.Q_flow; GS0CabiA005008002.T = GS0CabiA005008002.port.T; GS0CabiA005008002.der_T = der(GS0CabiA005008002.T); GS0CabiA005008002.C * der(GS0CabiA005008002.T) = GS0CabiA005008002.port.Q_flow; GS0CabiA006008002.T = GS0CabiA006008002.port.T; GS0CabiA006008002.der_T = der(GS0CabiA006008002.T); GS0CabiA006008002.C * der(GS0CabiA006008002.T) = GS0CabiA006008002.port.Q_flow; GS0CabiA007008002.T = GS0CabiA007008002.port.T; GS0CabiA007008002.der_T = der(GS0CabiA007008002.T); GS0CabiA007008002.C * der(GS0CabiA007008002.T) = GS0CabiA007008002.port.Q_flow; GS0CabiA008008002.T = GS0CabiA008008002.port.T; GS0CabiA008008002.der_T = der(GS0CabiA008008002.T); GS0CabiA008008002.C * der(GS0CabiA008008002.T) = GS0CabiA008008002.port.Q_flow; GS0CabiA009008002.T = GS0CabiA009008002.port.T; GS0CabiA009008002.der_T = der(GS0CabiA009008002.T); GS0CabiA009008002.C * der(GS0CabiA009008002.T) = GS0CabiA009008002.port.Q_flow; GS0CabiA010008002.T = GS0CabiA010008002.port.T; GS0CabiA010008002.der_T = der(GS0CabiA010008002.T); GS0CabiA010008002.C * der(GS0CabiA010008002.T) = GS0CabiA010008002.port.Q_flow; GS0CabiA011008002.T = GS0CabiA011008002.port.T; GS0CabiA011008002.der_T = der(GS0CabiA011008002.T); GS0CabiA011008002.C * der(GS0CabiA011008002.T) = GS0CabiA011008002.port.Q_flow; GS0CabiA004009002.T = GS0CabiA004009002.port.T; GS0CabiA004009002.der_T = der(GS0CabiA004009002.T); GS0CabiA004009002.C * der(GS0CabiA004009002.T) = GS0CabiA004009002.port.Q_flow; GS0CabiA005009002.T = GS0CabiA005009002.port.T; GS0CabiA005009002.der_T = der(GS0CabiA005009002.T); GS0CabiA005009002.C * der(GS0CabiA005009002.T) = GS0CabiA005009002.port.Q_flow; GS0CabiA006009002.T = GS0CabiA006009002.port.T; GS0CabiA006009002.der_T = der(GS0CabiA006009002.T); GS0CabiA006009002.C * der(GS0CabiA006009002.T) = GS0CabiA006009002.port.Q_flow; GS0CabiA007009002.T = GS0CabiA007009002.port.T; GS0CabiA007009002.der_T = der(GS0CabiA007009002.T); GS0CabiA007009002.C * der(GS0CabiA007009002.T) = GS0CabiA007009002.port.Q_flow; GS0CabiA008009002.T = GS0CabiA008009002.port.T; GS0CabiA008009002.der_T = der(GS0CabiA008009002.T); GS0CabiA008009002.C * der(GS0CabiA008009002.T) = GS0CabiA008009002.port.Q_flow; GS0CabiA009009002.T = GS0CabiA009009002.port.T; GS0CabiA009009002.der_T = der(GS0CabiA009009002.T); GS0CabiA009009002.C * der(GS0CabiA009009002.T) = GS0CabiA009009002.port.Q_flow; GS0CabiA010009002.T = GS0CabiA010009002.port.T; GS0CabiA010009002.der_T = der(GS0CabiA010009002.T); GS0CabiA010009002.C * der(GS0CabiA010009002.T) = GS0CabiA010009002.port.Q_flow; GS0CabiA011009002.T = GS0CabiA011009002.port.T; GS0CabiA011009002.der_T = der(GS0CabiA011009002.T); GS0CabiA011009002.C * der(GS0CabiA011009002.T) = GS0CabiA011009002.port.Q_flow; GS0CabiA004010002.T = GS0CabiA004010002.port.T; GS0CabiA004010002.der_T = der(GS0CabiA004010002.T); GS0CabiA004010002.C * der(GS0CabiA004010002.T) = GS0CabiA004010002.port.Q_flow; GS0CabiA005010002.T = GS0CabiA005010002.port.T; GS0CabiA005010002.der_T = der(GS0CabiA005010002.T); GS0CabiA005010002.C * der(GS0CabiA005010002.T) = GS0CabiA005010002.port.Q_flow; GS0CabiA006010002.T = GS0CabiA006010002.port.T; GS0CabiA006010002.der_T = der(GS0CabiA006010002.T); GS0CabiA006010002.C * der(GS0CabiA006010002.T) = GS0CabiA006010002.port.Q_flow; GS0CabiA007010002.T = GS0CabiA007010002.port.T; GS0CabiA007010002.der_T = der(GS0CabiA007010002.T); GS0CabiA007010002.C * der(GS0CabiA007010002.T) = GS0CabiA007010002.port.Q_flow; GS0CabiA008010002.T = GS0CabiA008010002.port.T; GS0CabiA008010002.der_T = der(GS0CabiA008010002.T); GS0CabiA008010002.C * der(GS0CabiA008010002.T) = GS0CabiA008010002.port.Q_flow; GS0CabiA009010002.T = GS0CabiA009010002.port.T; GS0CabiA009010002.der_T = der(GS0CabiA009010002.T); GS0CabiA009010002.C * der(GS0CabiA009010002.T) = GS0CabiA009010002.port.Q_flow; GS0CabiA010010002.T = GS0CabiA010010002.port.T; GS0CabiA010010002.der_T = der(GS0CabiA010010002.T); GS0CabiA010010002.C * der(GS0CabiA010010002.T) = GS0CabiA010010002.port.Q_flow; GS0CabiA011010002.T = GS0CabiA011010002.port.T; GS0CabiA011010002.der_T = der(GS0CabiA011010002.T); GS0CabiA011010002.C * der(GS0CabiA011010002.T) = GS0CabiA011010002.port.Q_flow; GS0CabiA004011002.T = GS0CabiA004011002.port.T; GS0CabiA004011002.der_T = der(GS0CabiA004011002.T); GS0CabiA004011002.C * der(GS0CabiA004011002.T) = GS0CabiA004011002.port.Q_flow; GS0CabiA005011002.T = GS0CabiA005011002.port.T; GS0CabiA005011002.der_T = der(GS0CabiA005011002.T); GS0CabiA005011002.C * der(GS0CabiA005011002.T) = GS0CabiA005011002.port.Q_flow; GS0CabiA006011002.T = GS0CabiA006011002.port.T; GS0CabiA006011002.der_T = der(GS0CabiA006011002.T); GS0CabiA006011002.C * der(GS0CabiA006011002.T) = GS0CabiA006011002.port.Q_flow; GS0CabiA007011002.T = GS0CabiA007011002.port.T; GS0CabiA007011002.der_T = der(GS0CabiA007011002.T); GS0CabiA007011002.C * der(GS0CabiA007011002.T) = GS0CabiA007011002.port.Q_flow; GS0CabiA008011002.T = GS0CabiA008011002.port.T; GS0CabiA008011002.der_T = der(GS0CabiA008011002.T); GS0CabiA008011002.C * der(GS0CabiA008011002.T) = GS0CabiA008011002.port.Q_flow; GS0CabiA009011002.T = GS0CabiA009011002.port.T; GS0CabiA009011002.der_T = der(GS0CabiA009011002.T); GS0CabiA009011002.C * der(GS0CabiA009011002.T) = GS0CabiA009011002.port.Q_flow; GS0CabiA010011002.T = GS0CabiA010011002.port.T; GS0CabiA010011002.der_T = der(GS0CabiA010011002.T); GS0CabiA010011002.C * der(GS0CabiA010011002.T) = GS0CabiA010011002.port.Q_flow; GS0CabiA011011002.T = GS0CabiA011011002.port.T; GS0CabiA011011002.der_T = der(GS0CabiA011011002.T); GS0CabiA011011002.C * der(GS0CabiA011011002.T) = GS0CabiA011011002.port.Q_flow; GS0CabiA004012002.T = GS0CabiA004012002.port.T; GS0CabiA004012002.der_T = der(GS0CabiA004012002.T); GS0CabiA004012002.C * der(GS0CabiA004012002.T) = GS0CabiA004012002.port.Q_flow; GS0CabiA005012002.T = GS0CabiA005012002.port.T; GS0CabiA005012002.der_T = der(GS0CabiA005012002.T); GS0CabiA005012002.C * der(GS0CabiA005012002.T) = GS0CabiA005012002.port.Q_flow; GS0CabiA006012002.T = GS0CabiA006012002.port.T; GS0CabiA006012002.der_T = der(GS0CabiA006012002.T); GS0CabiA006012002.C * der(GS0CabiA006012002.T) = GS0CabiA006012002.port.Q_flow; GS0CabiA007012002.T = GS0CabiA007012002.port.T; GS0CabiA007012002.der_T = der(GS0CabiA007012002.T); GS0CabiA007012002.C * der(GS0CabiA007012002.T) = GS0CabiA007012002.port.Q_flow; GS0CabiA008012002.T = GS0CabiA008012002.port.T; GS0CabiA008012002.der_T = der(GS0CabiA008012002.T); GS0CabiA008012002.C * der(GS0CabiA008012002.T) = GS0CabiA008012002.port.Q_flow; GS0CabiA009012002.T = GS0CabiA009012002.port.T; GS0CabiA009012002.der_T = der(GS0CabiA009012002.T); GS0CabiA009012002.C * der(GS0CabiA009012002.T) = GS0CabiA009012002.port.Q_flow; GS0CabiA010012002.T = GS0CabiA010012002.port.T; GS0CabiA010012002.der_T = der(GS0CabiA010012002.T); GS0CabiA010012002.C * der(GS0CabiA010012002.T) = GS0CabiA010012002.port.Q_flow; GS0CabiA011012002.T = GS0CabiA011012002.port.T; GS0CabiA011012002.der_T = der(GS0CabiA011012002.T); GS0CabiA011012002.C * der(GS0CabiA011012002.T) = GS0CabiA011012002.port.Q_flow; GS0CabiA004013002.T = GS0CabiA004013002.port.T; GS0CabiA004013002.der_T = der(GS0CabiA004013002.T); GS0CabiA004013002.C * der(GS0CabiA004013002.T) = GS0CabiA004013002.port.Q_flow; GS0CabiA005013002.T = GS0CabiA005013002.port.T; GS0CabiA005013002.der_T = der(GS0CabiA005013002.T); GS0CabiA005013002.C * der(GS0CabiA005013002.T) = GS0CabiA005013002.port.Q_flow; GS0CabiA006013002.T = GS0CabiA006013002.port.T; GS0CabiA006013002.der_T = der(GS0CabiA006013002.T); GS0CabiA006013002.C * der(GS0CabiA006013002.T) = GS0CabiA006013002.port.Q_flow; GS0CabiA007013002.T = GS0CabiA007013002.port.T; GS0CabiA007013002.der_T = der(GS0CabiA007013002.T); GS0CabiA007013002.C * der(GS0CabiA007013002.T) = GS0CabiA007013002.port.Q_flow; GS0CabiA008013002.T = GS0CabiA008013002.port.T; GS0CabiA008013002.der_T = der(GS0CabiA008013002.T); GS0CabiA008013002.C * der(GS0CabiA008013002.T) = GS0CabiA008013002.port.Q_flow; GS0CabiA009013002.T = GS0CabiA009013002.port.T; GS0CabiA009013002.der_T = der(GS0CabiA009013002.T); GS0CabiA009013002.C * der(GS0CabiA009013002.T) = GS0CabiA009013002.port.Q_flow; GS0CabiA010013002.T = GS0CabiA010013002.port.T; GS0CabiA010013002.der_T = der(GS0CabiA010013002.T); GS0CabiA010013002.C * der(GS0CabiA010013002.T) = GS0CabiA010013002.port.Q_flow; GS0CabiA011013002.T = GS0CabiA011013002.port.T; GS0CabiA011013002.der_T = der(GS0CabiA011013002.T); GS0CabiA011013002.C * der(GS0CabiA011013002.T) = GS0CabiA011013002.port.Q_flow; GS0CabiA004004002.T = GS0CabiA004004002.port.T; GS0CabiA004004002.der_T = der(GS0CabiA004004002.T); GS0CabiA004004002.C * der(GS0CabiA004004002.T) = GS0CabiA004004002.port.Q_flow; GS0CabiA005004002.T = GS0CabiA005004002.port.T; GS0CabiA005004002.der_T = der(GS0CabiA005004002.T); GS0CabiA005004002.C * der(GS0CabiA005004002.T) = GS0CabiA005004002.port.Q_flow; GS0CabiA006004002.T = GS0CabiA006004002.port.T; GS0CabiA006004002.der_T = der(GS0CabiA006004002.T); GS0CabiA006004002.C * der(GS0CabiA006004002.T) = GS0CabiA006004002.port.Q_flow; GS0CabiA007004002.T = GS0CabiA007004002.port.T; GS0CabiA007004002.der_T = der(GS0CabiA007004002.T); GS0CabiA007004002.C * der(GS0CabiA007004002.T) = GS0CabiA007004002.port.Q_flow; GS0CabiA008004002.T = GS0CabiA008004002.port.T; GS0CabiA008004002.der_T = der(GS0CabiA008004002.T); GS0CabiA008004002.C * der(GS0CabiA008004002.T) = GS0CabiA008004002.port.Q_flow; GS0CabiA009004002.T = GS0CabiA009004002.port.T; GS0CabiA009004002.der_T = der(GS0CabiA009004002.T); GS0CabiA009004002.C * der(GS0CabiA009004002.T) = GS0CabiA009004002.port.Q_flow; GS0CabiA010004002.T = GS0CabiA010004002.port.T; GS0CabiA010004002.der_T = der(GS0CabiA010004002.T); GS0CabiA010004002.C * der(GS0CabiA010004002.T) = GS0CabiA010004002.port.Q_flow; GS0CabiA011004002.T = GS0CabiA011004002.port.T; GS0CabiA011004002.der_T = der(GS0CabiA011004002.T); GS0CabiA011004002.C * der(GS0CabiA011004002.T) = GS0CabiA011004002.port.Q_flow; AIR0CabiA002015007.T = AIR0CabiA002015007.port.T; AIR0CabiA002015007.der_T = der(AIR0CabiA002015007.T); AIR0CabiA002015007.C * der(AIR0CabiA002015007.T) = AIR0CabiA002015007.port.Q_flow; AIR0CabiA003015007.T = AIR0CabiA003015007.port.T; AIR0CabiA003015007.der_T = der(AIR0CabiA003015007.T); AIR0CabiA003015007.C * der(AIR0CabiA003015007.T) = AIR0CabiA003015007.port.Q_flow; AIR0CabiA004015007.T = AIR0CabiA004015007.port.T; AIR0CabiA004015007.der_T = der(AIR0CabiA004015007.T); AIR0CabiA004015007.C * der(AIR0CabiA004015007.T) = AIR0CabiA004015007.port.Q_flow; AIR0CabiA005015007.T = AIR0CabiA005015007.port.T; AIR0CabiA005015007.der_T = der(AIR0CabiA005015007.T); AIR0CabiA005015007.C * der(AIR0CabiA005015007.T) = AIR0CabiA005015007.port.Q_flow; AIR0CabiA006015007.T = AIR0CabiA006015007.port.T; AIR0CabiA006015007.der_T = der(AIR0CabiA006015007.T); AIR0CabiA006015007.C * der(AIR0CabiA006015007.T) = AIR0CabiA006015007.port.Q_flow; AIR0CabiA007015007.T = AIR0CabiA007015007.port.T; AIR0CabiA007015007.der_T = der(AIR0CabiA007015007.T); AIR0CabiA007015007.C * der(AIR0CabiA007015007.T) = AIR0CabiA007015007.port.Q_flow; AIR0CabiA008015007.T = AIR0CabiA008015007.port.T; AIR0CabiA008015007.der_T = der(AIR0CabiA008015007.T); AIR0CabiA008015007.C * der(AIR0CabiA008015007.T) = AIR0CabiA008015007.port.Q_flow; AIR0CabiA009015007.T = AIR0CabiA009015007.port.T; AIR0CabiA009015007.der_T = der(AIR0CabiA009015007.T); AIR0CabiA009015007.C * der(AIR0CabiA009015007.T) = AIR0CabiA009015007.port.Q_flow; AIR0CabiA010015007.T = AIR0CabiA010015007.port.T; AIR0CabiA010015007.der_T = der(AIR0CabiA010015007.T); AIR0CabiA010015007.C * der(AIR0CabiA010015007.T) = AIR0CabiA010015007.port.Q_flow; AIR0CabiA011015007.T = AIR0CabiA011015007.port.T; AIR0CabiA011015007.der_T = der(AIR0CabiA011015007.T); AIR0CabiA011015007.C * der(AIR0CabiA011015007.T) = AIR0CabiA011015007.port.Q_flow; AIR0CabiA012015007.T = AIR0CabiA012015007.port.T; AIR0CabiA012015007.der_T = der(AIR0CabiA012015007.T); AIR0CabiA012015007.C * der(AIR0CabiA012015007.T) = AIR0CabiA012015007.port.Q_flow; AIR0CabiA002014007.T = AIR0CabiA002014007.port.T; AIR0CabiA002014007.der_T = der(AIR0CabiA002014007.T); AIR0CabiA002014007.C * der(AIR0CabiA002014007.T) = AIR0CabiA002014007.port.Q_flow; AIR0CabiA003014007.T = AIR0CabiA003014007.port.T; AIR0CabiA003014007.der_T = der(AIR0CabiA003014007.T); AIR0CabiA003014007.C * der(AIR0CabiA003014007.T) = AIR0CabiA003014007.port.Q_flow; AIR0CabiA004014007.T = AIR0CabiA004014007.port.T; AIR0CabiA004014007.der_T = der(AIR0CabiA004014007.T); AIR0CabiA004014007.C * der(AIR0CabiA004014007.T) = AIR0CabiA004014007.port.Q_flow; AIR0CabiA005014007.T = AIR0CabiA005014007.port.T; AIR0CabiA005014007.der_T = der(AIR0CabiA005014007.T); AIR0CabiA005014007.C * der(AIR0CabiA005014007.T) = AIR0CabiA005014007.port.Q_flow; AIR0CabiA006014007.T = AIR0CabiA006014007.port.T; AIR0CabiA006014007.der_T = der(AIR0CabiA006014007.T); AIR0CabiA006014007.C * der(AIR0CabiA006014007.T) = AIR0CabiA006014007.port.Q_flow; AIR0CabiA007014007.T = AIR0CabiA007014007.port.T; AIR0CabiA007014007.der_T = der(AIR0CabiA007014007.T); AIR0CabiA007014007.C * der(AIR0CabiA007014007.T) = AIR0CabiA007014007.port.Q_flow; AIR0CabiA008014007.T = AIR0CabiA008014007.port.T; AIR0CabiA008014007.der_T = der(AIR0CabiA008014007.T); AIR0CabiA008014007.C * der(AIR0CabiA008014007.T) = AIR0CabiA008014007.port.Q_flow; AIR0CabiA009014007.T = AIR0CabiA009014007.port.T; AIR0CabiA009014007.der_T = der(AIR0CabiA009014007.T); AIR0CabiA009014007.C * der(AIR0CabiA009014007.T) = AIR0CabiA009014007.port.Q_flow; AIR0CabiA010014007.T = AIR0CabiA010014007.port.T; AIR0CabiA010014007.der_T = der(AIR0CabiA010014007.T); AIR0CabiA010014007.C * der(AIR0CabiA010014007.T) = AIR0CabiA010014007.port.Q_flow; AIR0CabiA011014007.T = AIR0CabiA011014007.port.T; AIR0CabiA011014007.der_T = der(AIR0CabiA011014007.T); AIR0CabiA011014007.C * der(AIR0CabiA011014007.T) = AIR0CabiA011014007.port.Q_flow; AIR0CabiA012014007.T = AIR0CabiA012014007.port.T; AIR0CabiA012014007.der_T = der(AIR0CabiA012014007.T); AIR0CabiA012014007.C * der(AIR0CabiA012014007.T) = AIR0CabiA012014007.port.Q_flow; AIR0CabiA002007007.T = AIR0CabiA002007007.port.T; AIR0CabiA002007007.der_T = der(AIR0CabiA002007007.T); AIR0CabiA002007007.C * der(AIR0CabiA002007007.T) = AIR0CabiA002007007.port.Q_flow; AIR0CabiA003007007.T = AIR0CabiA003007007.port.T; AIR0CabiA003007007.der_T = der(AIR0CabiA003007007.T); AIR0CabiA003007007.C * der(AIR0CabiA003007007.T) = AIR0CabiA003007007.port.Q_flow; AIR0CabiA004007007.T = AIR0CabiA004007007.port.T; AIR0CabiA004007007.der_T = der(AIR0CabiA004007007.T); AIR0CabiA004007007.C * der(AIR0CabiA004007007.T) = AIR0CabiA004007007.port.Q_flow; AIR0CabiA005007007.T = AIR0CabiA005007007.port.T; AIR0CabiA005007007.der_T = der(AIR0CabiA005007007.T); AIR0CabiA005007007.C * der(AIR0CabiA005007007.T) = AIR0CabiA005007007.port.Q_flow; AIR0CabiA006007007.T = AIR0CabiA006007007.port.T; AIR0CabiA006007007.der_T = der(AIR0CabiA006007007.T); AIR0CabiA006007007.C * der(AIR0CabiA006007007.T) = AIR0CabiA006007007.port.Q_flow; AIR0CabiA007007007.T = AIR0CabiA007007007.port.T; AIR0CabiA007007007.der_T = der(AIR0CabiA007007007.T); AIR0CabiA007007007.C * der(AIR0CabiA007007007.T) = AIR0CabiA007007007.port.Q_flow; AIR0CabiA008007007.T = AIR0CabiA008007007.port.T; AIR0CabiA008007007.der_T = der(AIR0CabiA008007007.T); AIR0CabiA008007007.C * der(AIR0CabiA008007007.T) = AIR0CabiA008007007.port.Q_flow; AIR0CabiA009007007.T = AIR0CabiA009007007.port.T; AIR0CabiA009007007.der_T = der(AIR0CabiA009007007.T); AIR0CabiA009007007.C * der(AIR0CabiA009007007.T) = AIR0CabiA009007007.port.Q_flow; AIR0CabiA010007007.T = AIR0CabiA010007007.port.T; AIR0CabiA010007007.der_T = der(AIR0CabiA010007007.T); AIR0CabiA010007007.C * der(AIR0CabiA010007007.T) = AIR0CabiA010007007.port.Q_flow; AIR0CabiA011007007.T = AIR0CabiA011007007.port.T; AIR0CabiA011007007.der_T = der(AIR0CabiA011007007.T); AIR0CabiA011007007.C * der(AIR0CabiA011007007.T) = AIR0CabiA011007007.port.Q_flow; AIR0CabiA012007007.T = AIR0CabiA012007007.port.T; AIR0CabiA012007007.der_T = der(AIR0CabiA012007007.T); AIR0CabiA012007007.C * der(AIR0CabiA012007007.T) = AIR0CabiA012007007.port.Q_flow; AIR0CabiA002008007.T = AIR0CabiA002008007.port.T; AIR0CabiA002008007.der_T = der(AIR0CabiA002008007.T); AIR0CabiA002008007.C * der(AIR0CabiA002008007.T) = AIR0CabiA002008007.port.Q_flow; AIR0CabiA003008007.T = AIR0CabiA003008007.port.T; AIR0CabiA003008007.der_T = der(AIR0CabiA003008007.T); AIR0CabiA003008007.C * der(AIR0CabiA003008007.T) = AIR0CabiA003008007.port.Q_flow; AIR0CabiA004008007.T = AIR0CabiA004008007.port.T; AIR0CabiA004008007.der_T = der(AIR0CabiA004008007.T); AIR0CabiA004008007.C * der(AIR0CabiA004008007.T) = AIR0CabiA004008007.port.Q_flow; AIR0CabiA005008007.T = AIR0CabiA005008007.port.T; AIR0CabiA005008007.der_T = der(AIR0CabiA005008007.T); AIR0CabiA005008007.C * der(AIR0CabiA005008007.T) = AIR0CabiA005008007.port.Q_flow; AIR0CabiA006008007.T = AIR0CabiA006008007.port.T; AIR0CabiA006008007.der_T = der(AIR0CabiA006008007.T); AIR0CabiA006008007.C * der(AIR0CabiA006008007.T) = AIR0CabiA006008007.port.Q_flow; AIR0CabiA007008007.T = AIR0CabiA007008007.port.T; AIR0CabiA007008007.der_T = der(AIR0CabiA007008007.T); AIR0CabiA007008007.C * der(AIR0CabiA007008007.T) = AIR0CabiA007008007.port.Q_flow; AIR0CabiA008008007.T = AIR0CabiA008008007.port.T; AIR0CabiA008008007.der_T = der(AIR0CabiA008008007.T); AIR0CabiA008008007.C * der(AIR0CabiA008008007.T) = AIR0CabiA008008007.port.Q_flow; AIR0CabiA009008007.T = AIR0CabiA009008007.port.T; AIR0CabiA009008007.der_T = der(AIR0CabiA009008007.T); AIR0CabiA009008007.C * der(AIR0CabiA009008007.T) = AIR0CabiA009008007.port.Q_flow; AIR0CabiA010008007.T = AIR0CabiA010008007.port.T; AIR0CabiA010008007.der_T = der(AIR0CabiA010008007.T); AIR0CabiA010008007.C * der(AIR0CabiA010008007.T) = AIR0CabiA010008007.port.Q_flow; AIR0CabiA011008007.T = AIR0CabiA011008007.port.T; AIR0CabiA011008007.der_T = der(AIR0CabiA011008007.T); AIR0CabiA011008007.C * der(AIR0CabiA011008007.T) = AIR0CabiA011008007.port.Q_flow; AIR0CabiA012008007.T = AIR0CabiA012008007.port.T; AIR0CabiA012008007.der_T = der(AIR0CabiA012008007.T); AIR0CabiA012008007.C * der(AIR0CabiA012008007.T) = AIR0CabiA012008007.port.Q_flow; AIR0CabiA002009007.T = AIR0CabiA002009007.port.T; AIR0CabiA002009007.der_T = der(AIR0CabiA002009007.T); AIR0CabiA002009007.C * der(AIR0CabiA002009007.T) = AIR0CabiA002009007.port.Q_flow; AIR0CabiA003009007.T = AIR0CabiA003009007.port.T; AIR0CabiA003009007.der_T = der(AIR0CabiA003009007.T); AIR0CabiA003009007.C * der(AIR0CabiA003009007.T) = AIR0CabiA003009007.port.Q_flow; AIR0CabiA004009007.T = AIR0CabiA004009007.port.T; AIR0CabiA004009007.der_T = der(AIR0CabiA004009007.T); AIR0CabiA004009007.C * der(AIR0CabiA004009007.T) = AIR0CabiA004009007.port.Q_flow; AIR0CabiA005009007.T = AIR0CabiA005009007.port.T; AIR0CabiA005009007.der_T = der(AIR0CabiA005009007.T); AIR0CabiA005009007.C * der(AIR0CabiA005009007.T) = AIR0CabiA005009007.port.Q_flow; AIR0CabiA006009007.T = AIR0CabiA006009007.port.T; AIR0CabiA006009007.der_T = der(AIR0CabiA006009007.T); AIR0CabiA006009007.C * der(AIR0CabiA006009007.T) = AIR0CabiA006009007.port.Q_flow; AIR0CabiA007009007.T = AIR0CabiA007009007.port.T; AIR0CabiA007009007.der_T = der(AIR0CabiA007009007.T); AIR0CabiA007009007.C * der(AIR0CabiA007009007.T) = AIR0CabiA007009007.port.Q_flow; AIR0CabiA008009007.T = AIR0CabiA008009007.port.T; AIR0CabiA008009007.der_T = der(AIR0CabiA008009007.T); AIR0CabiA008009007.C * der(AIR0CabiA008009007.T) = AIR0CabiA008009007.port.Q_flow; AIR0CabiA009009007.T = AIR0CabiA009009007.port.T; AIR0CabiA009009007.der_T = der(AIR0CabiA009009007.T); AIR0CabiA009009007.C * der(AIR0CabiA009009007.T) = AIR0CabiA009009007.port.Q_flow; AIR0CabiA010009007.T = AIR0CabiA010009007.port.T; AIR0CabiA010009007.der_T = der(AIR0CabiA010009007.T); AIR0CabiA010009007.C * der(AIR0CabiA010009007.T) = AIR0CabiA010009007.port.Q_flow; AIR0CabiA011009007.T = AIR0CabiA011009007.port.T; AIR0CabiA011009007.der_T = der(AIR0CabiA011009007.T); AIR0CabiA011009007.C * der(AIR0CabiA011009007.T) = AIR0CabiA011009007.port.Q_flow; AIR0CabiA012009007.T = AIR0CabiA012009007.port.T; AIR0CabiA012009007.der_T = der(AIR0CabiA012009007.T); AIR0CabiA012009007.C * der(AIR0CabiA012009007.T) = AIR0CabiA012009007.port.Q_flow; AIR0CabiA002010007.T = AIR0CabiA002010007.port.T; AIR0CabiA002010007.der_T = der(AIR0CabiA002010007.T); AIR0CabiA002010007.C * der(AIR0CabiA002010007.T) = AIR0CabiA002010007.port.Q_flow; AIR0CabiA003010007.T = AIR0CabiA003010007.port.T; AIR0CabiA003010007.der_T = der(AIR0CabiA003010007.T); AIR0CabiA003010007.C * der(AIR0CabiA003010007.T) = AIR0CabiA003010007.port.Q_flow; AIR0CabiA004010007.T = AIR0CabiA004010007.port.T; AIR0CabiA004010007.der_T = der(AIR0CabiA004010007.T); AIR0CabiA004010007.C * der(AIR0CabiA004010007.T) = AIR0CabiA004010007.port.Q_flow; AIR0CabiA005010007.T = AIR0CabiA005010007.port.T; AIR0CabiA005010007.der_T = der(AIR0CabiA005010007.T); AIR0CabiA005010007.C * der(AIR0CabiA005010007.T) = AIR0CabiA005010007.port.Q_flow; AIR0CabiA006010007.T = AIR0CabiA006010007.port.T; AIR0CabiA006010007.der_T = der(AIR0CabiA006010007.T); AIR0CabiA006010007.C * der(AIR0CabiA006010007.T) = AIR0CabiA006010007.port.Q_flow; AIR0CabiA007010007.T = AIR0CabiA007010007.port.T; AIR0CabiA007010007.der_T = der(AIR0CabiA007010007.T); AIR0CabiA007010007.C * der(AIR0CabiA007010007.T) = AIR0CabiA007010007.port.Q_flow; AIR0CabiA008010007.T = AIR0CabiA008010007.port.T; AIR0CabiA008010007.der_T = der(AIR0CabiA008010007.T); AIR0CabiA008010007.C * der(AIR0CabiA008010007.T) = AIR0CabiA008010007.port.Q_flow; AIR0CabiA009010007.T = AIR0CabiA009010007.port.T; AIR0CabiA009010007.der_T = der(AIR0CabiA009010007.T); AIR0CabiA009010007.C * der(AIR0CabiA009010007.T) = AIR0CabiA009010007.port.Q_flow; AIR0CabiA010010007.T = AIR0CabiA010010007.port.T; AIR0CabiA010010007.der_T = der(AIR0CabiA010010007.T); AIR0CabiA010010007.C * der(AIR0CabiA010010007.T) = AIR0CabiA010010007.port.Q_flow; AIR0CabiA011010007.T = AIR0CabiA011010007.port.T; AIR0CabiA011010007.der_T = der(AIR0CabiA011010007.T); AIR0CabiA011010007.C * der(AIR0CabiA011010007.T) = AIR0CabiA011010007.port.Q_flow; AIR0CabiA012010007.T = AIR0CabiA012010007.port.T; AIR0CabiA012010007.der_T = der(AIR0CabiA012010007.T); AIR0CabiA012010007.C * der(AIR0CabiA012010007.T) = AIR0CabiA012010007.port.Q_flow; AIR0CabiA002011007.T = AIR0CabiA002011007.port.T; AIR0CabiA002011007.der_T = der(AIR0CabiA002011007.T); AIR0CabiA002011007.C * der(AIR0CabiA002011007.T) = AIR0CabiA002011007.port.Q_flow; AIR0CabiA003011007.T = AIR0CabiA003011007.port.T; AIR0CabiA003011007.der_T = der(AIR0CabiA003011007.T); AIR0CabiA003011007.C * der(AIR0CabiA003011007.T) = AIR0CabiA003011007.port.Q_flow; AIR0CabiA004011007.T = AIR0CabiA004011007.port.T; AIR0CabiA004011007.der_T = der(AIR0CabiA004011007.T); AIR0CabiA004011007.C * der(AIR0CabiA004011007.T) = AIR0CabiA004011007.port.Q_flow; AIR0CabiA005011007.T = AIR0CabiA005011007.port.T; AIR0CabiA005011007.der_T = der(AIR0CabiA005011007.T); AIR0CabiA005011007.C * der(AIR0CabiA005011007.T) = AIR0CabiA005011007.port.Q_flow; AIR0CabiA006011007.T = AIR0CabiA006011007.port.T; AIR0CabiA006011007.der_T = der(AIR0CabiA006011007.T); AIR0CabiA006011007.C * der(AIR0CabiA006011007.T) = AIR0CabiA006011007.port.Q_flow; AIR0CabiA007011007.T = AIR0CabiA007011007.port.T; AIR0CabiA007011007.der_T = der(AIR0CabiA007011007.T); AIR0CabiA007011007.C * der(AIR0CabiA007011007.T) = AIR0CabiA007011007.port.Q_flow; AIR0CabiA008011007.T = AIR0CabiA008011007.port.T; AIR0CabiA008011007.der_T = der(AIR0CabiA008011007.T); AIR0CabiA008011007.C * der(AIR0CabiA008011007.T) = AIR0CabiA008011007.port.Q_flow; AIR0CabiA009011007.T = AIR0CabiA009011007.port.T; AIR0CabiA009011007.der_T = der(AIR0CabiA009011007.T); AIR0CabiA009011007.C * der(AIR0CabiA009011007.T) = AIR0CabiA009011007.port.Q_flow; AIR0CabiA010011007.T = AIR0CabiA010011007.port.T; AIR0CabiA010011007.der_T = der(AIR0CabiA010011007.T); AIR0CabiA010011007.C * der(AIR0CabiA010011007.T) = AIR0CabiA010011007.port.Q_flow; AIR0CabiA011011007.T = AIR0CabiA011011007.port.T; AIR0CabiA011011007.der_T = der(AIR0CabiA011011007.T); AIR0CabiA011011007.C * der(AIR0CabiA011011007.T) = AIR0CabiA011011007.port.Q_flow; AIR0CabiA012011007.T = AIR0CabiA012011007.port.T; AIR0CabiA012011007.der_T = der(AIR0CabiA012011007.T); AIR0CabiA012011007.C * der(AIR0CabiA012011007.T) = AIR0CabiA012011007.port.Q_flow; AIR0CabiA002012007.T = AIR0CabiA002012007.port.T; AIR0CabiA002012007.der_T = der(AIR0CabiA002012007.T); AIR0CabiA002012007.C * der(AIR0CabiA002012007.T) = AIR0CabiA002012007.port.Q_flow; AIR0CabiA003012007.T = AIR0CabiA003012007.port.T; AIR0CabiA003012007.der_T = der(AIR0CabiA003012007.T); AIR0CabiA003012007.C * der(AIR0CabiA003012007.T) = AIR0CabiA003012007.port.Q_flow; AIR0CabiA004012007.T = AIR0CabiA004012007.port.T; AIR0CabiA004012007.der_T = der(AIR0CabiA004012007.T); AIR0CabiA004012007.C * der(AIR0CabiA004012007.T) = AIR0CabiA004012007.port.Q_flow; AIR0CabiA005012007.T = AIR0CabiA005012007.port.T; AIR0CabiA005012007.der_T = der(AIR0CabiA005012007.T); AIR0CabiA005012007.C * der(AIR0CabiA005012007.T) = AIR0CabiA005012007.port.Q_flow; AIR0CabiA006012007.T = AIR0CabiA006012007.port.T; AIR0CabiA006012007.der_T = der(AIR0CabiA006012007.T); AIR0CabiA006012007.C * der(AIR0CabiA006012007.T) = AIR0CabiA006012007.port.Q_flow; AIR0CabiA007012007.T = AIR0CabiA007012007.port.T; AIR0CabiA007012007.der_T = der(AIR0CabiA007012007.T); AIR0CabiA007012007.C * der(AIR0CabiA007012007.T) = AIR0CabiA007012007.port.Q_flow; AIR0CabiA008012007.T = AIR0CabiA008012007.port.T; AIR0CabiA008012007.der_T = der(AIR0CabiA008012007.T); AIR0CabiA008012007.C * der(AIR0CabiA008012007.T) = AIR0CabiA008012007.port.Q_flow; AIR0CabiA009012007.T = AIR0CabiA009012007.port.T; AIR0CabiA009012007.der_T = der(AIR0CabiA009012007.T); AIR0CabiA009012007.C * der(AIR0CabiA009012007.T) = AIR0CabiA009012007.port.Q_flow; AIR0CabiA010012007.T = AIR0CabiA010012007.port.T; AIR0CabiA010012007.der_T = der(AIR0CabiA010012007.T); AIR0CabiA010012007.C * der(AIR0CabiA010012007.T) = AIR0CabiA010012007.port.Q_flow; AIR0CabiA011012007.T = AIR0CabiA011012007.port.T; AIR0CabiA011012007.der_T = der(AIR0CabiA011012007.T); AIR0CabiA011012007.C * der(AIR0CabiA011012007.T) = AIR0CabiA011012007.port.Q_flow; AIR0CabiA012012007.T = AIR0CabiA012012007.port.T; AIR0CabiA012012007.der_T = der(AIR0CabiA012012007.T); AIR0CabiA012012007.C * der(AIR0CabiA012012007.T) = AIR0CabiA012012007.port.Q_flow; AIR0CabiA002013007.T = AIR0CabiA002013007.port.T; AIR0CabiA002013007.der_T = der(AIR0CabiA002013007.T); AIR0CabiA002013007.C * der(AIR0CabiA002013007.T) = AIR0CabiA002013007.port.Q_flow; AIR0CabiA003013007.T = AIR0CabiA003013007.port.T; AIR0CabiA003013007.der_T = der(AIR0CabiA003013007.T); AIR0CabiA003013007.C * der(AIR0CabiA003013007.T) = AIR0CabiA003013007.port.Q_flow; AIR0CabiA004013007.T = AIR0CabiA004013007.port.T; AIR0CabiA004013007.der_T = der(AIR0CabiA004013007.T); AIR0CabiA004013007.C * der(AIR0CabiA004013007.T) = AIR0CabiA004013007.port.Q_flow; AIR0CabiA005013007.T = AIR0CabiA005013007.port.T; AIR0CabiA005013007.der_T = der(AIR0CabiA005013007.T); AIR0CabiA005013007.C * der(AIR0CabiA005013007.T) = AIR0CabiA005013007.port.Q_flow; AIR0CabiA006013007.T = AIR0CabiA006013007.port.T; AIR0CabiA006013007.der_T = der(AIR0CabiA006013007.T); AIR0CabiA006013007.C * der(AIR0CabiA006013007.T) = AIR0CabiA006013007.port.Q_flow; AIR0CabiA007013007.T = AIR0CabiA007013007.port.T; AIR0CabiA007013007.der_T = der(AIR0CabiA007013007.T); AIR0CabiA007013007.C * der(AIR0CabiA007013007.T) = AIR0CabiA007013007.port.Q_flow; AIR0CabiA008013007.T = AIR0CabiA008013007.port.T; AIR0CabiA008013007.der_T = der(AIR0CabiA008013007.T); AIR0CabiA008013007.C * der(AIR0CabiA008013007.T) = AIR0CabiA008013007.port.Q_flow; AIR0CabiA009013007.T = AIR0CabiA009013007.port.T; AIR0CabiA009013007.der_T = der(AIR0CabiA009013007.T); AIR0CabiA009013007.C * der(AIR0CabiA009013007.T) = AIR0CabiA009013007.port.Q_flow; AIR0CabiA010013007.T = AIR0CabiA010013007.port.T; AIR0CabiA010013007.der_T = der(AIR0CabiA010013007.T); AIR0CabiA010013007.C * der(AIR0CabiA010013007.T) = AIR0CabiA010013007.port.Q_flow; AIR0CabiA011013007.T = AIR0CabiA011013007.port.T; AIR0CabiA011013007.der_T = der(AIR0CabiA011013007.T); AIR0CabiA011013007.C * der(AIR0CabiA011013007.T) = AIR0CabiA011013007.port.Q_flow; AIR0CabiA012013007.T = AIR0CabiA012013007.port.T; AIR0CabiA012013007.der_T = der(AIR0CabiA012013007.T); AIR0CabiA012013007.C * der(AIR0CabiA012013007.T) = AIR0CabiA012013007.port.Q_flow; AIR0CabiA002002007.T = AIR0CabiA002002007.port.T; AIR0CabiA002002007.der_T = der(AIR0CabiA002002007.T); AIR0CabiA002002007.C * der(AIR0CabiA002002007.T) = AIR0CabiA002002007.port.Q_flow; AIR0CabiA003002007.T = AIR0CabiA003002007.port.T; AIR0CabiA003002007.der_T = der(AIR0CabiA003002007.T); AIR0CabiA003002007.C * der(AIR0CabiA003002007.T) = AIR0CabiA003002007.port.Q_flow; AIR0CabiA004002007.T = AIR0CabiA004002007.port.T; AIR0CabiA004002007.der_T = der(AIR0CabiA004002007.T); AIR0CabiA004002007.C * der(AIR0CabiA004002007.T) = AIR0CabiA004002007.port.Q_flow; AIR0CabiA005002007.T = AIR0CabiA005002007.port.T; AIR0CabiA005002007.der_T = der(AIR0CabiA005002007.T); AIR0CabiA005002007.C * der(AIR0CabiA005002007.T) = AIR0CabiA005002007.port.Q_flow; AIR0CabiA006002007.T = AIR0CabiA006002007.port.T; AIR0CabiA006002007.der_T = der(AIR0CabiA006002007.T); AIR0CabiA006002007.C * der(AIR0CabiA006002007.T) = AIR0CabiA006002007.port.Q_flow; AIR0CabiA007002007.T = AIR0CabiA007002007.port.T; AIR0CabiA007002007.der_T = der(AIR0CabiA007002007.T); AIR0CabiA007002007.C * der(AIR0CabiA007002007.T) = AIR0CabiA007002007.port.Q_flow; AIR0CabiA008002007.T = AIR0CabiA008002007.port.T; AIR0CabiA008002007.der_T = der(AIR0CabiA008002007.T); AIR0CabiA008002007.C * der(AIR0CabiA008002007.T) = AIR0CabiA008002007.port.Q_flow; AIR0CabiA009002007.T = AIR0CabiA009002007.port.T; AIR0CabiA009002007.der_T = der(AIR0CabiA009002007.T); AIR0CabiA009002007.C * der(AIR0CabiA009002007.T) = AIR0CabiA009002007.port.Q_flow; AIR0CabiA010002007.T = AIR0CabiA010002007.port.T; AIR0CabiA010002007.der_T = der(AIR0CabiA010002007.T); AIR0CabiA010002007.C * der(AIR0CabiA010002007.T) = AIR0CabiA010002007.port.Q_flow; AIR0CabiA011002007.T = AIR0CabiA011002007.port.T; AIR0CabiA011002007.der_T = der(AIR0CabiA011002007.T); AIR0CabiA011002007.C * der(AIR0CabiA011002007.T) = AIR0CabiA011002007.port.Q_flow; AIR0CabiA012002007.T = AIR0CabiA012002007.port.T; AIR0CabiA012002007.der_T = der(AIR0CabiA012002007.T); AIR0CabiA012002007.C * der(AIR0CabiA012002007.T) = AIR0CabiA012002007.port.Q_flow; AIR0CabiA002003007.T = AIR0CabiA002003007.port.T; AIR0CabiA002003007.der_T = der(AIR0CabiA002003007.T); AIR0CabiA002003007.C * der(AIR0CabiA002003007.T) = AIR0CabiA002003007.port.Q_flow; AIR0CabiA003003007.T = AIR0CabiA003003007.port.T; AIR0CabiA003003007.der_T = der(AIR0CabiA003003007.T); AIR0CabiA003003007.C * der(AIR0CabiA003003007.T) = AIR0CabiA003003007.port.Q_flow; AIR0CabiA004003007.T = AIR0CabiA004003007.port.T; AIR0CabiA004003007.der_T = der(AIR0CabiA004003007.T); AIR0CabiA004003007.C * der(AIR0CabiA004003007.T) = AIR0CabiA004003007.port.Q_flow; AIR0CabiA005003007.T = AIR0CabiA005003007.port.T; AIR0CabiA005003007.der_T = der(AIR0CabiA005003007.T); AIR0CabiA005003007.C * der(AIR0CabiA005003007.T) = AIR0CabiA005003007.port.Q_flow; AIR0CabiA006003007.T = AIR0CabiA006003007.port.T; AIR0CabiA006003007.der_T = der(AIR0CabiA006003007.T); AIR0CabiA006003007.C * der(AIR0CabiA006003007.T) = AIR0CabiA006003007.port.Q_flow; AIR0CabiA007003007.T = AIR0CabiA007003007.port.T; AIR0CabiA007003007.der_T = der(AIR0CabiA007003007.T); AIR0CabiA007003007.C * der(AIR0CabiA007003007.T) = AIR0CabiA007003007.port.Q_flow; AIR0CabiA008003007.T = AIR0CabiA008003007.port.T; AIR0CabiA008003007.der_T = der(AIR0CabiA008003007.T); AIR0CabiA008003007.C * der(AIR0CabiA008003007.T) = AIR0CabiA008003007.port.Q_flow; AIR0CabiA009003007.T = AIR0CabiA009003007.port.T; AIR0CabiA009003007.der_T = der(AIR0CabiA009003007.T); AIR0CabiA009003007.C * der(AIR0CabiA009003007.T) = AIR0CabiA009003007.port.Q_flow; AIR0CabiA010003007.T = AIR0CabiA010003007.port.T; AIR0CabiA010003007.der_T = der(AIR0CabiA010003007.T); AIR0CabiA010003007.C * der(AIR0CabiA010003007.T) = AIR0CabiA010003007.port.Q_flow; AIR0CabiA011003007.T = AIR0CabiA011003007.port.T; AIR0CabiA011003007.der_T = der(AIR0CabiA011003007.T); AIR0CabiA011003007.C * der(AIR0CabiA011003007.T) = AIR0CabiA011003007.port.Q_flow; AIR0CabiA012003007.T = AIR0CabiA012003007.port.T; AIR0CabiA012003007.der_T = der(AIR0CabiA012003007.T); AIR0CabiA012003007.C * der(AIR0CabiA012003007.T) = AIR0CabiA012003007.port.Q_flow; AIR0CabiA002004007.T = AIR0CabiA002004007.port.T; AIR0CabiA002004007.der_T = der(AIR0CabiA002004007.T); AIR0CabiA002004007.C * der(AIR0CabiA002004007.T) = AIR0CabiA002004007.port.Q_flow; AIR0CabiA003004007.T = AIR0CabiA003004007.port.T; AIR0CabiA003004007.der_T = der(AIR0CabiA003004007.T); AIR0CabiA003004007.C * der(AIR0CabiA003004007.T) = AIR0CabiA003004007.port.Q_flow; AIR0CabiA004004007.T = AIR0CabiA004004007.port.T; AIR0CabiA004004007.der_T = der(AIR0CabiA004004007.T); AIR0CabiA004004007.C * der(AIR0CabiA004004007.T) = AIR0CabiA004004007.port.Q_flow; AIR0CabiA005004007.T = AIR0CabiA005004007.port.T; AIR0CabiA005004007.der_T = der(AIR0CabiA005004007.T); AIR0CabiA005004007.C * der(AIR0CabiA005004007.T) = AIR0CabiA005004007.port.Q_flow; AIR0CabiA006004007.T = AIR0CabiA006004007.port.T; AIR0CabiA006004007.der_T = der(AIR0CabiA006004007.T); AIR0CabiA006004007.C * der(AIR0CabiA006004007.T) = AIR0CabiA006004007.port.Q_flow; AIR0CabiA007004007.T = AIR0CabiA007004007.port.T; AIR0CabiA007004007.der_T = der(AIR0CabiA007004007.T); AIR0CabiA007004007.C * der(AIR0CabiA007004007.T) = AIR0CabiA007004007.port.Q_flow; AIR0CabiA008004007.T = AIR0CabiA008004007.port.T; AIR0CabiA008004007.der_T = der(AIR0CabiA008004007.T); AIR0CabiA008004007.C * der(AIR0CabiA008004007.T) = AIR0CabiA008004007.port.Q_flow; AIR0CabiA009004007.T = AIR0CabiA009004007.port.T; AIR0CabiA009004007.der_T = der(AIR0CabiA009004007.T); AIR0CabiA009004007.C * der(AIR0CabiA009004007.T) = AIR0CabiA009004007.port.Q_flow; AIR0CabiA010004007.T = AIR0CabiA010004007.port.T; AIR0CabiA010004007.der_T = der(AIR0CabiA010004007.T); AIR0CabiA010004007.C * der(AIR0CabiA010004007.T) = AIR0CabiA010004007.port.Q_flow; AIR0CabiA011004007.T = AIR0CabiA011004007.port.T; AIR0CabiA011004007.der_T = der(AIR0CabiA011004007.T); AIR0CabiA011004007.C * der(AIR0CabiA011004007.T) = AIR0CabiA011004007.port.Q_flow; AIR0CabiA012004007.T = AIR0CabiA012004007.port.T; AIR0CabiA012004007.der_T = der(AIR0CabiA012004007.T); AIR0CabiA012004007.C * der(AIR0CabiA012004007.T) = AIR0CabiA012004007.port.Q_flow; AIR0CabiA002005007.T = AIR0CabiA002005007.port.T; AIR0CabiA002005007.der_T = der(AIR0CabiA002005007.T); AIR0CabiA002005007.C * der(AIR0CabiA002005007.T) = AIR0CabiA002005007.port.Q_flow; AIR0CabiA003005007.T = AIR0CabiA003005007.port.T; AIR0CabiA003005007.der_T = der(AIR0CabiA003005007.T); AIR0CabiA003005007.C * der(AIR0CabiA003005007.T) = AIR0CabiA003005007.port.Q_flow; AIR0CabiA004005007.T = AIR0CabiA004005007.port.T; AIR0CabiA004005007.der_T = der(AIR0CabiA004005007.T); AIR0CabiA004005007.C * der(AIR0CabiA004005007.T) = AIR0CabiA004005007.port.Q_flow; AIR0CabiA005005007.T = AIR0CabiA005005007.port.T; AIR0CabiA005005007.der_T = der(AIR0CabiA005005007.T); AIR0CabiA005005007.C * der(AIR0CabiA005005007.T) = AIR0CabiA005005007.port.Q_flow; AIR0CabiA006005007.T = AIR0CabiA006005007.port.T; AIR0CabiA006005007.der_T = der(AIR0CabiA006005007.T); AIR0CabiA006005007.C * der(AIR0CabiA006005007.T) = AIR0CabiA006005007.port.Q_flow; AIR0CabiA007005007.T = AIR0CabiA007005007.port.T; AIR0CabiA007005007.der_T = der(AIR0CabiA007005007.T); AIR0CabiA007005007.C * der(AIR0CabiA007005007.T) = AIR0CabiA007005007.port.Q_flow; AIR0CabiA008005007.T = AIR0CabiA008005007.port.T; AIR0CabiA008005007.der_T = der(AIR0CabiA008005007.T); AIR0CabiA008005007.C * der(AIR0CabiA008005007.T) = AIR0CabiA008005007.port.Q_flow; AIR0CabiA009005007.T = AIR0CabiA009005007.port.T; AIR0CabiA009005007.der_T = der(AIR0CabiA009005007.T); AIR0CabiA009005007.C * der(AIR0CabiA009005007.T) = AIR0CabiA009005007.port.Q_flow; AIR0CabiA010005007.T = AIR0CabiA010005007.port.T; AIR0CabiA010005007.der_T = der(AIR0CabiA010005007.T); AIR0CabiA010005007.C * der(AIR0CabiA010005007.T) = AIR0CabiA010005007.port.Q_flow; AIR0CabiA011005007.T = AIR0CabiA011005007.port.T; AIR0CabiA011005007.der_T = der(AIR0CabiA011005007.T); AIR0CabiA011005007.C * der(AIR0CabiA011005007.T) = AIR0CabiA011005007.port.Q_flow; AIR0CabiA012005007.T = AIR0CabiA012005007.port.T; AIR0CabiA012005007.der_T = der(AIR0CabiA012005007.T); AIR0CabiA012005007.C * der(AIR0CabiA012005007.T) = AIR0CabiA012005007.port.Q_flow; AIR0CabiA002006007.T = AIR0CabiA002006007.port.T; AIR0CabiA002006007.der_T = der(AIR0CabiA002006007.T); AIR0CabiA002006007.C * der(AIR0CabiA002006007.T) = AIR0CabiA002006007.port.Q_flow; AIR0CabiA003006007.T = AIR0CabiA003006007.port.T; AIR0CabiA003006007.der_T = der(AIR0CabiA003006007.T); AIR0CabiA003006007.C * der(AIR0CabiA003006007.T) = AIR0CabiA003006007.port.Q_flow; AIR0CabiA004006007.T = AIR0CabiA004006007.port.T; AIR0CabiA004006007.der_T = der(AIR0CabiA004006007.T); AIR0CabiA004006007.C * der(AIR0CabiA004006007.T) = AIR0CabiA004006007.port.Q_flow; AIR0CabiA005006007.T = AIR0CabiA005006007.port.T; AIR0CabiA005006007.der_T = der(AIR0CabiA005006007.T); AIR0CabiA005006007.C * der(AIR0CabiA005006007.T) = AIR0CabiA005006007.port.Q_flow; AIR0CabiA006006007.T = AIR0CabiA006006007.port.T; AIR0CabiA006006007.der_T = der(AIR0CabiA006006007.T); AIR0CabiA006006007.C * der(AIR0CabiA006006007.T) = AIR0CabiA006006007.port.Q_flow; AIR0CabiA007006007.T = AIR0CabiA007006007.port.T; AIR0CabiA007006007.der_T = der(AIR0CabiA007006007.T); AIR0CabiA007006007.C * der(AIR0CabiA007006007.T) = AIR0CabiA007006007.port.Q_flow; AIR0CabiA008006007.T = AIR0CabiA008006007.port.T; AIR0CabiA008006007.der_T = der(AIR0CabiA008006007.T); AIR0CabiA008006007.C * der(AIR0CabiA008006007.T) = AIR0CabiA008006007.port.Q_flow; AIR0CabiA009006007.T = AIR0CabiA009006007.port.T; AIR0CabiA009006007.der_T = der(AIR0CabiA009006007.T); AIR0CabiA009006007.C * der(AIR0CabiA009006007.T) = AIR0CabiA009006007.port.Q_flow; AIR0CabiA010006007.T = AIR0CabiA010006007.port.T; AIR0CabiA010006007.der_T = der(AIR0CabiA010006007.T); AIR0CabiA010006007.C * der(AIR0CabiA010006007.T) = AIR0CabiA010006007.port.Q_flow; AIR0CabiA011006007.T = AIR0CabiA011006007.port.T; AIR0CabiA011006007.der_T = der(AIR0CabiA011006007.T); AIR0CabiA011006007.C * der(AIR0CabiA011006007.T) = AIR0CabiA011006007.port.Q_flow; AIR0CabiA012006007.T = AIR0CabiA012006007.port.T; AIR0CabiA012006007.der_T = der(AIR0CabiA012006007.T); AIR0CabiA012006007.C * der(AIR0CabiA012006007.T) = AIR0CabiA012006007.port.Q_flow; AIR0CabiA011009006.T = AIR0CabiA011009006.port.T; AIR0CabiA011009006.der_T = der(AIR0CabiA011009006.T); AIR0CabiA011009006.C * der(AIR0CabiA011009006.T) = AIR0CabiA011009006.port.Q_flow; AIR0CabiA012009006.T = AIR0CabiA012009006.port.T; AIR0CabiA012009006.der_T = der(AIR0CabiA012009006.T); AIR0CabiA012009006.C * der(AIR0CabiA012009006.T) = AIR0CabiA012009006.port.Q_flow; AIR0CabiA002010006.T = AIR0CabiA002010006.port.T; AIR0CabiA002010006.der_T = der(AIR0CabiA002010006.T); AIR0CabiA002010006.C * der(AIR0CabiA002010006.T) = AIR0CabiA002010006.port.Q_flow; AIR0CabiA003010006.T = AIR0CabiA003010006.port.T; AIR0CabiA003010006.der_T = der(AIR0CabiA003010006.T); AIR0CabiA003010006.C * der(AIR0CabiA003010006.T) = AIR0CabiA003010006.port.Q_flow; AIR0CabiA004010006.T = AIR0CabiA004010006.port.T; AIR0CabiA004010006.der_T = der(AIR0CabiA004010006.T); AIR0CabiA004010006.C * der(AIR0CabiA004010006.T) = AIR0CabiA004010006.port.Q_flow; AIR0CabiA005010006.T = AIR0CabiA005010006.port.T; AIR0CabiA005010006.der_T = der(AIR0CabiA005010006.T); AIR0CabiA005010006.C * der(AIR0CabiA005010006.T) = AIR0CabiA005010006.port.Q_flow; AIR0CabiA006010006.T = AIR0CabiA006010006.port.T; AIR0CabiA006010006.der_T = der(AIR0CabiA006010006.T); AIR0CabiA006010006.C * der(AIR0CabiA006010006.T) = AIR0CabiA006010006.port.Q_flow; AIR0CabiA007010006.T = AIR0CabiA007010006.port.T; AIR0CabiA007010006.der_T = der(AIR0CabiA007010006.T); AIR0CabiA007010006.C * der(AIR0CabiA007010006.T) = AIR0CabiA007010006.port.Q_flow; AIR0CabiA011010006.T = AIR0CabiA011010006.port.T; AIR0CabiA011010006.der_T = der(AIR0CabiA011010006.T); AIR0CabiA011010006.C * der(AIR0CabiA011010006.T) = AIR0CabiA011010006.port.Q_flow; AIR0CabiA012010006.T = AIR0CabiA012010006.port.T; AIR0CabiA012010006.der_T = der(AIR0CabiA012010006.T); AIR0CabiA012010006.C * der(AIR0CabiA012010006.T) = AIR0CabiA012010006.port.Q_flow; AIR0CabiA002011006.T = AIR0CabiA002011006.port.T; AIR0CabiA002011006.der_T = der(AIR0CabiA002011006.T); AIR0CabiA002011006.C * der(AIR0CabiA002011006.T) = AIR0CabiA002011006.port.Q_flow; AIR0CabiA003011006.T = AIR0CabiA003011006.port.T; AIR0CabiA003011006.der_T = der(AIR0CabiA003011006.T); AIR0CabiA003011006.C * der(AIR0CabiA003011006.T) = AIR0CabiA003011006.port.Q_flow; AIR0CabiA007011006.T = AIR0CabiA007011006.port.T; AIR0CabiA007011006.der_T = der(AIR0CabiA007011006.T); AIR0CabiA007011006.C * der(AIR0CabiA007011006.T) = AIR0CabiA007011006.port.Q_flow; AIR0CabiA011011006.T = AIR0CabiA011011006.port.T; AIR0CabiA011011006.der_T = der(AIR0CabiA011011006.T); AIR0CabiA011011006.C * der(AIR0CabiA011011006.T) = AIR0CabiA011011006.port.Q_flow; AIR0CabiA012011006.T = AIR0CabiA012011006.port.T; AIR0CabiA012011006.der_T = der(AIR0CabiA012011006.T); AIR0CabiA012011006.C * der(AIR0CabiA012011006.T) = AIR0CabiA012011006.port.Q_flow; AIR0CabiA002012006.T = AIR0CabiA002012006.port.T; AIR0CabiA002012006.der_T = der(AIR0CabiA002012006.T); AIR0CabiA002012006.C * der(AIR0CabiA002012006.T) = AIR0CabiA002012006.port.Q_flow; AIR0CabiA003012006.T = AIR0CabiA003012006.port.T; AIR0CabiA003012006.der_T = der(AIR0CabiA003012006.T); AIR0CabiA003012006.C * der(AIR0CabiA003012006.T) = AIR0CabiA003012006.port.Q_flow; AIR0CabiA007012006.T = AIR0CabiA007012006.port.T; AIR0CabiA007012006.der_T = der(AIR0CabiA007012006.T); AIR0CabiA007012006.C * der(AIR0CabiA007012006.T) = AIR0CabiA007012006.port.Q_flow; AIR0CabiA008012006.T = AIR0CabiA008012006.port.T; AIR0CabiA008012006.der_T = der(AIR0CabiA008012006.T); AIR0CabiA008012006.C * der(AIR0CabiA008012006.T) = AIR0CabiA008012006.port.Q_flow; AIR0CabiA009012006.T = AIR0CabiA009012006.port.T; AIR0CabiA009012006.der_T = der(AIR0CabiA009012006.T); AIR0CabiA009012006.C * der(AIR0CabiA009012006.T) = AIR0CabiA009012006.port.Q_flow; AIR0CabiA010012006.T = AIR0CabiA010012006.port.T; AIR0CabiA010012006.der_T = der(AIR0CabiA010012006.T); AIR0CabiA010012006.C * der(AIR0CabiA010012006.T) = AIR0CabiA010012006.port.Q_flow; AIR0CabiA011012006.T = AIR0CabiA011012006.port.T; AIR0CabiA011012006.der_T = der(AIR0CabiA011012006.T); AIR0CabiA011012006.C * der(AIR0CabiA011012006.T) = AIR0CabiA011012006.port.Q_flow; AIR0CabiA012012006.T = AIR0CabiA012012006.port.T; AIR0CabiA012012006.der_T = der(AIR0CabiA012012006.T); AIR0CabiA012012006.C * der(AIR0CabiA012012006.T) = AIR0CabiA012012006.port.Q_flow; AIR0CabiA002013006.T = AIR0CabiA002013006.port.T; AIR0CabiA002013006.der_T = der(AIR0CabiA002013006.T); AIR0CabiA002013006.C * der(AIR0CabiA002013006.T) = AIR0CabiA002013006.port.Q_flow; AIR0CabiA003013006.T = AIR0CabiA003013006.port.T; AIR0CabiA003013006.der_T = der(AIR0CabiA003013006.T); AIR0CabiA003013006.C * der(AIR0CabiA003013006.T) = AIR0CabiA003013006.port.Q_flow; AIR0CabiA007013006.T = AIR0CabiA007013006.port.T; AIR0CabiA007013006.der_T = der(AIR0CabiA007013006.T); AIR0CabiA007013006.C * der(AIR0CabiA007013006.T) = AIR0CabiA007013006.port.Q_flow; AIR0CabiA008013006.T = AIR0CabiA008013006.port.T; AIR0CabiA008013006.der_T = der(AIR0CabiA008013006.T); AIR0CabiA008013006.C * der(AIR0CabiA008013006.T) = AIR0CabiA008013006.port.Q_flow; AIR0CabiA009013006.T = AIR0CabiA009013006.port.T; AIR0CabiA009013006.der_T = der(AIR0CabiA009013006.T); AIR0CabiA009013006.C * der(AIR0CabiA009013006.T) = AIR0CabiA009013006.port.Q_flow; AIR0CabiA010013006.T = AIR0CabiA010013006.port.T; AIR0CabiA010013006.der_T = der(AIR0CabiA010013006.T); AIR0CabiA010013006.C * der(AIR0CabiA010013006.T) = AIR0CabiA010013006.port.Q_flow; AIR0CabiA011013006.T = AIR0CabiA011013006.port.T; AIR0CabiA011013006.der_T = der(AIR0CabiA011013006.T); AIR0CabiA011013006.C * der(AIR0CabiA011013006.T) = AIR0CabiA011013006.port.Q_flow; AIR0CabiA012013006.T = AIR0CabiA012013006.port.T; AIR0CabiA012013006.der_T = der(AIR0CabiA012013006.T); AIR0CabiA012013006.C * der(AIR0CabiA012013006.T) = AIR0CabiA012013006.port.Q_flow; AIR0CabiA002014006.T = AIR0CabiA002014006.port.T; AIR0CabiA002014006.der_T = der(AIR0CabiA002014006.T); AIR0CabiA002014006.C * der(AIR0CabiA002014006.T) = AIR0CabiA002014006.port.Q_flow; AIR0CabiA003014006.T = AIR0CabiA003014006.port.T; AIR0CabiA003014006.der_T = der(AIR0CabiA003014006.T); AIR0CabiA003014006.C * der(AIR0CabiA003014006.T) = AIR0CabiA003014006.port.Q_flow; AIR0CabiA004014006.T = AIR0CabiA004014006.port.T; AIR0CabiA004014006.der_T = der(AIR0CabiA004014006.T); AIR0CabiA004014006.C * der(AIR0CabiA004014006.T) = AIR0CabiA004014006.port.Q_flow; AIR0CabiA005014006.T = AIR0CabiA005014006.port.T; AIR0CabiA005014006.der_T = der(AIR0CabiA005014006.T); AIR0CabiA005014006.C * der(AIR0CabiA005014006.T) = AIR0CabiA005014006.port.Q_flow; AIR0CabiA006014006.T = AIR0CabiA006014006.port.T; AIR0CabiA006014006.der_T = der(AIR0CabiA006014006.T); AIR0CabiA006014006.C * der(AIR0CabiA006014006.T) = AIR0CabiA006014006.port.Q_flow; AIR0CabiA007014006.T = AIR0CabiA007014006.port.T; AIR0CabiA007014006.der_T = der(AIR0CabiA007014006.T); AIR0CabiA007014006.C * der(AIR0CabiA007014006.T) = AIR0CabiA007014006.port.Q_flow; AIR0CabiA008014006.T = AIR0CabiA008014006.port.T; AIR0CabiA008014006.der_T = der(AIR0CabiA008014006.T); AIR0CabiA008014006.C * der(AIR0CabiA008014006.T) = AIR0CabiA008014006.port.Q_flow; AIR0CabiA009014006.T = AIR0CabiA009014006.port.T; AIR0CabiA009014006.der_T = der(AIR0CabiA009014006.T); AIR0CabiA009014006.C * der(AIR0CabiA009014006.T) = AIR0CabiA009014006.port.Q_flow; AIR0CabiA010014006.T = AIR0CabiA010014006.port.T; AIR0CabiA010014006.der_T = der(AIR0CabiA010014006.T); AIR0CabiA010014006.C * der(AIR0CabiA010014006.T) = AIR0CabiA010014006.port.Q_flow; AIR0CabiA011014006.T = AIR0CabiA011014006.port.T; AIR0CabiA011014006.der_T = der(AIR0CabiA011014006.T); AIR0CabiA011014006.C * der(AIR0CabiA011014006.T) = AIR0CabiA011014006.port.Q_flow; AIR0CabiA012014006.T = AIR0CabiA012014006.port.T; AIR0CabiA012014006.der_T = der(AIR0CabiA012014006.T); AIR0CabiA012014006.C * der(AIR0CabiA012014006.T) = AIR0CabiA012014006.port.Q_flow; AIR0CabiA002015006.T = AIR0CabiA002015006.port.T; AIR0CabiA002015006.der_T = der(AIR0CabiA002015006.T); AIR0CabiA002015006.C * der(AIR0CabiA002015006.T) = AIR0CabiA002015006.port.Q_flow; AIR0CabiA003015006.T = AIR0CabiA003015006.port.T; AIR0CabiA003015006.der_T = der(AIR0CabiA003015006.T); AIR0CabiA003015006.C * der(AIR0CabiA003015006.T) = AIR0CabiA003015006.port.Q_flow; AIR0CabiA004015006.T = AIR0CabiA004015006.port.T; AIR0CabiA004015006.der_T = der(AIR0CabiA004015006.T); AIR0CabiA004015006.C * der(AIR0CabiA004015006.T) = AIR0CabiA004015006.port.Q_flow; AIR0CabiA005015006.T = AIR0CabiA005015006.port.T; AIR0CabiA005015006.der_T = der(AIR0CabiA005015006.T); AIR0CabiA005015006.C * der(AIR0CabiA005015006.T) = AIR0CabiA005015006.port.Q_flow; AIR0CabiA006015006.T = AIR0CabiA006015006.port.T; AIR0CabiA006015006.der_T = der(AIR0CabiA006015006.T); AIR0CabiA006015006.C * der(AIR0CabiA006015006.T) = AIR0CabiA006015006.port.Q_flow; AIR0CabiA007015006.T = AIR0CabiA007015006.port.T; AIR0CabiA007015006.der_T = der(AIR0CabiA007015006.T); AIR0CabiA007015006.C * der(AIR0CabiA007015006.T) = AIR0CabiA007015006.port.Q_flow; AIR0CabiA008015006.T = AIR0CabiA008015006.port.T; AIR0CabiA008015006.der_T = der(AIR0CabiA008015006.T); AIR0CabiA008015006.C * der(AIR0CabiA008015006.T) = AIR0CabiA008015006.port.Q_flow; AIR0CabiA009015006.T = AIR0CabiA009015006.port.T; AIR0CabiA009015006.der_T = der(AIR0CabiA009015006.T); AIR0CabiA009015006.C * der(AIR0CabiA009015006.T) = AIR0CabiA009015006.port.Q_flow; AIR0CabiA010015006.T = AIR0CabiA010015006.port.T; AIR0CabiA010015006.der_T = der(AIR0CabiA010015006.T); AIR0CabiA010015006.C * der(AIR0CabiA010015006.T) = AIR0CabiA010015006.port.Q_flow; AIR0CabiA011015006.T = AIR0CabiA011015006.port.T; AIR0CabiA011015006.der_T = der(AIR0CabiA011015006.T); AIR0CabiA011015006.C * der(AIR0CabiA011015006.T) = AIR0CabiA011015006.port.Q_flow; AIR0CabiA012015006.T = AIR0CabiA012015006.port.T; AIR0CabiA012015006.der_T = der(AIR0CabiA012015006.T); AIR0CabiA012015006.C * der(AIR0CabiA012015006.T) = AIR0CabiA012015006.port.Q_flow; AIR0CabiA010005006.T = AIR0CabiA010005006.port.T; AIR0CabiA010005006.der_T = der(AIR0CabiA010005006.T); AIR0CabiA010005006.C * der(AIR0CabiA010005006.T) = AIR0CabiA010005006.port.Q_flow; AIR0CabiA011005006.T = AIR0CabiA011005006.port.T; AIR0CabiA011005006.der_T = der(AIR0CabiA011005006.T); AIR0CabiA011005006.C * der(AIR0CabiA011005006.T) = AIR0CabiA011005006.port.Q_flow; AIR0CabiA012005006.T = AIR0CabiA012005006.port.T; AIR0CabiA012005006.der_T = der(AIR0CabiA012005006.T); AIR0CabiA012005006.C * der(AIR0CabiA012005006.T) = AIR0CabiA012005006.port.Q_flow; AIR0CabiA002006006.T = AIR0CabiA002006006.port.T; AIR0CabiA002006006.der_T = der(AIR0CabiA002006006.T); AIR0CabiA002006006.C * der(AIR0CabiA002006006.T) = AIR0CabiA002006006.port.Q_flow; AIR0CabiA003006006.T = AIR0CabiA003006006.port.T; AIR0CabiA003006006.der_T = der(AIR0CabiA003006006.T); AIR0CabiA003006006.C * der(AIR0CabiA003006006.T) = AIR0CabiA003006006.port.Q_flow; AIR0CabiA004006006.T = AIR0CabiA004006006.port.T; AIR0CabiA004006006.der_T = der(AIR0CabiA004006006.T); AIR0CabiA004006006.C * der(AIR0CabiA004006006.T) = AIR0CabiA004006006.port.Q_flow; AIR0CabiA005006006.T = AIR0CabiA005006006.port.T; AIR0CabiA005006006.der_T = der(AIR0CabiA005006006.T); AIR0CabiA005006006.C * der(AIR0CabiA005006006.T) = AIR0CabiA005006006.port.Q_flow; AIR0CabiA010006006.T = AIR0CabiA010006006.port.T; AIR0CabiA010006006.der_T = der(AIR0CabiA010006006.T); AIR0CabiA010006006.C * der(AIR0CabiA010006006.T) = AIR0CabiA010006006.port.Q_flow; AIR0CabiA011006006.T = AIR0CabiA011006006.port.T; AIR0CabiA011006006.der_T = der(AIR0CabiA011006006.T); AIR0CabiA011006006.C * der(AIR0CabiA011006006.T) = AIR0CabiA011006006.port.Q_flow; AIR0CabiA012006006.T = AIR0CabiA012006006.port.T; AIR0CabiA012006006.der_T = der(AIR0CabiA012006006.T); AIR0CabiA012006006.C * der(AIR0CabiA012006006.T) = AIR0CabiA012006006.port.Q_flow; AIR0CabiA002007006.T = AIR0CabiA002007006.port.T; AIR0CabiA002007006.der_T = der(AIR0CabiA002007006.T); AIR0CabiA002007006.C * der(AIR0CabiA002007006.T) = AIR0CabiA002007006.port.Q_flow; AIR0CabiA003007006.T = AIR0CabiA003007006.port.T; AIR0CabiA003007006.der_T = der(AIR0CabiA003007006.T); AIR0CabiA003007006.C * der(AIR0CabiA003007006.T) = AIR0CabiA003007006.port.Q_flow; AIR0CabiA004007006.T = AIR0CabiA004007006.port.T; AIR0CabiA004007006.der_T = der(AIR0CabiA004007006.T); AIR0CabiA004007006.C * der(AIR0CabiA004007006.T) = AIR0CabiA004007006.port.Q_flow; AIR0CabiA005007006.T = AIR0CabiA005007006.port.T; AIR0CabiA005007006.der_T = der(AIR0CabiA005007006.T); AIR0CabiA005007006.C * der(AIR0CabiA005007006.T) = AIR0CabiA005007006.port.Q_flow; AIR0CabiA006007006.T = AIR0CabiA006007006.port.T; AIR0CabiA006007006.der_T = der(AIR0CabiA006007006.T); AIR0CabiA006007006.C * der(AIR0CabiA006007006.T) = AIR0CabiA006007006.port.Q_flow; AIR0CabiA007007006.T = AIR0CabiA007007006.port.T; AIR0CabiA007007006.der_T = der(AIR0CabiA007007006.T); AIR0CabiA007007006.C * der(AIR0CabiA007007006.T) = AIR0CabiA007007006.port.Q_flow; AIR0CabiA008007006.T = AIR0CabiA008007006.port.T; AIR0CabiA008007006.der_T = der(AIR0CabiA008007006.T); AIR0CabiA008007006.C * der(AIR0CabiA008007006.T) = AIR0CabiA008007006.port.Q_flow; AIR0CabiA009007006.T = AIR0CabiA009007006.port.T; AIR0CabiA009007006.der_T = der(AIR0CabiA009007006.T); AIR0CabiA009007006.C * der(AIR0CabiA009007006.T) = AIR0CabiA009007006.port.Q_flow; AIR0CabiA010007006.T = AIR0CabiA010007006.port.T; AIR0CabiA010007006.der_T = der(AIR0CabiA010007006.T); AIR0CabiA010007006.C * der(AIR0CabiA010007006.T) = AIR0CabiA010007006.port.Q_flow; AIR0CabiA011007006.T = AIR0CabiA011007006.port.T; AIR0CabiA011007006.der_T = der(AIR0CabiA011007006.T); AIR0CabiA011007006.C * der(AIR0CabiA011007006.T) = AIR0CabiA011007006.port.Q_flow; AIR0CabiA012007006.T = AIR0CabiA012007006.port.T; AIR0CabiA012007006.der_T = der(AIR0CabiA012007006.T); AIR0CabiA012007006.C * der(AIR0CabiA012007006.T) = AIR0CabiA012007006.port.Q_flow; AIR0CabiA002008006.T = AIR0CabiA002008006.port.T; AIR0CabiA002008006.der_T = der(AIR0CabiA002008006.T); AIR0CabiA002008006.C * der(AIR0CabiA002008006.T) = AIR0CabiA002008006.port.Q_flow; AIR0CabiA003008006.T = AIR0CabiA003008006.port.T; AIR0CabiA003008006.der_T = der(AIR0CabiA003008006.T); AIR0CabiA003008006.C * der(AIR0CabiA003008006.T) = AIR0CabiA003008006.port.Q_flow; AIR0CabiA004008006.T = AIR0CabiA004008006.port.T; AIR0CabiA004008006.der_T = der(AIR0CabiA004008006.T); AIR0CabiA004008006.C * der(AIR0CabiA004008006.T) = AIR0CabiA004008006.port.Q_flow; AIR0CabiA005008006.T = AIR0CabiA005008006.port.T; AIR0CabiA005008006.der_T = der(AIR0CabiA005008006.T); AIR0CabiA005008006.C * der(AIR0CabiA005008006.T) = AIR0CabiA005008006.port.Q_flow; AIR0CabiA006008006.T = AIR0CabiA006008006.port.T; AIR0CabiA006008006.der_T = der(AIR0CabiA006008006.T); AIR0CabiA006008006.C * der(AIR0CabiA006008006.T) = AIR0CabiA006008006.port.Q_flow; AIR0CabiA007008006.T = AIR0CabiA007008006.port.T; AIR0CabiA007008006.der_T = der(AIR0CabiA007008006.T); AIR0CabiA007008006.C * der(AIR0CabiA007008006.T) = AIR0CabiA007008006.port.Q_flow; AIR0CabiA008008006.T = AIR0CabiA008008006.port.T; AIR0CabiA008008006.der_T = der(AIR0CabiA008008006.T); AIR0CabiA008008006.C * der(AIR0CabiA008008006.T) = AIR0CabiA008008006.port.Q_flow; AIR0CabiA009008006.T = AIR0CabiA009008006.port.T; AIR0CabiA009008006.der_T = der(AIR0CabiA009008006.T); AIR0CabiA009008006.C * der(AIR0CabiA009008006.T) = AIR0CabiA009008006.port.Q_flow; AIR0CabiA010008006.T = AIR0CabiA010008006.port.T; AIR0CabiA010008006.der_T = der(AIR0CabiA010008006.T); AIR0CabiA010008006.C * der(AIR0CabiA010008006.T) = AIR0CabiA010008006.port.Q_flow; AIR0CabiA011008006.T = AIR0CabiA011008006.port.T; AIR0CabiA011008006.der_T = der(AIR0CabiA011008006.T); AIR0CabiA011008006.C * der(AIR0CabiA011008006.T) = AIR0CabiA011008006.port.Q_flow; AIR0CabiA012008006.T = AIR0CabiA012008006.port.T; AIR0CabiA012008006.der_T = der(AIR0CabiA012008006.T); AIR0CabiA012008006.C * der(AIR0CabiA012008006.T) = AIR0CabiA012008006.port.Q_flow; AIR0CabiA002009006.T = AIR0CabiA002009006.port.T; AIR0CabiA002009006.der_T = der(AIR0CabiA002009006.T); AIR0CabiA002009006.C * der(AIR0CabiA002009006.T) = AIR0CabiA002009006.port.Q_flow; AIR0CabiA003009006.T = AIR0CabiA003009006.port.T; AIR0CabiA003009006.der_T = der(AIR0CabiA003009006.T); AIR0CabiA003009006.C * der(AIR0CabiA003009006.T) = AIR0CabiA003009006.port.Q_flow; AIR0CabiA004009006.T = AIR0CabiA004009006.port.T; AIR0CabiA004009006.der_T = der(AIR0CabiA004009006.T); AIR0CabiA004009006.C * der(AIR0CabiA004009006.T) = AIR0CabiA004009006.port.Q_flow; AIR0CabiA005009006.T = AIR0CabiA005009006.port.T; AIR0CabiA005009006.der_T = der(AIR0CabiA005009006.T); AIR0CabiA005009006.C * der(AIR0CabiA005009006.T) = AIR0CabiA005009006.port.Q_flow; AIR0CabiA006009006.T = AIR0CabiA006009006.port.T; AIR0CabiA006009006.der_T = der(AIR0CabiA006009006.T); AIR0CabiA006009006.C * der(AIR0CabiA006009006.T) = AIR0CabiA006009006.port.Q_flow; AIR0CabiA007009006.T = AIR0CabiA007009006.port.T; AIR0CabiA007009006.der_T = der(AIR0CabiA007009006.T); AIR0CabiA007009006.C * der(AIR0CabiA007009006.T) = AIR0CabiA007009006.port.Q_flow; AIR0CabiA002002006.T = AIR0CabiA002002006.port.T; AIR0CabiA002002006.der_T = der(AIR0CabiA002002006.T); AIR0CabiA002002006.C * der(AIR0CabiA002002006.T) = AIR0CabiA002002006.port.Q_flow; AIR0CabiA003002006.T = AIR0CabiA003002006.port.T; AIR0CabiA003002006.der_T = der(AIR0CabiA003002006.T); AIR0CabiA003002006.C * der(AIR0CabiA003002006.T) = AIR0CabiA003002006.port.Q_flow; AIR0CabiA004002006.T = AIR0CabiA004002006.port.T; AIR0CabiA004002006.der_T = der(AIR0CabiA004002006.T); AIR0CabiA004002006.C * der(AIR0CabiA004002006.T) = AIR0CabiA004002006.port.Q_flow; AIR0CabiA005002006.T = AIR0CabiA005002006.port.T; AIR0CabiA005002006.der_T = der(AIR0CabiA005002006.T); AIR0CabiA005002006.C * der(AIR0CabiA005002006.T) = AIR0CabiA005002006.port.Q_flow; AIR0CabiA006002006.T = AIR0CabiA006002006.port.T; AIR0CabiA006002006.der_T = der(AIR0CabiA006002006.T); AIR0CabiA006002006.C * der(AIR0CabiA006002006.T) = AIR0CabiA006002006.port.Q_flow; AIR0CabiA007002006.T = AIR0CabiA007002006.port.T; AIR0CabiA007002006.der_T = der(AIR0CabiA007002006.T); AIR0CabiA007002006.C * der(AIR0CabiA007002006.T) = AIR0CabiA007002006.port.Q_flow; AIR0CabiA008002006.T = AIR0CabiA008002006.port.T; AIR0CabiA008002006.der_T = der(AIR0CabiA008002006.T); AIR0CabiA008002006.C * der(AIR0CabiA008002006.T) = AIR0CabiA008002006.port.Q_flow; AIR0CabiA009002006.T = AIR0CabiA009002006.port.T; AIR0CabiA009002006.der_T = der(AIR0CabiA009002006.T); AIR0CabiA009002006.C * der(AIR0CabiA009002006.T) = AIR0CabiA009002006.port.Q_flow; AIR0CabiA010002006.T = AIR0CabiA010002006.port.T; AIR0CabiA010002006.der_T = der(AIR0CabiA010002006.T); AIR0CabiA010002006.C * der(AIR0CabiA010002006.T) = AIR0CabiA010002006.port.Q_flow; AIR0CabiA011002006.T = AIR0CabiA011002006.port.T; AIR0CabiA011002006.der_T = der(AIR0CabiA011002006.T); AIR0CabiA011002006.C * der(AIR0CabiA011002006.T) = AIR0CabiA011002006.port.Q_flow; AIR0CabiA012002006.T = AIR0CabiA012002006.port.T; AIR0CabiA012002006.der_T = der(AIR0CabiA012002006.T); AIR0CabiA012002006.C * der(AIR0CabiA012002006.T) = AIR0CabiA012002006.port.Q_flow; AIR0CabiA002003006.T = AIR0CabiA002003006.port.T; AIR0CabiA002003006.der_T = der(AIR0CabiA002003006.T); AIR0CabiA002003006.C * der(AIR0CabiA002003006.T) = AIR0CabiA002003006.port.Q_flow; AIR0CabiA003003006.T = AIR0CabiA003003006.port.T; AIR0CabiA003003006.der_T = der(AIR0CabiA003003006.T); AIR0CabiA003003006.C * der(AIR0CabiA003003006.T) = AIR0CabiA003003006.port.Q_flow; AIR0CabiA004003006.T = AIR0CabiA004003006.port.T; AIR0CabiA004003006.der_T = der(AIR0CabiA004003006.T); AIR0CabiA004003006.C * der(AIR0CabiA004003006.T) = AIR0CabiA004003006.port.Q_flow; AIR0CabiA005003006.T = AIR0CabiA005003006.port.T; AIR0CabiA005003006.der_T = der(AIR0CabiA005003006.T); AIR0CabiA005003006.C * der(AIR0CabiA005003006.T) = AIR0CabiA005003006.port.Q_flow; AIR0CabiA006003006.T = AIR0CabiA006003006.port.T; AIR0CabiA006003006.der_T = der(AIR0CabiA006003006.T); AIR0CabiA006003006.C * der(AIR0CabiA006003006.T) = AIR0CabiA006003006.port.Q_flow; AIR0CabiA007003006.T = AIR0CabiA007003006.port.T; AIR0CabiA007003006.der_T = der(AIR0CabiA007003006.T); AIR0CabiA007003006.C * der(AIR0CabiA007003006.T) = AIR0CabiA007003006.port.Q_flow; AIR0CabiA008003006.T = AIR0CabiA008003006.port.T; AIR0CabiA008003006.der_T = der(AIR0CabiA008003006.T); AIR0CabiA008003006.C * der(AIR0CabiA008003006.T) = AIR0CabiA008003006.port.Q_flow; AIR0CabiA009003006.T = AIR0CabiA009003006.port.T; AIR0CabiA009003006.der_T = der(AIR0CabiA009003006.T); AIR0CabiA009003006.C * der(AIR0CabiA009003006.T) = AIR0CabiA009003006.port.Q_flow; AIR0CabiA010003006.T = AIR0CabiA010003006.port.T; AIR0CabiA010003006.der_T = der(AIR0CabiA010003006.T); AIR0CabiA010003006.C * der(AIR0CabiA010003006.T) = AIR0CabiA010003006.port.Q_flow; AIR0CabiA011003006.T = AIR0CabiA011003006.port.T; AIR0CabiA011003006.der_T = der(AIR0CabiA011003006.T); AIR0CabiA011003006.C * der(AIR0CabiA011003006.T) = AIR0CabiA011003006.port.Q_flow; AIR0CabiA012003006.T = AIR0CabiA012003006.port.T; AIR0CabiA012003006.der_T = der(AIR0CabiA012003006.T); AIR0CabiA012003006.C * der(AIR0CabiA012003006.T) = AIR0CabiA012003006.port.Q_flow; AIR0CabiA002004006.T = AIR0CabiA002004006.port.T; AIR0CabiA002004006.der_T = der(AIR0CabiA002004006.T); AIR0CabiA002004006.C * der(AIR0CabiA002004006.T) = AIR0CabiA002004006.port.Q_flow; AIR0CabiA003004006.T = AIR0CabiA003004006.port.T; AIR0CabiA003004006.der_T = der(AIR0CabiA003004006.T); AIR0CabiA003004006.C * der(AIR0CabiA003004006.T) = AIR0CabiA003004006.port.Q_flow; AIR0CabiA004004006.T = AIR0CabiA004004006.port.T; AIR0CabiA004004006.der_T = der(AIR0CabiA004004006.T); AIR0CabiA004004006.C * der(AIR0CabiA004004006.T) = AIR0CabiA004004006.port.Q_flow; AIR0CabiA005004006.T = AIR0CabiA005004006.port.T; AIR0CabiA005004006.der_T = der(AIR0CabiA005004006.T); AIR0CabiA005004006.C * der(AIR0CabiA005004006.T) = AIR0CabiA005004006.port.Q_flow; AIR0CabiA010004006.T = AIR0CabiA010004006.port.T; AIR0CabiA010004006.der_T = der(AIR0CabiA010004006.T); AIR0CabiA010004006.C * der(AIR0CabiA010004006.T) = AIR0CabiA010004006.port.Q_flow; AIR0CabiA011004006.T = AIR0CabiA011004006.port.T; AIR0CabiA011004006.der_T = der(AIR0CabiA011004006.T); AIR0CabiA011004006.C * der(AIR0CabiA011004006.T) = AIR0CabiA011004006.port.Q_flow; AIR0CabiA012004006.T = AIR0CabiA012004006.port.T; AIR0CabiA012004006.der_T = der(AIR0CabiA012004006.T); AIR0CabiA012004006.C * der(AIR0CabiA012004006.T) = AIR0CabiA012004006.port.Q_flow; AIR0CabiA002005006.T = AIR0CabiA002005006.port.T; AIR0CabiA002005006.der_T = der(AIR0CabiA002005006.T); AIR0CabiA002005006.C * der(AIR0CabiA002005006.T) = AIR0CabiA002005006.port.Q_flow; AIR0CabiA003005006.T = AIR0CabiA003005006.port.T; AIR0CabiA003005006.der_T = der(AIR0CabiA003005006.T); AIR0CabiA003005006.C * der(AIR0CabiA003005006.T) = AIR0CabiA003005006.port.Q_flow; AIR0CabiA004005006.T = AIR0CabiA004005006.port.T; AIR0CabiA004005006.der_T = der(AIR0CabiA004005006.T); AIR0CabiA004005006.C * der(AIR0CabiA004005006.T) = AIR0CabiA004005006.port.Q_flow; AIR0CabiA005005006.T = AIR0CabiA005005006.port.T; AIR0CabiA005005006.der_T = der(AIR0CabiA005005006.T); AIR0CabiA005005006.C * der(AIR0CabiA005005006.T) = AIR0CabiA005005006.port.Q_flow; AIR0CabiA002002005.T = AIR0CabiA002002005.port.T; AIR0CabiA002002005.der_T = der(AIR0CabiA002002005.T); AIR0CabiA002002005.C * der(AIR0CabiA002002005.T) = AIR0CabiA002002005.port.Q_flow; AIR0CabiA003002005.T = AIR0CabiA003002005.port.T; AIR0CabiA003002005.der_T = der(AIR0CabiA003002005.T); AIR0CabiA003002005.C * der(AIR0CabiA003002005.T) = AIR0CabiA003002005.port.Q_flow; AIR0CabiA004002005.T = AIR0CabiA004002005.port.T; AIR0CabiA004002005.der_T = der(AIR0CabiA004002005.T); AIR0CabiA004002005.C * der(AIR0CabiA004002005.T) = AIR0CabiA004002005.port.Q_flow; AIR0CabiA005002005.T = AIR0CabiA005002005.port.T; AIR0CabiA005002005.der_T = der(AIR0CabiA005002005.T); AIR0CabiA005002005.C * der(AIR0CabiA005002005.T) = AIR0CabiA005002005.port.Q_flow; AIR0CabiA006002005.T = AIR0CabiA006002005.port.T; AIR0CabiA006002005.der_T = der(AIR0CabiA006002005.T); AIR0CabiA006002005.C * der(AIR0CabiA006002005.T) = AIR0CabiA006002005.port.Q_flow; AIR0CabiA007002005.T = AIR0CabiA007002005.port.T; AIR0CabiA007002005.der_T = der(AIR0CabiA007002005.T); AIR0CabiA007002005.C * der(AIR0CabiA007002005.T) = AIR0CabiA007002005.port.Q_flow; AIR0CabiA008002005.T = AIR0CabiA008002005.port.T; AIR0CabiA008002005.der_T = der(AIR0CabiA008002005.T); AIR0CabiA008002005.C * der(AIR0CabiA008002005.T) = AIR0CabiA008002005.port.Q_flow; AIR0CabiA009002005.T = AIR0CabiA009002005.port.T; AIR0CabiA009002005.der_T = der(AIR0CabiA009002005.T); AIR0CabiA009002005.C * der(AIR0CabiA009002005.T) = AIR0CabiA009002005.port.Q_flow; AIR0CabiA010002005.T = AIR0CabiA010002005.port.T; AIR0CabiA010002005.der_T = der(AIR0CabiA010002005.T); AIR0CabiA010002005.C * der(AIR0CabiA010002005.T) = AIR0CabiA010002005.port.Q_flow; AIR0CabiA011002005.T = AIR0CabiA011002005.port.T; AIR0CabiA011002005.der_T = der(AIR0CabiA011002005.T); AIR0CabiA011002005.C * der(AIR0CabiA011002005.T) = AIR0CabiA011002005.port.Q_flow; AIR0CabiA012002005.T = AIR0CabiA012002005.port.T; AIR0CabiA012002005.der_T = der(AIR0CabiA012002005.T); AIR0CabiA012002005.C * der(AIR0CabiA012002005.T) = AIR0CabiA012002005.port.Q_flow; AIR0CabiA002003005.T = AIR0CabiA002003005.port.T; AIR0CabiA002003005.der_T = der(AIR0CabiA002003005.T); AIR0CabiA002003005.C * der(AIR0CabiA002003005.T) = AIR0CabiA002003005.port.Q_flow; AIR0CabiA012003005.T = AIR0CabiA012003005.port.T; AIR0CabiA012003005.der_T = der(AIR0CabiA012003005.T); AIR0CabiA012003005.C * der(AIR0CabiA012003005.T) = AIR0CabiA012003005.port.Q_flow; AIR0CabiA002004005.T = AIR0CabiA002004005.port.T; AIR0CabiA002004005.der_T = der(AIR0CabiA002004005.T); AIR0CabiA002004005.C * der(AIR0CabiA002004005.T) = AIR0CabiA002004005.port.Q_flow; AIR0CabiA012004005.T = AIR0CabiA012004005.port.T; AIR0CabiA012004005.der_T = der(AIR0CabiA012004005.T); AIR0CabiA012004005.C * der(AIR0CabiA012004005.T) = AIR0CabiA012004005.port.Q_flow; AIR0CabiA002005005.T = AIR0CabiA002005005.port.T; AIR0CabiA002005005.der_T = der(AIR0CabiA002005005.T); AIR0CabiA002005005.C * der(AIR0CabiA002005005.T) = AIR0CabiA002005005.port.Q_flow; AIR0CabiA012005005.T = AIR0CabiA012005005.port.T; AIR0CabiA012005005.der_T = der(AIR0CabiA012005005.T); AIR0CabiA012005005.C * der(AIR0CabiA012005005.T) = AIR0CabiA012005005.port.Q_flow; AIR0CabiA002006005.T = AIR0CabiA002006005.port.T; AIR0CabiA002006005.der_T = der(AIR0CabiA002006005.T); AIR0CabiA002006005.C * der(AIR0CabiA002006005.T) = AIR0CabiA002006005.port.Q_flow; AIR0CabiA012006005.T = AIR0CabiA012006005.port.T; AIR0CabiA012006005.der_T = der(AIR0CabiA012006005.T); AIR0CabiA012006005.C * der(AIR0CabiA012006005.T) = AIR0CabiA012006005.port.Q_flow; AIR0CabiA002007005.T = AIR0CabiA002007005.port.T; AIR0CabiA002007005.der_T = der(AIR0CabiA002007005.T); AIR0CabiA002007005.C * der(AIR0CabiA002007005.T) = AIR0CabiA002007005.port.Q_flow; AIR0CabiA012007005.T = AIR0CabiA012007005.port.T; AIR0CabiA012007005.der_T = der(AIR0CabiA012007005.T); AIR0CabiA012007005.C * der(AIR0CabiA012007005.T) = AIR0CabiA012007005.port.Q_flow; AIR0CabiA002008005.T = AIR0CabiA002008005.port.T; AIR0CabiA002008005.der_T = der(AIR0CabiA002008005.T); AIR0CabiA002008005.C * der(AIR0CabiA002008005.T) = AIR0CabiA002008005.port.Q_flow; AIR0CabiA012008005.T = AIR0CabiA012008005.port.T; AIR0CabiA012008005.der_T = der(AIR0CabiA012008005.T); AIR0CabiA012008005.C * der(AIR0CabiA012008005.T) = AIR0CabiA012008005.port.Q_flow; AIR0CabiA002009005.T = AIR0CabiA002009005.port.T; AIR0CabiA002009005.der_T = der(AIR0CabiA002009005.T); AIR0CabiA002009005.C * der(AIR0CabiA002009005.T) = AIR0CabiA002009005.port.Q_flow; AIR0CabiA012009005.T = AIR0CabiA012009005.port.T; AIR0CabiA012009005.der_T = der(AIR0CabiA012009005.T); AIR0CabiA012009005.C * der(AIR0CabiA012009005.T) = AIR0CabiA012009005.port.Q_flow; AIR0CabiA002010005.T = AIR0CabiA002010005.port.T; AIR0CabiA002010005.der_T = der(AIR0CabiA002010005.T); AIR0CabiA002010005.C * der(AIR0CabiA002010005.T) = AIR0CabiA002010005.port.Q_flow; AIR0CabiA012010005.T = AIR0CabiA012010005.port.T; AIR0CabiA012010005.der_T = der(AIR0CabiA012010005.T); AIR0CabiA012010005.C * der(AIR0CabiA012010005.T) = AIR0CabiA012010005.port.Q_flow; AIR0CabiA002011005.T = AIR0CabiA002011005.port.T; AIR0CabiA002011005.der_T = der(AIR0CabiA002011005.T); AIR0CabiA002011005.C * der(AIR0CabiA002011005.T) = AIR0CabiA002011005.port.Q_flow; AIR0CabiA012011005.T = AIR0CabiA012011005.port.T; AIR0CabiA012011005.der_T = der(AIR0CabiA012011005.T); AIR0CabiA012011005.C * der(AIR0CabiA012011005.T) = AIR0CabiA012011005.port.Q_flow; AIR0CabiA002012005.T = AIR0CabiA002012005.port.T; AIR0CabiA002012005.der_T = der(AIR0CabiA002012005.T); AIR0CabiA002012005.C * der(AIR0CabiA002012005.T) = AIR0CabiA002012005.port.Q_flow; AIR0CabiA012012005.T = AIR0CabiA012012005.port.T; AIR0CabiA012012005.der_T = der(AIR0CabiA012012005.T); AIR0CabiA012012005.C * der(AIR0CabiA012012005.T) = AIR0CabiA012012005.port.Q_flow; AIR0CabiA002013005.T = AIR0CabiA002013005.port.T; AIR0CabiA002013005.der_T = der(AIR0CabiA002013005.T); AIR0CabiA002013005.C * der(AIR0CabiA002013005.T) = AIR0CabiA002013005.port.Q_flow; AIR0CabiA012013005.T = AIR0CabiA012013005.port.T; AIR0CabiA012013005.der_T = der(AIR0CabiA012013005.T); AIR0CabiA012013005.C * der(AIR0CabiA012013005.T) = AIR0CabiA012013005.port.Q_flow; AIR0CabiA002014005.T = AIR0CabiA002014005.port.T; AIR0CabiA002014005.der_T = der(AIR0CabiA002014005.T); AIR0CabiA002014005.C * der(AIR0CabiA002014005.T) = AIR0CabiA002014005.port.Q_flow; AIR0CabiA012014005.T = AIR0CabiA012014005.port.T; AIR0CabiA012014005.der_T = der(AIR0CabiA012014005.T); AIR0CabiA012014005.C * der(AIR0CabiA012014005.T) = AIR0CabiA012014005.port.Q_flow; AIR0CabiA002015005.T = AIR0CabiA002015005.port.T; AIR0CabiA002015005.der_T = der(AIR0CabiA002015005.T); AIR0CabiA002015005.C * der(AIR0CabiA002015005.T) = AIR0CabiA002015005.port.Q_flow; AIR0CabiA003015005.T = AIR0CabiA003015005.port.T; AIR0CabiA003015005.der_T = der(AIR0CabiA003015005.T); AIR0CabiA003015005.C * der(AIR0CabiA003015005.T) = AIR0CabiA003015005.port.Q_flow; AIR0CabiA004015005.T = AIR0CabiA004015005.port.T; AIR0CabiA004015005.der_T = der(AIR0CabiA004015005.T); AIR0CabiA004015005.C * der(AIR0CabiA004015005.T) = AIR0CabiA004015005.port.Q_flow; AIR0CabiA005015005.T = AIR0CabiA005015005.port.T; AIR0CabiA005015005.der_T = der(AIR0CabiA005015005.T); AIR0CabiA005015005.C * der(AIR0CabiA005015005.T) = AIR0CabiA005015005.port.Q_flow; AIR0CabiA006015005.T = AIR0CabiA006015005.port.T; AIR0CabiA006015005.der_T = der(AIR0CabiA006015005.T); AIR0CabiA006015005.C * der(AIR0CabiA006015005.T) = AIR0CabiA006015005.port.Q_flow; AIR0CabiA007015005.T = AIR0CabiA007015005.port.T; AIR0CabiA007015005.der_T = der(AIR0CabiA007015005.T); AIR0CabiA007015005.C * der(AIR0CabiA007015005.T) = AIR0CabiA007015005.port.Q_flow; AIR0CabiA008015005.T = AIR0CabiA008015005.port.T; AIR0CabiA008015005.der_T = der(AIR0CabiA008015005.T); AIR0CabiA008015005.C * der(AIR0CabiA008015005.T) = AIR0CabiA008015005.port.Q_flow; AIR0CabiA009015005.T = AIR0CabiA009015005.port.T; AIR0CabiA009015005.der_T = der(AIR0CabiA009015005.T); AIR0CabiA009015005.C * der(AIR0CabiA009015005.T) = AIR0CabiA009015005.port.Q_flow; AIR0CabiA010015005.T = AIR0CabiA010015005.port.T; AIR0CabiA010015005.der_T = der(AIR0CabiA010015005.T); AIR0CabiA010015005.C * der(AIR0CabiA010015005.T) = AIR0CabiA010015005.port.Q_flow; AIR0CabiA011015005.T = AIR0CabiA011015005.port.T; AIR0CabiA011015005.der_T = der(AIR0CabiA011015005.T); AIR0CabiA011015005.C * der(AIR0CabiA011015005.T) = AIR0CabiA011015005.port.Q_flow; AIR0CabiA012015005.T = AIR0CabiA012015005.port.T; AIR0CabiA012015005.der_T = der(AIR0CabiA012015005.T); AIR0CabiA012015005.C * der(AIR0CabiA012015005.T) = AIR0CabiA012015005.port.Q_flow; AIR0CabiA002002004.T = AIR0CabiA002002004.port.T; AIR0CabiA002002004.der_T = der(AIR0CabiA002002004.T); AIR0CabiA002002004.C * der(AIR0CabiA002002004.T) = AIR0CabiA002002004.port.Q_flow; AIR0CabiA003002004.T = AIR0CabiA003002004.port.T; AIR0CabiA003002004.der_T = der(AIR0CabiA003002004.T); AIR0CabiA003002004.C * der(AIR0CabiA003002004.T) = AIR0CabiA003002004.port.Q_flow; AIR0CabiA004002004.T = AIR0CabiA004002004.port.T; AIR0CabiA004002004.der_T = der(AIR0CabiA004002004.T); AIR0CabiA004002004.C * der(AIR0CabiA004002004.T) = AIR0CabiA004002004.port.Q_flow; AIR0CabiA005002004.T = AIR0CabiA005002004.port.T; AIR0CabiA005002004.der_T = der(AIR0CabiA005002004.T); AIR0CabiA005002004.C * der(AIR0CabiA005002004.T) = AIR0CabiA005002004.port.Q_flow; AIR0CabiA006002004.T = AIR0CabiA006002004.port.T; AIR0CabiA006002004.der_T = der(AIR0CabiA006002004.T); AIR0CabiA006002004.C * der(AIR0CabiA006002004.T) = AIR0CabiA006002004.port.Q_flow; AIR0CabiA007002004.T = AIR0CabiA007002004.port.T; AIR0CabiA007002004.der_T = der(AIR0CabiA007002004.T); AIR0CabiA007002004.C * der(AIR0CabiA007002004.T) = AIR0CabiA007002004.port.Q_flow; AIR0CabiA008002004.T = AIR0CabiA008002004.port.T; AIR0CabiA008002004.der_T = der(AIR0CabiA008002004.T); AIR0CabiA008002004.C * der(AIR0CabiA008002004.T) = AIR0CabiA008002004.port.Q_flow; AIR0CabiA009002004.T = AIR0CabiA009002004.port.T; AIR0CabiA009002004.der_T = der(AIR0CabiA009002004.T); AIR0CabiA009002004.C * der(AIR0CabiA009002004.T) = AIR0CabiA009002004.port.Q_flow; AIR0CabiA010002004.T = AIR0CabiA010002004.port.T; AIR0CabiA010002004.der_T = der(AIR0CabiA010002004.T); AIR0CabiA010002004.C * der(AIR0CabiA010002004.T) = AIR0CabiA010002004.port.Q_flow; AIR0CabiA011002004.T = AIR0CabiA011002004.port.T; AIR0CabiA011002004.der_T = der(AIR0CabiA011002004.T); AIR0CabiA011002004.C * der(AIR0CabiA011002004.T) = AIR0CabiA011002004.port.Q_flow; AIR0CabiA012002004.T = AIR0CabiA012002004.port.T; AIR0CabiA012002004.der_T = der(AIR0CabiA012002004.T); AIR0CabiA012002004.C * der(AIR0CabiA012002004.T) = AIR0CabiA012002004.port.Q_flow; AIR0CabiA002003004.T = AIR0CabiA002003004.port.T; AIR0CabiA002003004.der_T = der(AIR0CabiA002003004.T); AIR0CabiA002003004.C * der(AIR0CabiA002003004.T) = AIR0CabiA002003004.port.Q_flow; AIR0CabiA003003004.T = AIR0CabiA003003004.port.T; AIR0CabiA003003004.der_T = der(AIR0CabiA003003004.T); AIR0CabiA003003004.C * der(AIR0CabiA003003004.T) = AIR0CabiA003003004.port.Q_flow; AIR0CabiA004003004.T = AIR0CabiA004003004.port.T; AIR0CabiA004003004.der_T = der(AIR0CabiA004003004.T); AIR0CabiA004003004.C * der(AIR0CabiA004003004.T) = AIR0CabiA004003004.port.Q_flow; AIR0CabiA005003004.T = AIR0CabiA005003004.port.T; AIR0CabiA005003004.der_T = der(AIR0CabiA005003004.T); AIR0CabiA005003004.C * der(AIR0CabiA005003004.T) = AIR0CabiA005003004.port.Q_flow; AIR0CabiA006003004.T = AIR0CabiA006003004.port.T; AIR0CabiA006003004.der_T = der(AIR0CabiA006003004.T); AIR0CabiA006003004.C * der(AIR0CabiA006003004.T) = AIR0CabiA006003004.port.Q_flow; AIR0CabiA007003004.T = AIR0CabiA007003004.port.T; AIR0CabiA007003004.der_T = der(AIR0CabiA007003004.T); AIR0CabiA007003004.C * der(AIR0CabiA007003004.T) = AIR0CabiA007003004.port.Q_flow; AIR0CabiA008003004.T = AIR0CabiA008003004.port.T; AIR0CabiA008003004.der_T = der(AIR0CabiA008003004.T); AIR0CabiA008003004.C * der(AIR0CabiA008003004.T) = AIR0CabiA008003004.port.Q_flow; AIR0CabiA009003004.T = AIR0CabiA009003004.port.T; AIR0CabiA009003004.der_T = der(AIR0CabiA009003004.T); AIR0CabiA009003004.C * der(AIR0CabiA009003004.T) = AIR0CabiA009003004.port.Q_flow; AIR0CabiA010003004.T = AIR0CabiA010003004.port.T; AIR0CabiA010003004.der_T = der(AIR0CabiA010003004.T); AIR0CabiA010003004.C * der(AIR0CabiA010003004.T) = AIR0CabiA010003004.port.Q_flow; AIR0CabiA011003004.T = AIR0CabiA011003004.port.T; AIR0CabiA011003004.der_T = der(AIR0CabiA011003004.T); AIR0CabiA011003004.C * der(AIR0CabiA011003004.T) = AIR0CabiA011003004.port.Q_flow; AIR0CabiA012003004.T = AIR0CabiA012003004.port.T; AIR0CabiA012003004.der_T = der(AIR0CabiA012003004.T); AIR0CabiA012003004.C * der(AIR0CabiA012003004.T) = AIR0CabiA012003004.port.Q_flow; AIR0CabiA002004004.T = AIR0CabiA002004004.port.T; AIR0CabiA002004004.der_T = der(AIR0CabiA002004004.T); AIR0CabiA002004004.C * der(AIR0CabiA002004004.T) = AIR0CabiA002004004.port.Q_flow; AIR0CabiA003004004.T = AIR0CabiA003004004.port.T; AIR0CabiA003004004.der_T = der(AIR0CabiA003004004.T); AIR0CabiA003004004.C * der(AIR0CabiA003004004.T) = AIR0CabiA003004004.port.Q_flow; AIR0CabiA008004004.T = AIR0CabiA008004004.port.T; AIR0CabiA008004004.der_T = der(AIR0CabiA008004004.T); AIR0CabiA008004004.C * der(AIR0CabiA008004004.T) = AIR0CabiA008004004.port.Q_flow; AIR0CabiA009004004.T = AIR0CabiA009004004.port.T; AIR0CabiA009004004.der_T = der(AIR0CabiA009004004.T); AIR0CabiA009004004.C * der(AIR0CabiA009004004.T) = AIR0CabiA009004004.port.Q_flow; AIR0CabiA010004004.T = AIR0CabiA010004004.port.T; AIR0CabiA010004004.der_T = der(AIR0CabiA010004004.T); AIR0CabiA010004004.C * der(AIR0CabiA010004004.T) = AIR0CabiA010004004.port.Q_flow; AIR0CabiA011004004.T = AIR0CabiA011004004.port.T; AIR0CabiA011004004.der_T = der(AIR0CabiA011004004.T); AIR0CabiA011004004.C * der(AIR0CabiA011004004.T) = AIR0CabiA011004004.port.Q_flow; AIR0CabiA012004004.T = AIR0CabiA012004004.port.T; AIR0CabiA012004004.der_T = der(AIR0CabiA012004004.T); AIR0CabiA012004004.C * der(AIR0CabiA012004004.T) = AIR0CabiA012004004.port.Q_flow; AIR0CabiA002005004.T = AIR0CabiA002005004.port.T; AIR0CabiA002005004.der_T = der(AIR0CabiA002005004.T); AIR0CabiA002005004.C * der(AIR0CabiA002005004.T) = AIR0CabiA002005004.port.Q_flow; AIR0CabiA003005004.T = AIR0CabiA003005004.port.T; AIR0CabiA003005004.der_T = der(AIR0CabiA003005004.T); AIR0CabiA003005004.C * der(AIR0CabiA003005004.T) = AIR0CabiA003005004.port.Q_flow; AIR0CabiA008005004.T = AIR0CabiA008005004.port.T; AIR0CabiA008005004.der_T = der(AIR0CabiA008005004.T); AIR0CabiA008005004.C * der(AIR0CabiA008005004.T) = AIR0CabiA008005004.port.Q_flow; AIR0CabiA009005004.T = AIR0CabiA009005004.port.T; AIR0CabiA009005004.der_T = der(AIR0CabiA009005004.T); AIR0CabiA009005004.C * der(AIR0CabiA009005004.T) = AIR0CabiA009005004.port.Q_flow; AIR0CabiA010005004.T = AIR0CabiA010005004.port.T; AIR0CabiA010005004.der_T = der(AIR0CabiA010005004.T); AIR0CabiA010005004.C * der(AIR0CabiA010005004.T) = AIR0CabiA010005004.port.Q_flow; AIR0CabiA011005004.T = AIR0CabiA011005004.port.T; AIR0CabiA011005004.der_T = der(AIR0CabiA011005004.T); AIR0CabiA011005004.C * der(AIR0CabiA011005004.T) = AIR0CabiA011005004.port.Q_flow; AIR0CabiA012005004.T = AIR0CabiA012005004.port.T; AIR0CabiA012005004.der_T = der(AIR0CabiA012005004.T); AIR0CabiA012005004.C * der(AIR0CabiA012005004.T) = AIR0CabiA012005004.port.Q_flow; AIR0CabiA002006004.T = AIR0CabiA002006004.port.T; AIR0CabiA002006004.der_T = der(AIR0CabiA002006004.T); AIR0CabiA002006004.C * der(AIR0CabiA002006004.T) = AIR0CabiA002006004.port.Q_flow; AIR0CabiA003006004.T = AIR0CabiA003006004.port.T; AIR0CabiA003006004.der_T = der(AIR0CabiA003006004.T); AIR0CabiA003006004.C * der(AIR0CabiA003006004.T) = AIR0CabiA003006004.port.Q_flow; AIR0CabiA008006004.T = AIR0CabiA008006004.port.T; AIR0CabiA008006004.der_T = der(AIR0CabiA008006004.T); AIR0CabiA008006004.C * der(AIR0CabiA008006004.T) = AIR0CabiA008006004.port.Q_flow; AIR0CabiA009006004.T = AIR0CabiA009006004.port.T; AIR0CabiA009006004.der_T = der(AIR0CabiA009006004.T); AIR0CabiA009006004.C * der(AIR0CabiA009006004.T) = AIR0CabiA009006004.port.Q_flow; AIR0CabiA010006004.T = AIR0CabiA010006004.port.T; AIR0CabiA010006004.der_T = der(AIR0CabiA010006004.T); AIR0CabiA010006004.C * der(AIR0CabiA010006004.T) = AIR0CabiA010006004.port.Q_flow; AIR0CabiA011006004.T = AIR0CabiA011006004.port.T; AIR0CabiA011006004.der_T = der(AIR0CabiA011006004.T); AIR0CabiA011006004.C * der(AIR0CabiA011006004.T) = AIR0CabiA011006004.port.Q_flow; AIR0CabiA012006004.T = AIR0CabiA012006004.port.T; AIR0CabiA012006004.der_T = der(AIR0CabiA012006004.T); AIR0CabiA012006004.C * der(AIR0CabiA012006004.T) = AIR0CabiA012006004.port.Q_flow; AIR0CabiA002007004.T = AIR0CabiA002007004.port.T; AIR0CabiA002007004.der_T = der(AIR0CabiA002007004.T); AIR0CabiA002007004.C * der(AIR0CabiA002007004.T) = AIR0CabiA002007004.port.Q_flow; AIR0CabiA003007004.T = AIR0CabiA003007004.port.T; AIR0CabiA003007004.der_T = der(AIR0CabiA003007004.T); AIR0CabiA003007004.C * der(AIR0CabiA003007004.T) = AIR0CabiA003007004.port.Q_flow; AIR0CabiA004007004.T = AIR0CabiA004007004.port.T; AIR0CabiA004007004.der_T = der(AIR0CabiA004007004.T); AIR0CabiA004007004.C * der(AIR0CabiA004007004.T) = AIR0CabiA004007004.port.Q_flow; AIR0CabiA005007004.T = AIR0CabiA005007004.port.T; AIR0CabiA005007004.der_T = der(AIR0CabiA005007004.T); AIR0CabiA005007004.C * der(AIR0CabiA005007004.T) = AIR0CabiA005007004.port.Q_flow; AIR0CabiA006007004.T = AIR0CabiA006007004.port.T; AIR0CabiA006007004.der_T = der(AIR0CabiA006007004.T); AIR0CabiA006007004.C * der(AIR0CabiA006007004.T) = AIR0CabiA006007004.port.Q_flow; AIR0CabiA007007004.T = AIR0CabiA007007004.port.T; AIR0CabiA007007004.der_T = der(AIR0CabiA007007004.T); AIR0CabiA007007004.C * der(AIR0CabiA007007004.T) = AIR0CabiA007007004.port.Q_flow; AIR0CabiA008007004.T = AIR0CabiA008007004.port.T; AIR0CabiA008007004.der_T = der(AIR0CabiA008007004.T); AIR0CabiA008007004.C * der(AIR0CabiA008007004.T) = AIR0CabiA008007004.port.Q_flow; AIR0CabiA009007004.T = AIR0CabiA009007004.port.T; AIR0CabiA009007004.der_T = der(AIR0CabiA009007004.T); AIR0CabiA009007004.C * der(AIR0CabiA009007004.T) = AIR0CabiA009007004.port.Q_flow; AIR0CabiA010007004.T = AIR0CabiA010007004.port.T; AIR0CabiA010007004.der_T = der(AIR0CabiA010007004.T); AIR0CabiA010007004.C * der(AIR0CabiA010007004.T) = AIR0CabiA010007004.port.Q_flow; AIR0CabiA011007004.T = AIR0CabiA011007004.port.T; AIR0CabiA011007004.der_T = der(AIR0CabiA011007004.T); AIR0CabiA011007004.C * der(AIR0CabiA011007004.T) = AIR0CabiA011007004.port.Q_flow; AIR0CabiA012007004.T = AIR0CabiA012007004.port.T; AIR0CabiA012007004.der_T = der(AIR0CabiA012007004.T); AIR0CabiA012007004.C * der(AIR0CabiA012007004.T) = AIR0CabiA012007004.port.Q_flow; AIR0CabiA002008004.T = AIR0CabiA002008004.port.T; AIR0CabiA002008004.der_T = der(AIR0CabiA002008004.T); AIR0CabiA002008004.C * der(AIR0CabiA002008004.T) = AIR0CabiA002008004.port.Q_flow; AIR0CabiA003008004.T = AIR0CabiA003008004.port.T; AIR0CabiA003008004.der_T = der(AIR0CabiA003008004.T); AIR0CabiA003008004.C * der(AIR0CabiA003008004.T) = AIR0CabiA003008004.port.Q_flow; AIR0CabiA004008004.T = AIR0CabiA004008004.port.T; AIR0CabiA004008004.der_T = der(AIR0CabiA004008004.T); AIR0CabiA004008004.C * der(AIR0CabiA004008004.T) = AIR0CabiA004008004.port.Q_flow; AIR0CabiA005008004.T = AIR0CabiA005008004.port.T; AIR0CabiA005008004.der_T = der(AIR0CabiA005008004.T); AIR0CabiA005008004.C * der(AIR0CabiA005008004.T) = AIR0CabiA005008004.port.Q_flow; AIR0CabiA006008004.T = AIR0CabiA006008004.port.T; AIR0CabiA006008004.der_T = der(AIR0CabiA006008004.T); AIR0CabiA006008004.C * der(AIR0CabiA006008004.T) = AIR0CabiA006008004.port.Q_flow; AIR0CabiA007008004.T = AIR0CabiA007008004.port.T; AIR0CabiA007008004.der_T = der(AIR0CabiA007008004.T); AIR0CabiA007008004.C * der(AIR0CabiA007008004.T) = AIR0CabiA007008004.port.Q_flow; AIR0CabiA011008004.T = AIR0CabiA011008004.port.T; AIR0CabiA011008004.der_T = der(AIR0CabiA011008004.T); AIR0CabiA011008004.C * der(AIR0CabiA011008004.T) = AIR0CabiA011008004.port.Q_flow; AIR0CabiA012008004.T = AIR0CabiA012008004.port.T; AIR0CabiA012008004.der_T = der(AIR0CabiA012008004.T); AIR0CabiA012008004.C * der(AIR0CabiA012008004.T) = AIR0CabiA012008004.port.Q_flow; AIR0CabiA002009004.T = AIR0CabiA002009004.port.T; AIR0CabiA002009004.der_T = der(AIR0CabiA002009004.T); AIR0CabiA002009004.C * der(AIR0CabiA002009004.T) = AIR0CabiA002009004.port.Q_flow; AIR0CabiA003009004.T = AIR0CabiA003009004.port.T; AIR0CabiA003009004.der_T = der(AIR0CabiA003009004.T); AIR0CabiA003009004.C * der(AIR0CabiA003009004.T) = AIR0CabiA003009004.port.Q_flow; AIR0CabiA004009004.T = AIR0CabiA004009004.port.T; AIR0CabiA004009004.der_T = der(AIR0CabiA004009004.T); AIR0CabiA004009004.C * der(AIR0CabiA004009004.T) = AIR0CabiA004009004.port.Q_flow; AIR0CabiA005009004.T = AIR0CabiA005009004.port.T; AIR0CabiA005009004.der_T = der(AIR0CabiA005009004.T); AIR0CabiA005009004.C * der(AIR0CabiA005009004.T) = AIR0CabiA005009004.port.Q_flow; AIR0CabiA006009004.T = AIR0CabiA006009004.port.T; AIR0CabiA006009004.der_T = der(AIR0CabiA006009004.T); AIR0CabiA006009004.C * der(AIR0CabiA006009004.T) = AIR0CabiA006009004.port.Q_flow; AIR0CabiA007009004.T = AIR0CabiA007009004.port.T; AIR0CabiA007009004.der_T = der(AIR0CabiA007009004.T); AIR0CabiA007009004.C * der(AIR0CabiA007009004.T) = AIR0CabiA007009004.port.Q_flow; AIR0CabiA011009004.T = AIR0CabiA011009004.port.T; AIR0CabiA011009004.der_T = der(AIR0CabiA011009004.T); AIR0CabiA011009004.C * der(AIR0CabiA011009004.T) = AIR0CabiA011009004.port.Q_flow; AIR0CabiA012009004.T = AIR0CabiA012009004.port.T; AIR0CabiA012009004.der_T = der(AIR0CabiA012009004.T); AIR0CabiA012009004.C * der(AIR0CabiA012009004.T) = AIR0CabiA012009004.port.Q_flow; AIR0CabiA002010004.T = AIR0CabiA002010004.port.T; AIR0CabiA002010004.der_T = der(AIR0CabiA002010004.T); AIR0CabiA002010004.C * der(AIR0CabiA002010004.T) = AIR0CabiA002010004.port.Q_flow; AIR0CabiA003010004.T = AIR0CabiA003010004.port.T; AIR0CabiA003010004.der_T = der(AIR0CabiA003010004.T); AIR0CabiA003010004.C * der(AIR0CabiA003010004.T) = AIR0CabiA003010004.port.Q_flow; AIR0CabiA004010004.T = AIR0CabiA004010004.port.T; AIR0CabiA004010004.der_T = der(AIR0CabiA004010004.T); AIR0CabiA004010004.C * der(AIR0CabiA004010004.T) = AIR0CabiA004010004.port.Q_flow; AIR0CabiA005010004.T = AIR0CabiA005010004.port.T; AIR0CabiA005010004.der_T = der(AIR0CabiA005010004.T); AIR0CabiA005010004.C * der(AIR0CabiA005010004.T) = AIR0CabiA005010004.port.Q_flow; AIR0CabiA006010004.T = AIR0CabiA006010004.port.T; AIR0CabiA006010004.der_T = der(AIR0CabiA006010004.T); AIR0CabiA006010004.C * der(AIR0CabiA006010004.T) = AIR0CabiA006010004.port.Q_flow; AIR0CabiA007010004.T = AIR0CabiA007010004.port.T; AIR0CabiA007010004.der_T = der(AIR0CabiA007010004.T); AIR0CabiA007010004.C * der(AIR0CabiA007010004.T) = AIR0CabiA007010004.port.Q_flow; AIR0CabiA011010004.T = AIR0CabiA011010004.port.T; AIR0CabiA011010004.der_T = der(AIR0CabiA011010004.T); AIR0CabiA011010004.C * der(AIR0CabiA011010004.T) = AIR0CabiA011010004.port.Q_flow; AIR0CabiA012010004.T = AIR0CabiA012010004.port.T; AIR0CabiA012010004.der_T = der(AIR0CabiA012010004.T); AIR0CabiA012010004.C * der(AIR0CabiA012010004.T) = AIR0CabiA012010004.port.Q_flow; AIR0CabiA002011004.T = AIR0CabiA002011004.port.T; AIR0CabiA002011004.der_T = der(AIR0CabiA002011004.T); AIR0CabiA002011004.C * der(AIR0CabiA002011004.T) = AIR0CabiA002011004.port.Q_flow; AIR0CabiA003011004.T = AIR0CabiA003011004.port.T; AIR0CabiA003011004.der_T = der(AIR0CabiA003011004.T); AIR0CabiA003011004.C * der(AIR0CabiA003011004.T) = AIR0CabiA003011004.port.Q_flow; AIR0CabiA007011004.T = AIR0CabiA007011004.port.T; AIR0CabiA007011004.der_T = der(AIR0CabiA007011004.T); AIR0CabiA007011004.C * der(AIR0CabiA007011004.T) = AIR0CabiA007011004.port.Q_flow; AIR0CabiA008011004.T = AIR0CabiA008011004.port.T; AIR0CabiA008011004.der_T = der(AIR0CabiA008011004.T); AIR0CabiA008011004.C * der(AIR0CabiA008011004.T) = AIR0CabiA008011004.port.Q_flow; AIR0CabiA009011004.T = AIR0CabiA009011004.port.T; AIR0CabiA009011004.der_T = der(AIR0CabiA009011004.T); AIR0CabiA009011004.C * der(AIR0CabiA009011004.T) = AIR0CabiA009011004.port.Q_flow; AIR0CabiA010011004.T = AIR0CabiA010011004.port.T; AIR0CabiA010011004.der_T = der(AIR0CabiA010011004.T); AIR0CabiA010011004.C * der(AIR0CabiA010011004.T) = AIR0CabiA010011004.port.Q_flow; AIR0CabiA011011004.T = AIR0CabiA011011004.port.T; AIR0CabiA011011004.der_T = der(AIR0CabiA011011004.T); AIR0CabiA011011004.C * der(AIR0CabiA011011004.T) = AIR0CabiA011011004.port.Q_flow; AIR0CabiA012011004.T = AIR0CabiA012011004.port.T; AIR0CabiA012011004.der_T = der(AIR0CabiA012011004.T); AIR0CabiA012011004.C * der(AIR0CabiA012011004.T) = AIR0CabiA012011004.port.Q_flow; AIR0CabiA002012004.T = AIR0CabiA002012004.port.T; AIR0CabiA002012004.der_T = der(AIR0CabiA002012004.T); AIR0CabiA002012004.C * der(AIR0CabiA002012004.T) = AIR0CabiA002012004.port.Q_flow; AIR0CabiA003012004.T = AIR0CabiA003012004.port.T; AIR0CabiA003012004.der_T = der(AIR0CabiA003012004.T); AIR0CabiA003012004.C * der(AIR0CabiA003012004.T) = AIR0CabiA003012004.port.Q_flow; AIR0CabiA007012004.T = AIR0CabiA007012004.port.T; AIR0CabiA007012004.der_T = der(AIR0CabiA007012004.T); AIR0CabiA007012004.C * der(AIR0CabiA007012004.T) = AIR0CabiA007012004.port.Q_flow; AIR0CabiA008012004.T = AIR0CabiA008012004.port.T; AIR0CabiA008012004.der_T = der(AIR0CabiA008012004.T); AIR0CabiA008012004.C * der(AIR0CabiA008012004.T) = AIR0CabiA008012004.port.Q_flow; AIR0CabiA009012004.T = AIR0CabiA009012004.port.T; AIR0CabiA009012004.der_T = der(AIR0CabiA009012004.T); AIR0CabiA009012004.C * der(AIR0CabiA009012004.T) = AIR0CabiA009012004.port.Q_flow; AIR0CabiA010012004.T = AIR0CabiA010012004.port.T; AIR0CabiA010012004.der_T = der(AIR0CabiA010012004.T); AIR0CabiA010012004.C * der(AIR0CabiA010012004.T) = AIR0CabiA010012004.port.Q_flow; AIR0CabiA011012004.T = AIR0CabiA011012004.port.T; AIR0CabiA011012004.der_T = der(AIR0CabiA011012004.T); AIR0CabiA011012004.C * der(AIR0CabiA011012004.T) = AIR0CabiA011012004.port.Q_flow; AIR0CabiA012012004.T = AIR0CabiA012012004.port.T; AIR0CabiA012012004.der_T = der(AIR0CabiA012012004.T); AIR0CabiA012012004.C * der(AIR0CabiA012012004.T) = AIR0CabiA012012004.port.Q_flow; AIR0CabiA002013004.T = AIR0CabiA002013004.port.T; AIR0CabiA002013004.der_T = der(AIR0CabiA002013004.T); AIR0CabiA002013004.C * der(AIR0CabiA002013004.T) = AIR0CabiA002013004.port.Q_flow; AIR0CabiA003013004.T = AIR0CabiA003013004.port.T; AIR0CabiA003013004.der_T = der(AIR0CabiA003013004.T); AIR0CabiA003013004.C * der(AIR0CabiA003013004.T) = AIR0CabiA003013004.port.Q_flow; AIR0CabiA007013004.T = AIR0CabiA007013004.port.T; AIR0CabiA007013004.der_T = der(AIR0CabiA007013004.T); AIR0CabiA007013004.C * der(AIR0CabiA007013004.T) = AIR0CabiA007013004.port.Q_flow; AIR0CabiA008013004.T = AIR0CabiA008013004.port.T; AIR0CabiA008013004.der_T = der(AIR0CabiA008013004.T); AIR0CabiA008013004.C * der(AIR0CabiA008013004.T) = AIR0CabiA008013004.port.Q_flow; AIR0CabiA009013004.T = AIR0CabiA009013004.port.T; AIR0CabiA009013004.der_T = der(AIR0CabiA009013004.T); AIR0CabiA009013004.C * der(AIR0CabiA009013004.T) = AIR0CabiA009013004.port.Q_flow; AIR0CabiA010013004.T = AIR0CabiA010013004.port.T; AIR0CabiA010013004.der_T = der(AIR0CabiA010013004.T); AIR0CabiA010013004.C * der(AIR0CabiA010013004.T) = AIR0CabiA010013004.port.Q_flow; AIR0CabiA011013004.T = AIR0CabiA011013004.port.T; AIR0CabiA011013004.der_T = der(AIR0CabiA011013004.T); AIR0CabiA011013004.C * der(AIR0CabiA011013004.T) = AIR0CabiA011013004.port.Q_flow; AIR0CabiA012013004.T = AIR0CabiA012013004.port.T; AIR0CabiA012013004.der_T = der(AIR0CabiA012013004.T); AIR0CabiA012013004.C * der(AIR0CabiA012013004.T) = AIR0CabiA012013004.port.Q_flow; AIR0CabiA002014004.T = AIR0CabiA002014004.port.T; AIR0CabiA002014004.der_T = der(AIR0CabiA002014004.T); AIR0CabiA002014004.C * der(AIR0CabiA002014004.T) = AIR0CabiA002014004.port.Q_flow; AIR0CabiA003014004.T = AIR0CabiA003014004.port.T; AIR0CabiA003014004.der_T = der(AIR0CabiA003014004.T); AIR0CabiA003014004.C * der(AIR0CabiA003014004.T) = AIR0CabiA003014004.port.Q_flow; AIR0CabiA004014004.T = AIR0CabiA004014004.port.T; AIR0CabiA004014004.der_T = der(AIR0CabiA004014004.T); AIR0CabiA004014004.C * der(AIR0CabiA004014004.T) = AIR0CabiA004014004.port.Q_flow; AIR0CabiA005014004.T = AIR0CabiA005014004.port.T; AIR0CabiA005014004.der_T = der(AIR0CabiA005014004.T); AIR0CabiA005014004.C * der(AIR0CabiA005014004.T) = AIR0CabiA005014004.port.Q_flow; AIR0CabiA006014004.T = AIR0CabiA006014004.port.T; AIR0CabiA006014004.der_T = der(AIR0CabiA006014004.T); AIR0CabiA006014004.C * der(AIR0CabiA006014004.T) = AIR0CabiA006014004.port.Q_flow; AIR0CabiA007014004.T = AIR0CabiA007014004.port.T; AIR0CabiA007014004.der_T = der(AIR0CabiA007014004.T); AIR0CabiA007014004.C * der(AIR0CabiA007014004.T) = AIR0CabiA007014004.port.Q_flow; AIR0CabiA008014004.T = AIR0CabiA008014004.port.T; AIR0CabiA008014004.der_T = der(AIR0CabiA008014004.T); AIR0CabiA008014004.C * der(AIR0CabiA008014004.T) = AIR0CabiA008014004.port.Q_flow; AIR0CabiA009014004.T = AIR0CabiA009014004.port.T; AIR0CabiA009014004.der_T = der(AIR0CabiA009014004.T); AIR0CabiA009014004.C * der(AIR0CabiA009014004.T) = AIR0CabiA009014004.port.Q_flow; AIR0CabiA010014004.T = AIR0CabiA010014004.port.T; AIR0CabiA010014004.der_T = der(AIR0CabiA010014004.T); AIR0CabiA010014004.C * der(AIR0CabiA010014004.T) = AIR0CabiA010014004.port.Q_flow; AIR0CabiA011014004.T = AIR0CabiA011014004.port.T; AIR0CabiA011014004.der_T = der(AIR0CabiA011014004.T); AIR0CabiA011014004.C * der(AIR0CabiA011014004.T) = AIR0CabiA011014004.port.Q_flow; AIR0CabiA012014004.T = AIR0CabiA012014004.port.T; AIR0CabiA012014004.der_T = der(AIR0CabiA012014004.T); AIR0CabiA012014004.C * der(AIR0CabiA012014004.T) = AIR0CabiA012014004.port.Q_flow; AIR0CabiA002015004.T = AIR0CabiA002015004.port.T; AIR0CabiA002015004.der_T = der(AIR0CabiA002015004.T); AIR0CabiA002015004.C * der(AIR0CabiA002015004.T) = AIR0CabiA002015004.port.Q_flow; AIR0CabiA003015004.T = AIR0CabiA003015004.port.T; AIR0CabiA003015004.der_T = der(AIR0CabiA003015004.T); AIR0CabiA003015004.C * der(AIR0CabiA003015004.T) = AIR0CabiA003015004.port.Q_flow; AIR0CabiA004015004.T = AIR0CabiA004015004.port.T; AIR0CabiA004015004.der_T = der(AIR0CabiA004015004.T); AIR0CabiA004015004.C * der(AIR0CabiA004015004.T) = AIR0CabiA004015004.port.Q_flow; AIR0CabiA005015004.T = AIR0CabiA005015004.port.T; AIR0CabiA005015004.der_T = der(AIR0CabiA005015004.T); AIR0CabiA005015004.C * der(AIR0CabiA005015004.T) = AIR0CabiA005015004.port.Q_flow; AIR0CabiA006015004.T = AIR0CabiA006015004.port.T; AIR0CabiA006015004.der_T = der(AIR0CabiA006015004.T); AIR0CabiA006015004.C * der(AIR0CabiA006015004.T) = AIR0CabiA006015004.port.Q_flow; AIR0CabiA007015004.T = AIR0CabiA007015004.port.T; AIR0CabiA007015004.der_T = der(AIR0CabiA007015004.T); AIR0CabiA007015004.C * der(AIR0CabiA007015004.T) = AIR0CabiA007015004.port.Q_flow; AIR0CabiA008015004.T = AIR0CabiA008015004.port.T; AIR0CabiA008015004.der_T = der(AIR0CabiA008015004.T); AIR0CabiA008015004.C * der(AIR0CabiA008015004.T) = AIR0CabiA008015004.port.Q_flow; AIR0CabiA009015004.T = AIR0CabiA009015004.port.T; AIR0CabiA009015004.der_T = der(AIR0CabiA009015004.T); AIR0CabiA009015004.C * der(AIR0CabiA009015004.T) = AIR0CabiA009015004.port.Q_flow; AIR0CabiA010015004.T = AIR0CabiA010015004.port.T; AIR0CabiA010015004.der_T = der(AIR0CabiA010015004.T); AIR0CabiA010015004.C * der(AIR0CabiA010015004.T) = AIR0CabiA010015004.port.Q_flow; AIR0CabiA011015004.T = AIR0CabiA011015004.port.T; AIR0CabiA011015004.der_T = der(AIR0CabiA011015004.T); AIR0CabiA011015004.C * der(AIR0CabiA011015004.T) = AIR0CabiA011015004.port.Q_flow; AIR0CabiA012015004.T = AIR0CabiA012015004.port.T; AIR0CabiA012015004.der_T = der(AIR0CabiA012015004.T); AIR0CabiA012015004.C * der(AIR0CabiA012015004.T) = AIR0CabiA012015004.port.Q_flow; AIR0CabiA002002003.T = AIR0CabiA002002003.port.T; AIR0CabiA002002003.der_T = der(AIR0CabiA002002003.T); AIR0CabiA002002003.C * der(AIR0CabiA002002003.T) = AIR0CabiA002002003.port.Q_flow; AIR0CabiA003002003.T = AIR0CabiA003002003.port.T; AIR0CabiA003002003.der_T = der(AIR0CabiA003002003.T); AIR0CabiA003002003.C * der(AIR0CabiA003002003.T) = AIR0CabiA003002003.port.Q_flow; AIR0CabiA004002003.T = AIR0CabiA004002003.port.T; AIR0CabiA004002003.der_T = der(AIR0CabiA004002003.T); AIR0CabiA004002003.C * der(AIR0CabiA004002003.T) = AIR0CabiA004002003.port.Q_flow; AIR0CabiA005002003.T = AIR0CabiA005002003.port.T; AIR0CabiA005002003.der_T = der(AIR0CabiA005002003.T); AIR0CabiA005002003.C * der(AIR0CabiA005002003.T) = AIR0CabiA005002003.port.Q_flow; AIR0CabiA006002003.T = AIR0CabiA006002003.port.T; AIR0CabiA006002003.der_T = der(AIR0CabiA006002003.T); AIR0CabiA006002003.C * der(AIR0CabiA006002003.T) = AIR0CabiA006002003.port.Q_flow; AIR0CabiA007002003.T = AIR0CabiA007002003.port.T; AIR0CabiA007002003.der_T = der(AIR0CabiA007002003.T); AIR0CabiA007002003.C * der(AIR0CabiA007002003.T) = AIR0CabiA007002003.port.Q_flow; AIR0CabiA008002003.T = AIR0CabiA008002003.port.T; AIR0CabiA008002003.der_T = der(AIR0CabiA008002003.T); AIR0CabiA008002003.C * der(AIR0CabiA008002003.T) = AIR0CabiA008002003.port.Q_flow; AIR0CabiA009002003.T = AIR0CabiA009002003.port.T; AIR0CabiA009002003.der_T = der(AIR0CabiA009002003.T); AIR0CabiA009002003.C * der(AIR0CabiA009002003.T) = AIR0CabiA009002003.port.Q_flow; AIR0CabiA010002003.T = AIR0CabiA010002003.port.T; AIR0CabiA010002003.der_T = der(AIR0CabiA010002003.T); AIR0CabiA010002003.C * der(AIR0CabiA010002003.T) = AIR0CabiA010002003.port.Q_flow; AIR0CabiA011002003.T = AIR0CabiA011002003.port.T; AIR0CabiA011002003.der_T = der(AIR0CabiA011002003.T); AIR0CabiA011002003.C * der(AIR0CabiA011002003.T) = AIR0CabiA011002003.port.Q_flow; AIR0CabiA012002003.T = AIR0CabiA012002003.port.T; AIR0CabiA012002003.der_T = der(AIR0CabiA012002003.T); AIR0CabiA012002003.C * der(AIR0CabiA012002003.T) = AIR0CabiA012002003.port.Q_flow; AIR0CabiA002003003.T = AIR0CabiA002003003.port.T; AIR0CabiA002003003.der_T = der(AIR0CabiA002003003.T); AIR0CabiA002003003.C * der(AIR0CabiA002003003.T) = AIR0CabiA002003003.port.Q_flow; AIR0CabiA003003003.T = AIR0CabiA003003003.port.T; AIR0CabiA003003003.der_T = der(AIR0CabiA003003003.T); AIR0CabiA003003003.C * der(AIR0CabiA003003003.T) = AIR0CabiA003003003.port.Q_flow; AIR0CabiA004003003.T = AIR0CabiA004003003.port.T; AIR0CabiA004003003.der_T = der(AIR0CabiA004003003.T); AIR0CabiA004003003.C * der(AIR0CabiA004003003.T) = AIR0CabiA004003003.port.Q_flow; AIR0CabiA005003003.T = AIR0CabiA005003003.port.T; AIR0CabiA005003003.der_T = der(AIR0CabiA005003003.T); AIR0CabiA005003003.C * der(AIR0CabiA005003003.T) = AIR0CabiA005003003.port.Q_flow; AIR0CabiA006003003.T = AIR0CabiA006003003.port.T; AIR0CabiA006003003.der_T = der(AIR0CabiA006003003.T); AIR0CabiA006003003.C * der(AIR0CabiA006003003.T) = AIR0CabiA006003003.port.Q_flow; AIR0CabiA007003003.T = AIR0CabiA007003003.port.T; AIR0CabiA007003003.der_T = der(AIR0CabiA007003003.T); AIR0CabiA007003003.C * der(AIR0CabiA007003003.T) = AIR0CabiA007003003.port.Q_flow; AIR0CabiA008003003.T = AIR0CabiA008003003.port.T; AIR0CabiA008003003.der_T = der(AIR0CabiA008003003.T); AIR0CabiA008003003.C * der(AIR0CabiA008003003.T) = AIR0CabiA008003003.port.Q_flow; AIR0CabiA009003003.T = AIR0CabiA009003003.port.T; AIR0CabiA009003003.der_T = der(AIR0CabiA009003003.T); AIR0CabiA009003003.C * der(AIR0CabiA009003003.T) = AIR0CabiA009003003.port.Q_flow; AIR0CabiA010003003.T = AIR0CabiA010003003.port.T; AIR0CabiA010003003.der_T = der(AIR0CabiA010003003.T); AIR0CabiA010003003.C * der(AIR0CabiA010003003.T) = AIR0CabiA010003003.port.Q_flow; AIR0CabiA011003003.T = AIR0CabiA011003003.port.T; AIR0CabiA011003003.der_T = der(AIR0CabiA011003003.T); AIR0CabiA011003003.C * der(AIR0CabiA011003003.T) = AIR0CabiA011003003.port.Q_flow; AIR0CabiA012003003.T = AIR0CabiA012003003.port.T; AIR0CabiA012003003.der_T = der(AIR0CabiA012003003.T); AIR0CabiA012003003.C * der(AIR0CabiA012003003.T) = AIR0CabiA012003003.port.Q_flow; AIR0CabiA002004003.T = AIR0CabiA002004003.port.T; AIR0CabiA002004003.der_T = der(AIR0CabiA002004003.T); AIR0CabiA002004003.C * der(AIR0CabiA002004003.T) = AIR0CabiA002004003.port.Q_flow; AIR0CabiA003004003.T = AIR0CabiA003004003.port.T; AIR0CabiA003004003.der_T = der(AIR0CabiA003004003.T); AIR0CabiA003004003.C * der(AIR0CabiA003004003.T) = AIR0CabiA003004003.port.Q_flow; AIR0CabiA004004003.T = AIR0CabiA004004003.port.T; AIR0CabiA004004003.der_T = der(AIR0CabiA004004003.T); AIR0CabiA004004003.C * der(AIR0CabiA004004003.T) = AIR0CabiA004004003.port.Q_flow; AIR0CabiA005004003.T = AIR0CabiA005004003.port.T; AIR0CabiA005004003.der_T = der(AIR0CabiA005004003.T); AIR0CabiA005004003.C * der(AIR0CabiA005004003.T) = AIR0CabiA005004003.port.Q_flow; AIR0CabiA006004003.T = AIR0CabiA006004003.port.T; AIR0CabiA006004003.der_T = der(AIR0CabiA006004003.T); AIR0CabiA006004003.C * der(AIR0CabiA006004003.T) = AIR0CabiA006004003.port.Q_flow; AIR0CabiA007004003.T = AIR0CabiA007004003.port.T; AIR0CabiA007004003.der_T = der(AIR0CabiA007004003.T); AIR0CabiA007004003.C * der(AIR0CabiA007004003.T) = AIR0CabiA007004003.port.Q_flow; AIR0CabiA008004003.T = AIR0CabiA008004003.port.T; AIR0CabiA008004003.der_T = der(AIR0CabiA008004003.T); AIR0CabiA008004003.C * der(AIR0CabiA008004003.T) = AIR0CabiA008004003.port.Q_flow; AIR0CabiA009004003.T = AIR0CabiA009004003.port.T; AIR0CabiA009004003.der_T = der(AIR0CabiA009004003.T); AIR0CabiA009004003.C * der(AIR0CabiA009004003.T) = AIR0CabiA009004003.port.Q_flow; AIR0CabiA010004003.T = AIR0CabiA010004003.port.T; AIR0CabiA010004003.der_T = der(AIR0CabiA010004003.T); AIR0CabiA010004003.C * der(AIR0CabiA010004003.T) = AIR0CabiA010004003.port.Q_flow; AIR0CabiA011004003.T = AIR0CabiA011004003.port.T; AIR0CabiA011004003.der_T = der(AIR0CabiA011004003.T); AIR0CabiA011004003.C * der(AIR0CabiA011004003.T) = AIR0CabiA011004003.port.Q_flow; AIR0CabiA012004003.T = AIR0CabiA012004003.port.T; AIR0CabiA012004003.der_T = der(AIR0CabiA012004003.T); AIR0CabiA012004003.C * der(AIR0CabiA012004003.T) = AIR0CabiA012004003.port.Q_flow; AIR0CabiA002005003.T = AIR0CabiA002005003.port.T; AIR0CabiA002005003.der_T = der(AIR0CabiA002005003.T); AIR0CabiA002005003.C * der(AIR0CabiA002005003.T) = AIR0CabiA002005003.port.Q_flow; AIR0CabiA003005003.T = AIR0CabiA003005003.port.T; AIR0CabiA003005003.der_T = der(AIR0CabiA003005003.T); AIR0CabiA003005003.C * der(AIR0CabiA003005003.T) = AIR0CabiA003005003.port.Q_flow; AIR0CabiA004005003.T = AIR0CabiA004005003.port.T; AIR0CabiA004005003.der_T = der(AIR0CabiA004005003.T); AIR0CabiA004005003.C * der(AIR0CabiA004005003.T) = AIR0CabiA004005003.port.Q_flow; AIR0CabiA005005003.T = AIR0CabiA005005003.port.T; AIR0CabiA005005003.der_T = der(AIR0CabiA005005003.T); AIR0CabiA005005003.C * der(AIR0CabiA005005003.T) = AIR0CabiA005005003.port.Q_flow; AIR0CabiA006005003.T = AIR0CabiA006005003.port.T; AIR0CabiA006005003.der_T = der(AIR0CabiA006005003.T); AIR0CabiA006005003.C * der(AIR0CabiA006005003.T) = AIR0CabiA006005003.port.Q_flow; AIR0CabiA007005003.T = AIR0CabiA007005003.port.T; AIR0CabiA007005003.der_T = der(AIR0CabiA007005003.T); AIR0CabiA007005003.C * der(AIR0CabiA007005003.T) = AIR0CabiA007005003.port.Q_flow; AIR0CabiA008005003.T = AIR0CabiA008005003.port.T; AIR0CabiA008005003.der_T = der(AIR0CabiA008005003.T); AIR0CabiA008005003.C * der(AIR0CabiA008005003.T) = AIR0CabiA008005003.port.Q_flow; AIR0CabiA009005003.T = AIR0CabiA009005003.port.T; AIR0CabiA009005003.der_T = der(AIR0CabiA009005003.T); AIR0CabiA009005003.C * der(AIR0CabiA009005003.T) = AIR0CabiA009005003.port.Q_flow; AIR0CabiA010005003.T = AIR0CabiA010005003.port.T; AIR0CabiA010005003.der_T = der(AIR0CabiA010005003.T); AIR0CabiA010005003.C * der(AIR0CabiA010005003.T) = AIR0CabiA010005003.port.Q_flow; AIR0CabiA011005003.T = AIR0CabiA011005003.port.T; AIR0CabiA011005003.der_T = der(AIR0CabiA011005003.T); AIR0CabiA011005003.C * der(AIR0CabiA011005003.T) = AIR0CabiA011005003.port.Q_flow; AIR0CabiA012005003.T = AIR0CabiA012005003.port.T; AIR0CabiA012005003.der_T = der(AIR0CabiA012005003.T); AIR0CabiA012005003.C * der(AIR0CabiA012005003.T) = AIR0CabiA012005003.port.Q_flow; AIR0CabiA002006003.T = AIR0CabiA002006003.port.T; AIR0CabiA002006003.der_T = der(AIR0CabiA002006003.T); AIR0CabiA002006003.C * der(AIR0CabiA002006003.T) = AIR0CabiA002006003.port.Q_flow; AIR0CabiA003006003.T = AIR0CabiA003006003.port.T; AIR0CabiA003006003.der_T = der(AIR0CabiA003006003.T); AIR0CabiA003006003.C * der(AIR0CabiA003006003.T) = AIR0CabiA003006003.port.Q_flow; AIR0CabiA004006003.T = AIR0CabiA004006003.port.T; AIR0CabiA004006003.der_T = der(AIR0CabiA004006003.T); AIR0CabiA004006003.C * der(AIR0CabiA004006003.T) = AIR0CabiA004006003.port.Q_flow; AIR0CabiA005006003.T = AIR0CabiA005006003.port.T; AIR0CabiA005006003.der_T = der(AIR0CabiA005006003.T); AIR0CabiA005006003.C * der(AIR0CabiA005006003.T) = AIR0CabiA005006003.port.Q_flow; AIR0CabiA006006003.T = AIR0CabiA006006003.port.T; AIR0CabiA006006003.der_T = der(AIR0CabiA006006003.T); AIR0CabiA006006003.C * der(AIR0CabiA006006003.T) = AIR0CabiA006006003.port.Q_flow; AIR0CabiA007006003.T = AIR0CabiA007006003.port.T; AIR0CabiA007006003.der_T = der(AIR0CabiA007006003.T); AIR0CabiA007006003.C * der(AIR0CabiA007006003.T) = AIR0CabiA007006003.port.Q_flow; AIR0CabiA008006003.T = AIR0CabiA008006003.port.T; AIR0CabiA008006003.der_T = der(AIR0CabiA008006003.T); AIR0CabiA008006003.C * der(AIR0CabiA008006003.T) = AIR0CabiA008006003.port.Q_flow; AIR0CabiA009006003.T = AIR0CabiA009006003.port.T; AIR0CabiA009006003.der_T = der(AIR0CabiA009006003.T); AIR0CabiA009006003.C * der(AIR0CabiA009006003.T) = AIR0CabiA009006003.port.Q_flow; AIR0CabiA010006003.T = AIR0CabiA010006003.port.T; AIR0CabiA010006003.der_T = der(AIR0CabiA010006003.T); AIR0CabiA010006003.C * der(AIR0CabiA010006003.T) = AIR0CabiA010006003.port.Q_flow; AIR0CabiA011006003.T = AIR0CabiA011006003.port.T; AIR0CabiA011006003.der_T = der(AIR0CabiA011006003.T); AIR0CabiA011006003.C * der(AIR0CabiA011006003.T) = AIR0CabiA011006003.port.Q_flow; AIR0CabiA012006003.T = AIR0CabiA012006003.port.T; AIR0CabiA012006003.der_T = der(AIR0CabiA012006003.T); AIR0CabiA012006003.C * der(AIR0CabiA012006003.T) = AIR0CabiA012006003.port.Q_flow; AIR0CabiA002007003.T = AIR0CabiA002007003.port.T; AIR0CabiA002007003.der_T = der(AIR0CabiA002007003.T); AIR0CabiA002007003.C * der(AIR0CabiA002007003.T) = AIR0CabiA002007003.port.Q_flow; AIR0CabiA003007003.T = AIR0CabiA003007003.port.T; AIR0CabiA003007003.der_T = der(AIR0CabiA003007003.T); AIR0CabiA003007003.C * der(AIR0CabiA003007003.T) = AIR0CabiA003007003.port.Q_flow; AIR0CabiA004007003.T = AIR0CabiA004007003.port.T; AIR0CabiA004007003.der_T = der(AIR0CabiA004007003.T); AIR0CabiA004007003.C * der(AIR0CabiA004007003.T) = AIR0CabiA004007003.port.Q_flow; AIR0CabiA005007003.T = AIR0CabiA005007003.port.T; AIR0CabiA005007003.der_T = der(AIR0CabiA005007003.T); AIR0CabiA005007003.C * der(AIR0CabiA005007003.T) = AIR0CabiA005007003.port.Q_flow; AIR0CabiA006007003.T = AIR0CabiA006007003.port.T; AIR0CabiA006007003.der_T = der(AIR0CabiA006007003.T); AIR0CabiA006007003.C * der(AIR0CabiA006007003.T) = AIR0CabiA006007003.port.Q_flow; AIR0CabiA007007003.T = AIR0CabiA007007003.port.T; AIR0CabiA007007003.der_T = der(AIR0CabiA007007003.T); AIR0CabiA007007003.C * der(AIR0CabiA007007003.T) = AIR0CabiA007007003.port.Q_flow; AIR0CabiA008007003.T = AIR0CabiA008007003.port.T; AIR0CabiA008007003.der_T = der(AIR0CabiA008007003.T); AIR0CabiA008007003.C * der(AIR0CabiA008007003.T) = AIR0CabiA008007003.port.Q_flow; AIR0CabiA009007003.T = AIR0CabiA009007003.port.T; AIR0CabiA009007003.der_T = der(AIR0CabiA009007003.T); AIR0CabiA009007003.C * der(AIR0CabiA009007003.T) = AIR0CabiA009007003.port.Q_flow; AIR0CabiA010007003.T = AIR0CabiA010007003.port.T; AIR0CabiA010007003.der_T = der(AIR0CabiA010007003.T); AIR0CabiA010007003.C * der(AIR0CabiA010007003.T) = AIR0CabiA010007003.port.Q_flow; AIR0CabiA011007003.T = AIR0CabiA011007003.port.T; AIR0CabiA011007003.der_T = der(AIR0CabiA011007003.T); AIR0CabiA011007003.C * der(AIR0CabiA011007003.T) = AIR0CabiA011007003.port.Q_flow; AIR0CabiA012007003.T = AIR0CabiA012007003.port.T; AIR0CabiA012007003.der_T = der(AIR0CabiA012007003.T); AIR0CabiA012007003.C * der(AIR0CabiA012007003.T) = AIR0CabiA012007003.port.Q_flow; AIR0CabiA002008003.T = AIR0CabiA002008003.port.T; AIR0CabiA002008003.der_T = der(AIR0CabiA002008003.T); AIR0CabiA002008003.C * der(AIR0CabiA002008003.T) = AIR0CabiA002008003.port.Q_flow; AIR0CabiA003008003.T = AIR0CabiA003008003.port.T; AIR0CabiA003008003.der_T = der(AIR0CabiA003008003.T); AIR0CabiA003008003.C * der(AIR0CabiA003008003.T) = AIR0CabiA003008003.port.Q_flow; AIR0CabiA004008003.T = AIR0CabiA004008003.port.T; AIR0CabiA004008003.der_T = der(AIR0CabiA004008003.T); AIR0CabiA004008003.C * der(AIR0CabiA004008003.T) = AIR0CabiA004008003.port.Q_flow; AIR0CabiA005008003.T = AIR0CabiA005008003.port.T; AIR0CabiA005008003.der_T = der(AIR0CabiA005008003.T); AIR0CabiA005008003.C * der(AIR0CabiA005008003.T) = AIR0CabiA005008003.port.Q_flow; AIR0CabiA006008003.T = AIR0CabiA006008003.port.T; AIR0CabiA006008003.der_T = der(AIR0CabiA006008003.T); AIR0CabiA006008003.C * der(AIR0CabiA006008003.T) = AIR0CabiA006008003.port.Q_flow; AIR0CabiA007008003.T = AIR0CabiA007008003.port.T; AIR0CabiA007008003.der_T = der(AIR0CabiA007008003.T); AIR0CabiA007008003.C * der(AIR0CabiA007008003.T) = AIR0CabiA007008003.port.Q_flow; AIR0CabiA011008003.T = AIR0CabiA011008003.port.T; AIR0CabiA011008003.der_T = der(AIR0CabiA011008003.T); AIR0CabiA011008003.C * der(AIR0CabiA011008003.T) = AIR0CabiA011008003.port.Q_flow; AIR0CabiA012008003.T = AIR0CabiA012008003.port.T; AIR0CabiA012008003.der_T = der(AIR0CabiA012008003.T); AIR0CabiA012008003.C * der(AIR0CabiA012008003.T) = AIR0CabiA012008003.port.Q_flow; AIR0CabiA002009003.T = AIR0CabiA002009003.port.T; AIR0CabiA002009003.der_T = der(AIR0CabiA002009003.T); AIR0CabiA002009003.C * der(AIR0CabiA002009003.T) = AIR0CabiA002009003.port.Q_flow; AIR0CabiA003009003.T = AIR0CabiA003009003.port.T; AIR0CabiA003009003.der_T = der(AIR0CabiA003009003.T); AIR0CabiA003009003.C * der(AIR0CabiA003009003.T) = AIR0CabiA003009003.port.Q_flow; AIR0CabiA004009003.T = AIR0CabiA004009003.port.T; AIR0CabiA004009003.der_T = der(AIR0CabiA004009003.T); AIR0CabiA004009003.C * der(AIR0CabiA004009003.T) = AIR0CabiA004009003.port.Q_flow; AIR0CabiA005009003.T = AIR0CabiA005009003.port.T; AIR0CabiA005009003.der_T = der(AIR0CabiA005009003.T); AIR0CabiA005009003.C * der(AIR0CabiA005009003.T) = AIR0CabiA005009003.port.Q_flow; AIR0CabiA006009003.T = AIR0CabiA006009003.port.T; AIR0CabiA006009003.der_T = der(AIR0CabiA006009003.T); AIR0CabiA006009003.C * der(AIR0CabiA006009003.T) = AIR0CabiA006009003.port.Q_flow; AIR0CabiA007009003.T = AIR0CabiA007009003.port.T; AIR0CabiA007009003.der_T = der(AIR0CabiA007009003.T); AIR0CabiA007009003.C * der(AIR0CabiA007009003.T) = AIR0CabiA007009003.port.Q_flow; AIR0CabiA011009003.T = AIR0CabiA011009003.port.T; AIR0CabiA011009003.der_T = der(AIR0CabiA011009003.T); AIR0CabiA011009003.C * der(AIR0CabiA011009003.T) = AIR0CabiA011009003.port.Q_flow; AIR0CabiA012009003.T = AIR0CabiA012009003.port.T; AIR0CabiA012009003.der_T = der(AIR0CabiA012009003.T); AIR0CabiA012009003.C * der(AIR0CabiA012009003.T) = AIR0CabiA012009003.port.Q_flow; AIR0CabiA002010003.T = AIR0CabiA002010003.port.T; AIR0CabiA002010003.der_T = der(AIR0CabiA002010003.T); AIR0CabiA002010003.C * der(AIR0CabiA002010003.T) = AIR0CabiA002010003.port.Q_flow; AIR0CabiA003010003.T = AIR0CabiA003010003.port.T; AIR0CabiA003010003.der_T = der(AIR0CabiA003010003.T); AIR0CabiA003010003.C * der(AIR0CabiA003010003.T) = AIR0CabiA003010003.port.Q_flow; AIR0CabiA004010003.T = AIR0CabiA004010003.port.T; AIR0CabiA004010003.der_T = der(AIR0CabiA004010003.T); AIR0CabiA004010003.C * der(AIR0CabiA004010003.T) = AIR0CabiA004010003.port.Q_flow; AIR0CabiA005010003.T = AIR0CabiA005010003.port.T; AIR0CabiA005010003.der_T = der(AIR0CabiA005010003.T); AIR0CabiA005010003.C * der(AIR0CabiA005010003.T) = AIR0CabiA005010003.port.Q_flow; AIR0CabiA006010003.T = AIR0CabiA006010003.port.T; AIR0CabiA006010003.der_T = der(AIR0CabiA006010003.T); AIR0CabiA006010003.C * der(AIR0CabiA006010003.T) = AIR0CabiA006010003.port.Q_flow; AIR0CabiA007010003.T = AIR0CabiA007010003.port.T; AIR0CabiA007010003.der_T = der(AIR0CabiA007010003.T); AIR0CabiA007010003.C * der(AIR0CabiA007010003.T) = AIR0CabiA007010003.port.Q_flow; AIR0CabiA011010003.T = AIR0CabiA011010003.port.T; AIR0CabiA011010003.der_T = der(AIR0CabiA011010003.T); AIR0CabiA011010003.C * der(AIR0CabiA011010003.T) = AIR0CabiA011010003.port.Q_flow; AIR0CabiA012010003.T = AIR0CabiA012010003.port.T; AIR0CabiA012010003.der_T = der(AIR0CabiA012010003.T); AIR0CabiA012010003.C * der(AIR0CabiA012010003.T) = AIR0CabiA012010003.port.Q_flow; AIR0CabiA002011003.T = AIR0CabiA002011003.port.T; AIR0CabiA002011003.der_T = der(AIR0CabiA002011003.T); AIR0CabiA002011003.C * der(AIR0CabiA002011003.T) = AIR0CabiA002011003.port.Q_flow; AIR0CabiA003011003.T = AIR0CabiA003011003.port.T; AIR0CabiA003011003.der_T = der(AIR0CabiA003011003.T); AIR0CabiA003011003.C * der(AIR0CabiA003011003.T) = AIR0CabiA003011003.port.Q_flow; AIR0CabiA004011003.T = AIR0CabiA004011003.port.T; AIR0CabiA004011003.der_T = der(AIR0CabiA004011003.T); AIR0CabiA004011003.C * der(AIR0CabiA004011003.T) = AIR0CabiA004011003.port.Q_flow; AIR0CabiA005011003.T = AIR0CabiA005011003.port.T; AIR0CabiA005011003.der_T = der(AIR0CabiA005011003.T); AIR0CabiA005011003.C * der(AIR0CabiA005011003.T) = AIR0CabiA005011003.port.Q_flow; AIR0CabiA006011003.T = AIR0CabiA006011003.port.T; AIR0CabiA006011003.der_T = der(AIR0CabiA006011003.T); AIR0CabiA006011003.C * der(AIR0CabiA006011003.T) = AIR0CabiA006011003.port.Q_flow; AIR0CabiA007011003.T = AIR0CabiA007011003.port.T; AIR0CabiA007011003.der_T = der(AIR0CabiA007011003.T); AIR0CabiA007011003.C * der(AIR0CabiA007011003.T) = AIR0CabiA007011003.port.Q_flow; AIR0CabiA008011003.T = AIR0CabiA008011003.port.T; AIR0CabiA008011003.der_T = der(AIR0CabiA008011003.T); AIR0CabiA008011003.C * der(AIR0CabiA008011003.T) = AIR0CabiA008011003.port.Q_flow; AIR0CabiA009011003.T = AIR0CabiA009011003.port.T; AIR0CabiA009011003.der_T = der(AIR0CabiA009011003.T); AIR0CabiA009011003.C * der(AIR0CabiA009011003.T) = AIR0CabiA009011003.port.Q_flow; AIR0CabiA010011003.T = AIR0CabiA010011003.port.T; AIR0CabiA010011003.der_T = der(AIR0CabiA010011003.T); AIR0CabiA010011003.C * der(AIR0CabiA010011003.T) = AIR0CabiA010011003.port.Q_flow; AIR0CabiA011011003.T = AIR0CabiA011011003.port.T; AIR0CabiA011011003.der_T = der(AIR0CabiA011011003.T); AIR0CabiA011011003.C * der(AIR0CabiA011011003.T) = AIR0CabiA011011003.port.Q_flow; AIR0CabiA012011003.T = AIR0CabiA012011003.port.T; AIR0CabiA012011003.der_T = der(AIR0CabiA012011003.T); AIR0CabiA012011003.C * der(AIR0CabiA012011003.T) = AIR0CabiA012011003.port.Q_flow; AIR0CabiA002012003.T = AIR0CabiA002012003.port.T; AIR0CabiA002012003.der_T = der(AIR0CabiA002012003.T); AIR0CabiA002012003.C * der(AIR0CabiA002012003.T) = AIR0CabiA002012003.port.Q_flow; AIR0CabiA003012003.T = AIR0CabiA003012003.port.T; AIR0CabiA003012003.der_T = der(AIR0CabiA003012003.T); AIR0CabiA003012003.C * der(AIR0CabiA003012003.T) = AIR0CabiA003012003.port.Q_flow; AIR0CabiA004012003.T = AIR0CabiA004012003.port.T; AIR0CabiA004012003.der_T = der(AIR0CabiA004012003.T); AIR0CabiA004012003.C * der(AIR0CabiA004012003.T) = AIR0CabiA004012003.port.Q_flow; AIR0CabiA005012003.T = AIR0CabiA005012003.port.T; AIR0CabiA005012003.der_T = der(AIR0CabiA005012003.T); AIR0CabiA005012003.C * der(AIR0CabiA005012003.T) = AIR0CabiA005012003.port.Q_flow; AIR0CabiA006012003.T = AIR0CabiA006012003.port.T; AIR0CabiA006012003.der_T = der(AIR0CabiA006012003.T); AIR0CabiA006012003.C * der(AIR0CabiA006012003.T) = AIR0CabiA006012003.port.Q_flow; AIR0CabiA007012003.T = AIR0CabiA007012003.port.T; AIR0CabiA007012003.der_T = der(AIR0CabiA007012003.T); AIR0CabiA007012003.C * der(AIR0CabiA007012003.T) = AIR0CabiA007012003.port.Q_flow; AIR0CabiA008012003.T = AIR0CabiA008012003.port.T; AIR0CabiA008012003.der_T = der(AIR0CabiA008012003.T); AIR0CabiA008012003.C * der(AIR0CabiA008012003.T) = AIR0CabiA008012003.port.Q_flow; AIR0CabiA009012003.T = AIR0CabiA009012003.port.T; AIR0CabiA009012003.der_T = der(AIR0CabiA009012003.T); AIR0CabiA009012003.C * der(AIR0CabiA009012003.T) = AIR0CabiA009012003.port.Q_flow; AIR0CabiA010012003.T = AIR0CabiA010012003.port.T; AIR0CabiA010012003.der_T = der(AIR0CabiA010012003.T); AIR0CabiA010012003.C * der(AIR0CabiA010012003.T) = AIR0CabiA010012003.port.Q_flow; AIR0CabiA011012003.T = AIR0CabiA011012003.port.T; AIR0CabiA011012003.der_T = der(AIR0CabiA011012003.T); AIR0CabiA011012003.C * der(AIR0CabiA011012003.T) = AIR0CabiA011012003.port.Q_flow; AIR0CabiA012012003.T = AIR0CabiA012012003.port.T; AIR0CabiA012012003.der_T = der(AIR0CabiA012012003.T); AIR0CabiA012012003.C * der(AIR0CabiA012012003.T) = AIR0CabiA012012003.port.Q_flow; AIR0CabiA002013003.T = AIR0CabiA002013003.port.T; AIR0CabiA002013003.der_T = der(AIR0CabiA002013003.T); AIR0CabiA002013003.C * der(AIR0CabiA002013003.T) = AIR0CabiA002013003.port.Q_flow; AIR0CabiA003013003.T = AIR0CabiA003013003.port.T; AIR0CabiA003013003.der_T = der(AIR0CabiA003013003.T); AIR0CabiA003013003.C * der(AIR0CabiA003013003.T) = AIR0CabiA003013003.port.Q_flow; AIR0CabiA004013003.T = AIR0CabiA004013003.port.T; AIR0CabiA004013003.der_T = der(AIR0CabiA004013003.T); AIR0CabiA004013003.C * der(AIR0CabiA004013003.T) = AIR0CabiA004013003.port.Q_flow; AIR0CabiA005013003.T = AIR0CabiA005013003.port.T; AIR0CabiA005013003.der_T = der(AIR0CabiA005013003.T); AIR0CabiA005013003.C * der(AIR0CabiA005013003.T) = AIR0CabiA005013003.port.Q_flow; AIR0CabiA006013003.T = AIR0CabiA006013003.port.T; AIR0CabiA006013003.der_T = der(AIR0CabiA006013003.T); AIR0CabiA006013003.C * der(AIR0CabiA006013003.T) = AIR0CabiA006013003.port.Q_flow; AIR0CabiA007013003.T = AIR0CabiA007013003.port.T; AIR0CabiA007013003.der_T = der(AIR0CabiA007013003.T); AIR0CabiA007013003.C * der(AIR0CabiA007013003.T) = AIR0CabiA007013003.port.Q_flow; AIR0CabiA008013003.T = AIR0CabiA008013003.port.T; AIR0CabiA008013003.der_T = der(AIR0CabiA008013003.T); AIR0CabiA008013003.C * der(AIR0CabiA008013003.T) = AIR0CabiA008013003.port.Q_flow; AIR0CabiA009013003.T = AIR0CabiA009013003.port.T; AIR0CabiA009013003.der_T = der(AIR0CabiA009013003.T); AIR0CabiA009013003.C * der(AIR0CabiA009013003.T) = AIR0CabiA009013003.port.Q_flow; AIR0CabiA010013003.T = AIR0CabiA010013003.port.T; AIR0CabiA010013003.der_T = der(AIR0CabiA010013003.T); AIR0CabiA010013003.C * der(AIR0CabiA010013003.T) = AIR0CabiA010013003.port.Q_flow; AIR0CabiA011013003.T = AIR0CabiA011013003.port.T; AIR0CabiA011013003.der_T = der(AIR0CabiA011013003.T); AIR0CabiA011013003.C * der(AIR0CabiA011013003.T) = AIR0CabiA011013003.port.Q_flow; AIR0CabiA012013003.T = AIR0CabiA012013003.port.T; AIR0CabiA012013003.der_T = der(AIR0CabiA012013003.T); AIR0CabiA012013003.C * der(AIR0CabiA012013003.T) = AIR0CabiA012013003.port.Q_flow; AIR0CabiA002014003.T = AIR0CabiA002014003.port.T; AIR0CabiA002014003.der_T = der(AIR0CabiA002014003.T); AIR0CabiA002014003.C * der(AIR0CabiA002014003.T) = AIR0CabiA002014003.port.Q_flow; AIR0CabiA003014003.T = AIR0CabiA003014003.port.T; AIR0CabiA003014003.der_T = der(AIR0CabiA003014003.T); AIR0CabiA003014003.C * der(AIR0CabiA003014003.T) = AIR0CabiA003014003.port.Q_flow; AIR0CabiA004014003.T = AIR0CabiA004014003.port.T; AIR0CabiA004014003.der_T = der(AIR0CabiA004014003.T); AIR0CabiA004014003.C * der(AIR0CabiA004014003.T) = AIR0CabiA004014003.port.Q_flow; AIR0CabiA005014003.T = AIR0CabiA005014003.port.T; AIR0CabiA005014003.der_T = der(AIR0CabiA005014003.T); AIR0CabiA005014003.C * der(AIR0CabiA005014003.T) = AIR0CabiA005014003.port.Q_flow; AIR0CabiA006014003.T = AIR0CabiA006014003.port.T; AIR0CabiA006014003.der_T = der(AIR0CabiA006014003.T); AIR0CabiA006014003.C * der(AIR0CabiA006014003.T) = AIR0CabiA006014003.port.Q_flow; AIR0CabiA007014003.T = AIR0CabiA007014003.port.T; AIR0CabiA007014003.der_T = der(AIR0CabiA007014003.T); AIR0CabiA007014003.C * der(AIR0CabiA007014003.T) = AIR0CabiA007014003.port.Q_flow; AIR0CabiA008014003.T = AIR0CabiA008014003.port.T; AIR0CabiA008014003.der_T = der(AIR0CabiA008014003.T); AIR0CabiA008014003.C * der(AIR0CabiA008014003.T) = AIR0CabiA008014003.port.Q_flow; AIR0CabiA009014003.T = AIR0CabiA009014003.port.T; AIR0CabiA009014003.der_T = der(AIR0CabiA009014003.T); AIR0CabiA009014003.C * der(AIR0CabiA009014003.T) = AIR0CabiA009014003.port.Q_flow; AIR0CabiA010014003.T = AIR0CabiA010014003.port.T; AIR0CabiA010014003.der_T = der(AIR0CabiA010014003.T); AIR0CabiA010014003.C * der(AIR0CabiA010014003.T) = AIR0CabiA010014003.port.Q_flow; AIR0CabiA011014003.T = AIR0CabiA011014003.port.T; AIR0CabiA011014003.der_T = der(AIR0CabiA011014003.T); AIR0CabiA011014003.C * der(AIR0CabiA011014003.T) = AIR0CabiA011014003.port.Q_flow; AIR0CabiA012014003.T = AIR0CabiA012014003.port.T; AIR0CabiA012014003.der_T = der(AIR0CabiA012014003.T); AIR0CabiA012014003.C * der(AIR0CabiA012014003.T) = AIR0CabiA012014003.port.Q_flow; AIR0CabiA002015003.T = AIR0CabiA002015003.port.T; AIR0CabiA002015003.der_T = der(AIR0CabiA002015003.T); AIR0CabiA002015003.C * der(AIR0CabiA002015003.T) = AIR0CabiA002015003.port.Q_flow; AIR0CabiA003015003.T = AIR0CabiA003015003.port.T; AIR0CabiA003015003.der_T = der(AIR0CabiA003015003.T); AIR0CabiA003015003.C * der(AIR0CabiA003015003.T) = AIR0CabiA003015003.port.Q_flow; AIR0CabiA004015003.T = AIR0CabiA004015003.port.T; AIR0CabiA004015003.der_T = der(AIR0CabiA004015003.T); AIR0CabiA004015003.C * der(AIR0CabiA004015003.T) = AIR0CabiA004015003.port.Q_flow; AIR0CabiA005015003.T = AIR0CabiA005015003.port.T; AIR0CabiA005015003.der_T = der(AIR0CabiA005015003.T); AIR0CabiA005015003.C * der(AIR0CabiA005015003.T) = AIR0CabiA005015003.port.Q_flow; AIR0CabiA006015003.T = AIR0CabiA006015003.port.T; AIR0CabiA006015003.der_T = der(AIR0CabiA006015003.T); AIR0CabiA006015003.C * der(AIR0CabiA006015003.T) = AIR0CabiA006015003.port.Q_flow; AIR0CabiA007015003.T = AIR0CabiA007015003.port.T; AIR0CabiA007015003.der_T = der(AIR0CabiA007015003.T); AIR0CabiA007015003.C * der(AIR0CabiA007015003.T) = AIR0CabiA007015003.port.Q_flow; AIR0CabiA008015003.T = AIR0CabiA008015003.port.T; AIR0CabiA008015003.der_T = der(AIR0CabiA008015003.T); AIR0CabiA008015003.C * der(AIR0CabiA008015003.T) = AIR0CabiA008015003.port.Q_flow; AIR0CabiA009015003.T = AIR0CabiA009015003.port.T; AIR0CabiA009015003.der_T = der(AIR0CabiA009015003.T); AIR0CabiA009015003.C * der(AIR0CabiA009015003.T) = AIR0CabiA009015003.port.Q_flow; AIR0CabiA010015003.T = AIR0CabiA010015003.port.T; AIR0CabiA010015003.der_T = der(AIR0CabiA010015003.T); AIR0CabiA010015003.C * der(AIR0CabiA010015003.T) = AIR0CabiA010015003.port.Q_flow; AIR0CabiA011015003.T = AIR0CabiA011015003.port.T; AIR0CabiA011015003.der_T = der(AIR0CabiA011015003.T); AIR0CabiA011015003.C * der(AIR0CabiA011015003.T) = AIR0CabiA011015003.port.Q_flow; AIR0CabiA012015003.T = AIR0CabiA012015003.port.T; AIR0CabiA012015003.der_T = der(AIR0CabiA012015003.T); AIR0CabiA012015003.C * der(AIR0CabiA012015003.T) = AIR0CabiA012015003.port.Q_flow; AIR0CabiA012005002.T = AIR0CabiA012005002.port.T; AIR0CabiA012005002.der_T = der(AIR0CabiA012005002.T); AIR0CabiA012005002.C * der(AIR0CabiA012005002.T) = AIR0CabiA012005002.port.Q_flow; AIR0CabiA002006002.T = AIR0CabiA002006002.port.T; AIR0CabiA002006002.der_T = der(AIR0CabiA002006002.T); AIR0CabiA002006002.C * der(AIR0CabiA002006002.T) = AIR0CabiA002006002.port.Q_flow; AIR0CabiA003006002.T = AIR0CabiA003006002.port.T; AIR0CabiA003006002.der_T = der(AIR0CabiA003006002.T); AIR0CabiA003006002.C * der(AIR0CabiA003006002.T) = AIR0CabiA003006002.port.Q_flow; AIR0CabiA012006002.T = AIR0CabiA012006002.port.T; AIR0CabiA012006002.der_T = der(AIR0CabiA012006002.T); AIR0CabiA012006002.C * der(AIR0CabiA012006002.T) = AIR0CabiA012006002.port.Q_flow; AIR0CabiA002007002.T = AIR0CabiA002007002.port.T; AIR0CabiA002007002.der_T = der(AIR0CabiA002007002.T); AIR0CabiA002007002.C * der(AIR0CabiA002007002.T) = AIR0CabiA002007002.port.Q_flow; AIR0CabiA003007002.T = AIR0CabiA003007002.port.T; AIR0CabiA003007002.der_T = der(AIR0CabiA003007002.T); AIR0CabiA003007002.C * der(AIR0CabiA003007002.T) = AIR0CabiA003007002.port.Q_flow; AIR0CabiA012007002.T = AIR0CabiA012007002.port.T; AIR0CabiA012007002.der_T = der(AIR0CabiA012007002.T); AIR0CabiA012007002.C * der(AIR0CabiA012007002.T) = AIR0CabiA012007002.port.Q_flow; AIR0CabiA002008002.T = AIR0CabiA002008002.port.T; AIR0CabiA002008002.der_T = der(AIR0CabiA002008002.T); AIR0CabiA002008002.C * der(AIR0CabiA002008002.T) = AIR0CabiA002008002.port.Q_flow; AIR0CabiA003008002.T = AIR0CabiA003008002.port.T; AIR0CabiA003008002.der_T = der(AIR0CabiA003008002.T); AIR0CabiA003008002.C * der(AIR0CabiA003008002.T) = AIR0CabiA003008002.port.Q_flow; AIR0CabiA012008002.T = AIR0CabiA012008002.port.T; AIR0CabiA012008002.der_T = der(AIR0CabiA012008002.T); AIR0CabiA012008002.C * der(AIR0CabiA012008002.T) = AIR0CabiA012008002.port.Q_flow; AIR0CabiA002009002.T = AIR0CabiA002009002.port.T; AIR0CabiA002009002.der_T = der(AIR0CabiA002009002.T); AIR0CabiA002009002.C * der(AIR0CabiA002009002.T) = AIR0CabiA002009002.port.Q_flow; AIR0CabiA003009002.T = AIR0CabiA003009002.port.T; AIR0CabiA003009002.der_T = der(AIR0CabiA003009002.T); AIR0CabiA003009002.C * der(AIR0CabiA003009002.T) = AIR0CabiA003009002.port.Q_flow; AIR0CabiA012009002.T = AIR0CabiA012009002.port.T; AIR0CabiA012009002.der_T = der(AIR0CabiA012009002.T); AIR0CabiA012009002.C * der(AIR0CabiA012009002.T) = AIR0CabiA012009002.port.Q_flow; AIR0CabiA002010002.T = AIR0CabiA002010002.port.T; AIR0CabiA002010002.der_T = der(AIR0CabiA002010002.T); AIR0CabiA002010002.C * der(AIR0CabiA002010002.T) = AIR0CabiA002010002.port.Q_flow; AIR0CabiA003010002.T = AIR0CabiA003010002.port.T; AIR0CabiA003010002.der_T = der(AIR0CabiA003010002.T); AIR0CabiA003010002.C * der(AIR0CabiA003010002.T) = AIR0CabiA003010002.port.Q_flow; AIR0CabiA012010002.T = AIR0CabiA012010002.port.T; AIR0CabiA012010002.der_T = der(AIR0CabiA012010002.T); AIR0CabiA012010002.C * der(AIR0CabiA012010002.T) = AIR0CabiA012010002.port.Q_flow; AIR0CabiA002011002.T = AIR0CabiA002011002.port.T; AIR0CabiA002011002.der_T = der(AIR0CabiA002011002.T); AIR0CabiA002011002.C * der(AIR0CabiA002011002.T) = AIR0CabiA002011002.port.Q_flow; AIR0CabiA003011002.T = AIR0CabiA003011002.port.T; AIR0CabiA003011002.der_T = der(AIR0CabiA003011002.T); AIR0CabiA003011002.C * der(AIR0CabiA003011002.T) = AIR0CabiA003011002.port.Q_flow; AIR0CabiA012011002.T = AIR0CabiA012011002.port.T; AIR0CabiA012011002.der_T = der(AIR0CabiA012011002.T); AIR0CabiA012011002.C * der(AIR0CabiA012011002.T) = AIR0CabiA012011002.port.Q_flow; AIR0CabiA002012002.T = AIR0CabiA002012002.port.T; AIR0CabiA002012002.der_T = der(AIR0CabiA002012002.T); AIR0CabiA002012002.C * der(AIR0CabiA002012002.T) = AIR0CabiA002012002.port.Q_flow; AIR0CabiA003012002.T = AIR0CabiA003012002.port.T; AIR0CabiA003012002.der_T = der(AIR0CabiA003012002.T); AIR0CabiA003012002.C * der(AIR0CabiA003012002.T) = AIR0CabiA003012002.port.Q_flow; AIR0CabiA012012002.T = AIR0CabiA012012002.port.T; AIR0CabiA012012002.der_T = der(AIR0CabiA012012002.T); AIR0CabiA012012002.C * der(AIR0CabiA012012002.T) = AIR0CabiA012012002.port.Q_flow; AIR0CabiA002013002.T = AIR0CabiA002013002.port.T; AIR0CabiA002013002.der_T = der(AIR0CabiA002013002.T); AIR0CabiA002013002.C * der(AIR0CabiA002013002.T) = AIR0CabiA002013002.port.Q_flow; AIR0CabiA003013002.T = AIR0CabiA003013002.port.T; AIR0CabiA003013002.der_T = der(AIR0CabiA003013002.T); AIR0CabiA003013002.C * der(AIR0CabiA003013002.T) = AIR0CabiA003013002.port.Q_flow; AIR0CabiA012013002.T = AIR0CabiA012013002.port.T; AIR0CabiA012013002.der_T = der(AIR0CabiA012013002.T); AIR0CabiA012013002.C * der(AIR0CabiA012013002.T) = AIR0CabiA012013002.port.Q_flow; AIR0CabiA002014002.T = AIR0CabiA002014002.port.T; AIR0CabiA002014002.der_T = der(AIR0CabiA002014002.T); AIR0CabiA002014002.C * der(AIR0CabiA002014002.T) = AIR0CabiA002014002.port.Q_flow; AIR0CabiA003014002.T = AIR0CabiA003014002.port.T; AIR0CabiA003014002.der_T = der(AIR0CabiA003014002.T); AIR0CabiA003014002.C * der(AIR0CabiA003014002.T) = AIR0CabiA003014002.port.Q_flow; AIR0CabiA004014002.T = AIR0CabiA004014002.port.T; AIR0CabiA004014002.der_T = der(AIR0CabiA004014002.T); AIR0CabiA004014002.C * der(AIR0CabiA004014002.T) = AIR0CabiA004014002.port.Q_flow; AIR0CabiA005014002.T = AIR0CabiA005014002.port.T; AIR0CabiA005014002.der_T = der(AIR0CabiA005014002.T); AIR0CabiA005014002.C * der(AIR0CabiA005014002.T) = AIR0CabiA005014002.port.Q_flow; AIR0CabiA006014002.T = AIR0CabiA006014002.port.T; AIR0CabiA006014002.der_T = der(AIR0CabiA006014002.T); AIR0CabiA006014002.C * der(AIR0CabiA006014002.T) = AIR0CabiA006014002.port.Q_flow; AIR0CabiA007014002.T = AIR0CabiA007014002.port.T; AIR0CabiA007014002.der_T = der(AIR0CabiA007014002.T); AIR0CabiA007014002.C * der(AIR0CabiA007014002.T) = AIR0CabiA007014002.port.Q_flow; AIR0CabiA008014002.T = AIR0CabiA008014002.port.T; AIR0CabiA008014002.der_T = der(AIR0CabiA008014002.T); AIR0CabiA008014002.C * der(AIR0CabiA008014002.T) = AIR0CabiA008014002.port.Q_flow; AIR0CabiA009014002.T = AIR0CabiA009014002.port.T; AIR0CabiA009014002.der_T = der(AIR0CabiA009014002.T); AIR0CabiA009014002.C * der(AIR0CabiA009014002.T) = AIR0CabiA009014002.port.Q_flow; AIR0CabiA010014002.T = AIR0CabiA010014002.port.T; AIR0CabiA010014002.der_T = der(AIR0CabiA010014002.T); AIR0CabiA010014002.C * der(AIR0CabiA010014002.T) = AIR0CabiA010014002.port.Q_flow; AIR0CabiA011014002.T = AIR0CabiA011014002.port.T; AIR0CabiA011014002.der_T = der(AIR0CabiA011014002.T); AIR0CabiA011014002.C * der(AIR0CabiA011014002.T) = AIR0CabiA011014002.port.Q_flow; AIR0CabiA012014002.T = AIR0CabiA012014002.port.T; AIR0CabiA012014002.der_T = der(AIR0CabiA012014002.T); AIR0CabiA012014002.C * der(AIR0CabiA012014002.T) = AIR0CabiA012014002.port.Q_flow; AIR0CabiA002015002.T = AIR0CabiA002015002.port.T; AIR0CabiA002015002.der_T = der(AIR0CabiA002015002.T); AIR0CabiA002015002.C * der(AIR0CabiA002015002.T) = AIR0CabiA002015002.port.Q_flow; AIR0CabiA003015002.T = AIR0CabiA003015002.port.T; AIR0CabiA003015002.der_T = der(AIR0CabiA003015002.T); AIR0CabiA003015002.C * der(AIR0CabiA003015002.T) = AIR0CabiA003015002.port.Q_flow; AIR0CabiA004015002.T = AIR0CabiA004015002.port.T; AIR0CabiA004015002.der_T = der(AIR0CabiA004015002.T); AIR0CabiA004015002.C * der(AIR0CabiA004015002.T) = AIR0CabiA004015002.port.Q_flow; AIR0CabiA005015002.T = AIR0CabiA005015002.port.T; AIR0CabiA005015002.der_T = der(AIR0CabiA005015002.T); AIR0CabiA005015002.C * der(AIR0CabiA005015002.T) = AIR0CabiA005015002.port.Q_flow; AIR0CabiA006015002.T = AIR0CabiA006015002.port.T; AIR0CabiA006015002.der_T = der(AIR0CabiA006015002.T); AIR0CabiA006015002.C * der(AIR0CabiA006015002.T) = AIR0CabiA006015002.port.Q_flow; AIR0CabiA007015002.T = AIR0CabiA007015002.port.T; AIR0CabiA007015002.der_T = der(AIR0CabiA007015002.T); AIR0CabiA007015002.C * der(AIR0CabiA007015002.T) = AIR0CabiA007015002.port.Q_flow; AIR0CabiA008015002.T = AIR0CabiA008015002.port.T; AIR0CabiA008015002.der_T = der(AIR0CabiA008015002.T); AIR0CabiA008015002.C * der(AIR0CabiA008015002.T) = AIR0CabiA008015002.port.Q_flow; AIR0CabiA009015002.T = AIR0CabiA009015002.port.T; AIR0CabiA009015002.der_T = der(AIR0CabiA009015002.T); AIR0CabiA009015002.C * der(AIR0CabiA009015002.T) = AIR0CabiA009015002.port.Q_flow; AIR0CabiA010015002.T = AIR0CabiA010015002.port.T; AIR0CabiA010015002.der_T = der(AIR0CabiA010015002.T); AIR0CabiA010015002.C * der(AIR0CabiA010015002.T) = AIR0CabiA010015002.port.Q_flow; AIR0CabiA011015002.T = AIR0CabiA011015002.port.T; AIR0CabiA011015002.der_T = der(AIR0CabiA011015002.T); AIR0CabiA011015002.C * der(AIR0CabiA011015002.T) = AIR0CabiA011015002.port.Q_flow; AIR0CabiA012015002.T = AIR0CabiA012015002.port.T; AIR0CabiA012015002.der_T = der(AIR0CabiA012015002.T); AIR0CabiA012015002.C * der(AIR0CabiA012015002.T) = AIR0CabiA012015002.port.Q_flow; AIR0CabiA002004002.T = AIR0CabiA002004002.port.T; AIR0CabiA002004002.der_T = der(AIR0CabiA002004002.T); AIR0CabiA002004002.C * der(AIR0CabiA002004002.T) = AIR0CabiA002004002.port.Q_flow; AIR0CabiA003004002.T = AIR0CabiA003004002.port.T; AIR0CabiA003004002.der_T = der(AIR0CabiA003004002.T); AIR0CabiA003004002.C * der(AIR0CabiA003004002.T) = AIR0CabiA003004002.port.Q_flow; AIR0CabiA012004002.T = AIR0CabiA012004002.port.T; AIR0CabiA012004002.der_T = der(AIR0CabiA012004002.T); AIR0CabiA012004002.C * der(AIR0CabiA012004002.T) = AIR0CabiA012004002.port.Q_flow; AIR0CabiA002005002.T = AIR0CabiA002005002.port.T; AIR0CabiA002005002.der_T = der(AIR0CabiA002005002.T); AIR0CabiA002005002.C * der(AIR0CabiA002005002.T) = AIR0CabiA002005002.port.Q_flow; AIR0CabiA003005002.T = AIR0CabiA003005002.port.T; AIR0CabiA003005002.der_T = der(AIR0CabiA003005002.T); AIR0CabiA003005002.C * der(AIR0CabiA003005002.T) = AIR0CabiA003005002.port.Q_flow; AIR0CabiA002003002.T = AIR0CabiA002003002.port.T; AIR0CabiA002003002.der_T = der(AIR0CabiA002003002.T); AIR0CabiA002003002.C * der(AIR0CabiA002003002.T) = AIR0CabiA002003002.port.Q_flow; AIR0CabiA003003002.T = AIR0CabiA003003002.port.T; AIR0CabiA003003002.der_T = der(AIR0CabiA003003002.T); AIR0CabiA003003002.C * der(AIR0CabiA003003002.T) = AIR0CabiA003003002.port.Q_flow; AIR0CabiA004003002.T = AIR0CabiA004003002.port.T; AIR0CabiA004003002.der_T = der(AIR0CabiA004003002.T); AIR0CabiA004003002.C * der(AIR0CabiA004003002.T) = AIR0CabiA004003002.port.Q_flow; AIR0CabiA005003002.T = AIR0CabiA005003002.port.T; AIR0CabiA005003002.der_T = der(AIR0CabiA005003002.T); AIR0CabiA005003002.C * der(AIR0CabiA005003002.T) = AIR0CabiA005003002.port.Q_flow; AIR0CabiA006003002.T = AIR0CabiA006003002.port.T; AIR0CabiA006003002.der_T = der(AIR0CabiA006003002.T); AIR0CabiA006003002.C * der(AIR0CabiA006003002.T) = AIR0CabiA006003002.port.Q_flow; AIR0CabiA007003002.T = AIR0CabiA007003002.port.T; AIR0CabiA007003002.der_T = der(AIR0CabiA007003002.T); AIR0CabiA007003002.C * der(AIR0CabiA007003002.T) = AIR0CabiA007003002.port.Q_flow; AIR0CabiA008003002.T = AIR0CabiA008003002.port.T; AIR0CabiA008003002.der_T = der(AIR0CabiA008003002.T); AIR0CabiA008003002.C * der(AIR0CabiA008003002.T) = AIR0CabiA008003002.port.Q_flow; AIR0CabiA009003002.T = AIR0CabiA009003002.port.T; AIR0CabiA009003002.der_T = der(AIR0CabiA009003002.T); AIR0CabiA009003002.C * der(AIR0CabiA009003002.T) = AIR0CabiA009003002.port.Q_flow; AIR0CabiA010003002.T = AIR0CabiA010003002.port.T; AIR0CabiA010003002.der_T = der(AIR0CabiA010003002.T); AIR0CabiA010003002.C * der(AIR0CabiA010003002.T) = AIR0CabiA010003002.port.Q_flow; AIR0CabiA011003002.T = AIR0CabiA011003002.port.T; AIR0CabiA011003002.der_T = der(AIR0CabiA011003002.T); AIR0CabiA011003002.C * der(AIR0CabiA011003002.T) = AIR0CabiA011003002.port.Q_flow; AIR0CabiA012003002.T = AIR0CabiA012003002.port.T; AIR0CabiA012003002.der_T = der(AIR0CabiA012003002.T); AIR0CabiA012003002.C * der(AIR0CabiA012003002.T) = AIR0CabiA012003002.port.Q_flow; AIR0CabiA002002002.T = AIR0CabiA002002002.port.T; AIR0CabiA002002002.der_T = der(AIR0CabiA002002002.T); AIR0CabiA002002002.C * der(AIR0CabiA002002002.T) = AIR0CabiA002002002.port.Q_flow; AIR0CabiA003002002.T = AIR0CabiA003002002.port.T; AIR0CabiA003002002.der_T = der(AIR0CabiA003002002.T); AIR0CabiA003002002.C * der(AIR0CabiA003002002.T) = AIR0CabiA003002002.port.Q_flow; AIR0CabiA004002002.T = AIR0CabiA004002002.port.T; AIR0CabiA004002002.der_T = der(AIR0CabiA004002002.T); AIR0CabiA004002002.C * der(AIR0CabiA004002002.T) = AIR0CabiA004002002.port.Q_flow; AIR0CabiA005002002.T = AIR0CabiA005002002.port.T; AIR0CabiA005002002.der_T = der(AIR0CabiA005002002.T); AIR0CabiA005002002.C * der(AIR0CabiA005002002.T) = AIR0CabiA005002002.port.Q_flow; AIR0CabiA006002002.T = AIR0CabiA006002002.port.T; AIR0CabiA006002002.der_T = der(AIR0CabiA006002002.T); AIR0CabiA006002002.C * der(AIR0CabiA006002002.T) = AIR0CabiA006002002.port.Q_flow; AIR0CabiA007002002.T = AIR0CabiA007002002.port.T; AIR0CabiA007002002.der_T = der(AIR0CabiA007002002.T); AIR0CabiA007002002.C * der(AIR0CabiA007002002.T) = AIR0CabiA007002002.port.Q_flow; AIR0CabiA008002002.T = AIR0CabiA008002002.port.T; AIR0CabiA008002002.der_T = der(AIR0CabiA008002002.T); AIR0CabiA008002002.C * der(AIR0CabiA008002002.T) = AIR0CabiA008002002.port.Q_flow; AIR0CabiA009002002.T = AIR0CabiA009002002.port.T; AIR0CabiA009002002.der_T = der(AIR0CabiA009002002.T); AIR0CabiA009002002.C * der(AIR0CabiA009002002.T) = AIR0CabiA009002002.port.Q_flow; AIR0CabiA010002002.T = AIR0CabiA010002002.port.T; AIR0CabiA010002002.der_T = der(AIR0CabiA010002002.T); AIR0CabiA010002002.C * der(AIR0CabiA010002002.T) = AIR0CabiA010002002.port.Q_flow; AIR0CabiA011002002.T = AIR0CabiA011002002.port.T; AIR0CabiA011002002.der_T = der(AIR0CabiA011002002.T); AIR0CabiA011002002.C * der(AIR0CabiA011002002.T) = AIR0CabiA011002002.port.Q_flow; AIR0CabiA012002002.T = AIR0CabiA012002002.port.T; AIR0CabiA012002002.der_T = der(AIR0CabiA012002002.T); AIR0CabiA012002002.C * der(AIR0CabiA012002002.T) = AIR0CabiA012002002.port.Q_flow; ST0CabiA008008003.T = ST0CabiA008008003.port.T; ST0CabiA008008003.der_T = der(ST0CabiA008008003.T); ST0CabiA008008003.C * der(ST0CabiA008008003.T) = ST0CabiA008008003.port.Q_flow; ST0CabiA009008003.T = ST0CabiA009008003.port.T; ST0CabiA009008003.der_T = der(ST0CabiA009008003.T); ST0CabiA009008003.C * der(ST0CabiA009008003.T) = ST0CabiA009008003.port.Q_flow; ST0CabiA010008003.T = ST0CabiA010008003.port.T; ST0CabiA010008003.der_T = der(ST0CabiA010008003.T); ST0CabiA010008003.C * der(ST0CabiA010008003.T) = ST0CabiA010008003.port.Q_flow; ST0CabiA008009003.T = ST0CabiA008009003.port.T; ST0CabiA008009003.der_T = der(ST0CabiA008009003.T); ST0CabiA008009003.C * der(ST0CabiA008009003.T) = ST0CabiA008009003.port.Q_flow; ST0CabiA009009003.T = ST0CabiA009009003.port.T; ST0CabiA009009003.der_T = der(ST0CabiA009009003.T); ST0CabiA009009003.C * der(ST0CabiA009009003.T) = ST0CabiA009009003.port.Q_flow; ST0CabiA010009003.T = ST0CabiA010009003.port.T; ST0CabiA010009003.der_T = der(ST0CabiA010009003.T); ST0CabiA010009003.C * der(ST0CabiA010009003.T) = ST0CabiA010009003.port.Q_flow; ST0CabiA008010003.T = ST0CabiA008010003.port.T; ST0CabiA008010003.der_T = der(ST0CabiA008010003.T); ST0CabiA008010003.C * der(ST0CabiA008010003.T) = ST0CabiA008010003.port.Q_flow; ST0CabiA009010003.T = ST0CabiA009010003.port.T; ST0CabiA009010003.der_T = der(ST0CabiA009010003.T); ST0CabiA009010003.C * der(ST0CabiA009010003.T) = ST0CabiA009010003.port.Q_flow; ST0CabiA010010003.T = ST0CabiA010010003.port.T; ST0CabiA010010003.der_T = der(ST0CabiA010010003.T); ST0CabiA010010003.C * der(ST0CabiA010010003.T) = ST0CabiA010010003.port.Q_flow; IC30CabiA004004004.T = IC30CabiA004004004.port.T; IC30CabiA004004004.der_T = der(IC30CabiA004004004.T); IC30CabiA004004004.C * der(IC30CabiA004004004.T) = IC30CabiA004004004.port.Q_flow; IC30CabiA005004004.T = IC30CabiA005004004.port.T; IC30CabiA005004004.der_T = der(IC30CabiA005004004.T); IC30CabiA005004004.C * der(IC30CabiA005004004.T) = IC30CabiA005004004.port.Q_flow; IC30CabiA006004004.T = IC30CabiA006004004.port.T; IC30CabiA006004004.der_T = der(IC30CabiA006004004.T); IC30CabiA006004004.C * der(IC30CabiA006004004.T) = IC30CabiA006004004.port.Q_flow; IC30CabiA007004004.T = IC30CabiA007004004.port.T; IC30CabiA007004004.der_T = der(IC30CabiA007004004.T); IC30CabiA007004004.C * der(IC30CabiA007004004.T) = IC30CabiA007004004.port.Q_flow; IC30CabiA004005004.T = IC30CabiA004005004.port.T; IC30CabiA004005004.der_T = der(IC30CabiA004005004.T); IC30CabiA004005004.C * der(IC30CabiA004005004.T) = IC30CabiA004005004.port.Q_flow; IC30CabiA005005004.T = IC30CabiA005005004.port.T; IC30CabiA005005004.der_T = der(IC30CabiA005005004.T); IC30CabiA005005004.C * der(IC30CabiA005005004.T) = IC30CabiA005005004.port.Q_flow; IC30CabiA006005004.T = IC30CabiA006005004.port.T; IC30CabiA006005004.der_T = der(IC30CabiA006005004.T); IC30CabiA006005004.C * der(IC30CabiA006005004.T) = IC30CabiA006005004.port.Q_flow; IC30CabiA007005004.T = IC30CabiA007005004.port.T; IC30CabiA007005004.der_T = der(IC30CabiA007005004.T); IC30CabiA007005004.C * der(IC30CabiA007005004.T) = IC30CabiA007005004.port.Q_flow; IC30CabiA004006004.T = IC30CabiA004006004.port.T; IC30CabiA004006004.der_T = der(IC30CabiA004006004.T); IC30CabiA004006004.C * der(IC30CabiA004006004.T) = IC30CabiA004006004.port.Q_flow; IC30CabiA005006004.T = IC30CabiA005006004.port.T; IC30CabiA005006004.der_T = der(IC30CabiA005006004.T); IC30CabiA005006004.C * der(IC30CabiA005006004.T) = IC30CabiA005006004.port.Q_flow; IC30CabiA006006004.T = IC30CabiA006006004.port.T; IC30CabiA006006004.der_T = der(IC30CabiA006006004.T); IC30CabiA006006004.C * der(IC30CabiA006006004.T) = IC30CabiA006006004.port.Q_flow; IC30CabiA007006004.T = IC30CabiA007006004.port.T; IC30CabiA007006004.der_T = der(IC30CabiA007006004.T); IC30CabiA007006004.C * der(IC30CabiA007006004.T) = IC30CabiA007006004.port.Q_flow; IC20CabiA008008004.T = IC20CabiA008008004.port.T; IC20CabiA008008004.der_T = der(IC20CabiA008008004.T); IC20CabiA008008004.C * der(IC20CabiA008008004.T) = IC20CabiA008008004.port.Q_flow; IC20CabiA009008004.T = IC20CabiA009008004.port.T; IC20CabiA009008004.der_T = der(IC20CabiA009008004.T); IC20CabiA009008004.C * der(IC20CabiA009008004.T) = IC20CabiA009008004.port.Q_flow; IC20CabiA010008004.T = IC20CabiA010008004.port.T; IC20CabiA010008004.der_T = der(IC20CabiA010008004.T); IC20CabiA010008004.C * der(IC20CabiA010008004.T) = IC20CabiA010008004.port.Q_flow; IC20CabiA008009004.T = IC20CabiA008009004.port.T; IC20CabiA008009004.der_T = der(IC20CabiA008009004.T); IC20CabiA008009004.C * der(IC20CabiA008009004.T) = IC20CabiA008009004.port.Q_flow; IC20CabiA009009004.T = IC20CabiA009009004.port.T; IC20CabiA009009004.der_T = der(IC20CabiA009009004.T); IC20CabiA009009004.C * der(IC20CabiA009009004.T) = IC20CabiA009009004.port.Q_flow; IC20CabiA010009004.T = IC20CabiA010009004.port.T; IC20CabiA010009004.der_T = der(IC20CabiA010009004.T); IC20CabiA010009004.C * der(IC20CabiA010009004.T) = IC20CabiA010009004.port.Q_flow; IC20CabiA008010004.T = IC20CabiA008010004.port.T; IC20CabiA008010004.der_T = der(IC20CabiA008010004.T); IC20CabiA008010004.C * der(IC20CabiA008010004.T) = IC20CabiA008010004.port.Q_flow; IC20CabiA009010004.T = IC20CabiA009010004.port.T; IC20CabiA009010004.der_T = der(IC20CabiA009010004.T); IC20CabiA009010004.C * der(IC20CabiA009010004.T) = IC20CabiA009010004.port.Q_flow; IC20CabiA010010004.T = IC20CabiA010010004.port.T; IC20CabiA010010004.der_T = der(IC20CabiA010010004.T); IC20CabiA010010004.C * der(IC20CabiA010010004.T) = IC20CabiA010010004.port.Q_flow; IC60CabiA004011004.T = IC60CabiA004011004.port.T; IC60CabiA004011004.der_T = der(IC60CabiA004011004.T); IC60CabiA004011004.C * der(IC60CabiA004011004.T) = IC60CabiA004011004.port.Q_flow; IC60CabiA005011004.T = IC60CabiA005011004.port.T; IC60CabiA005011004.der_T = der(IC60CabiA005011004.T); IC60CabiA005011004.C * der(IC60CabiA005011004.T) = IC60CabiA005011004.port.Q_flow; IC60CabiA006011004.T = IC60CabiA006011004.port.T; IC60CabiA006011004.der_T = der(IC60CabiA006011004.T); IC60CabiA006011004.C * der(IC60CabiA006011004.T) = IC60CabiA006011004.port.Q_flow; IC60CabiA004012004.T = IC60CabiA004012004.port.T; IC60CabiA004012004.der_T = der(IC60CabiA004012004.T); IC60CabiA004012004.C * der(IC60CabiA004012004.T) = IC60CabiA004012004.port.Q_flow; IC60CabiA005012004.T = IC60CabiA005012004.port.T; IC60CabiA005012004.der_T = der(IC60CabiA005012004.T); IC60CabiA005012004.C * der(IC60CabiA005012004.T) = IC60CabiA005012004.port.Q_flow; IC60CabiA006012004.T = IC60CabiA006012004.port.T; IC60CabiA006012004.der_T = der(IC60CabiA006012004.T); IC60CabiA006012004.C * der(IC60CabiA006012004.T) = IC60CabiA006012004.port.Q_flow; IC60CabiA004013004.T = IC60CabiA004013004.port.T; IC60CabiA004013004.der_T = der(IC60CabiA004013004.T); IC60CabiA004013004.C * der(IC60CabiA004013004.T) = IC60CabiA004013004.port.Q_flow; IC60CabiA005013004.T = IC60CabiA005013004.port.T; IC60CabiA005013004.der_T = der(IC60CabiA005013004.T); IC60CabiA005013004.C * der(IC60CabiA005013004.T) = IC60CabiA005013004.port.Q_flow; IC60CabiA006013004.T = IC60CabiA006013004.port.T; IC60CabiA006013004.der_T = der(IC60CabiA006013004.T); IC60CabiA006013004.C * der(IC60CabiA006013004.T) = IC60CabiA006013004.port.Q_flow; PWB0CabiA003011005.T = PWB0CabiA003011005.port.T; PWB0CabiA003011005.der_T = der(PWB0CabiA003011005.T); PWB0CabiA003011005.C * der(PWB0CabiA003011005.T) = PWB0CabiA003011005.port.Q_flow; PWB0CabiA004011005.T = PWB0CabiA004011005.port.T; PWB0CabiA004011005.der_T = der(PWB0CabiA004011005.T); PWB0CabiA004011005.C * der(PWB0CabiA004011005.T) = PWB0CabiA004011005.port.Q_flow; PWB0CabiA005011005.T = PWB0CabiA005011005.port.T; PWB0CabiA005011005.der_T = der(PWB0CabiA005011005.T); PWB0CabiA005011005.C * der(PWB0CabiA005011005.T) = PWB0CabiA005011005.port.Q_flow; PWB0CabiA006011005.T = PWB0CabiA006011005.port.T; PWB0CabiA006011005.der_T = der(PWB0CabiA006011005.T); PWB0CabiA006011005.C * der(PWB0CabiA006011005.T) = PWB0CabiA006011005.port.Q_flow; PWB0CabiA007011005.T = PWB0CabiA007011005.port.T; PWB0CabiA007011005.der_T = der(PWB0CabiA007011005.T); PWB0CabiA007011005.C * der(PWB0CabiA007011005.T) = PWB0CabiA007011005.port.Q_flow; PWB0CabiA008011005.T = PWB0CabiA008011005.port.T; PWB0CabiA008011005.der_T = der(PWB0CabiA008011005.T); PWB0CabiA008011005.C * der(PWB0CabiA008011005.T) = PWB0CabiA008011005.port.Q_flow; PWB0CabiA009011005.T = PWB0CabiA009011005.port.T; PWB0CabiA009011005.der_T = der(PWB0CabiA009011005.T); PWB0CabiA009011005.C * der(PWB0CabiA009011005.T) = PWB0CabiA009011005.port.Q_flow; PWB0CabiA010011005.T = PWB0CabiA010011005.port.T; PWB0CabiA010011005.der_T = der(PWB0CabiA010011005.T); PWB0CabiA010011005.C * der(PWB0CabiA010011005.T) = PWB0CabiA010011005.port.Q_flow; PWB0CabiA011011005.T = PWB0CabiA011011005.port.T; PWB0CabiA011011005.der_T = der(PWB0CabiA011011005.T); PWB0CabiA011011005.C * der(PWB0CabiA011011005.T) = PWB0CabiA011011005.port.Q_flow; PWB0CabiA003012005.T = PWB0CabiA003012005.port.T; PWB0CabiA003012005.der_T = der(PWB0CabiA003012005.T); PWB0CabiA003012005.C * der(PWB0CabiA003012005.T) = PWB0CabiA003012005.port.Q_flow; PWB0CabiA004012005.T = PWB0CabiA004012005.port.T; PWB0CabiA004012005.der_T = der(PWB0CabiA004012005.T); PWB0CabiA004012005.C * der(PWB0CabiA004012005.T) = PWB0CabiA004012005.port.Q_flow; PWB0CabiA005012005.T = PWB0CabiA005012005.port.T; PWB0CabiA005012005.der_T = der(PWB0CabiA005012005.T); PWB0CabiA005012005.C * der(PWB0CabiA005012005.T) = PWB0CabiA005012005.port.Q_flow; PWB0CabiA006012005.T = PWB0CabiA006012005.port.T; PWB0CabiA006012005.der_T = der(PWB0CabiA006012005.T); PWB0CabiA006012005.C * der(PWB0CabiA006012005.T) = PWB0CabiA006012005.port.Q_flow; PWB0CabiA007012005.T = PWB0CabiA007012005.port.T; PWB0CabiA007012005.der_T = der(PWB0CabiA007012005.T); PWB0CabiA007012005.C * der(PWB0CabiA007012005.T) = PWB0CabiA007012005.port.Q_flow; PWB0CabiA008012005.T = PWB0CabiA008012005.port.T; PWB0CabiA008012005.der_T = der(PWB0CabiA008012005.T); PWB0CabiA008012005.C * der(PWB0CabiA008012005.T) = PWB0CabiA008012005.port.Q_flow; PWB0CabiA009012005.T = PWB0CabiA009012005.port.T; PWB0CabiA009012005.der_T = der(PWB0CabiA009012005.T); PWB0CabiA009012005.C * der(PWB0CabiA009012005.T) = PWB0CabiA009012005.port.Q_flow; PWB0CabiA010012005.T = PWB0CabiA010012005.port.T; PWB0CabiA010012005.der_T = der(PWB0CabiA010012005.T); PWB0CabiA010012005.C * der(PWB0CabiA010012005.T) = PWB0CabiA010012005.port.Q_flow; PWB0CabiA011012005.T = PWB0CabiA011012005.port.T; PWB0CabiA011012005.der_T = der(PWB0CabiA011012005.T); PWB0CabiA011012005.C * der(PWB0CabiA011012005.T) = PWB0CabiA011012005.port.Q_flow; PWB0CabiA003013005.T = PWB0CabiA003013005.port.T; PWB0CabiA003013005.der_T = der(PWB0CabiA003013005.T); PWB0CabiA003013005.C * der(PWB0CabiA003013005.T) = PWB0CabiA003013005.port.Q_flow; PWB0CabiA004013005.T = PWB0CabiA004013005.port.T; PWB0CabiA004013005.der_T = der(PWB0CabiA004013005.T); PWB0CabiA004013005.C * der(PWB0CabiA004013005.T) = PWB0CabiA004013005.port.Q_flow; PWB0CabiA005013005.T = PWB0CabiA005013005.port.T; PWB0CabiA005013005.der_T = der(PWB0CabiA005013005.T); PWB0CabiA005013005.C * der(PWB0CabiA005013005.T) = PWB0CabiA005013005.port.Q_flow; PWB0CabiA006013005.T = PWB0CabiA006013005.port.T; PWB0CabiA006013005.der_T = der(PWB0CabiA006013005.T); PWB0CabiA006013005.C * der(PWB0CabiA006013005.T) = PWB0CabiA006013005.port.Q_flow; PWB0CabiA007013005.T = PWB0CabiA007013005.port.T; PWB0CabiA007013005.der_T = der(PWB0CabiA007013005.T); PWB0CabiA007013005.C * der(PWB0CabiA007013005.T) = PWB0CabiA007013005.port.Q_flow; PWB0CabiA008013005.T = PWB0CabiA008013005.port.T; PWB0CabiA008013005.der_T = der(PWB0CabiA008013005.T); PWB0CabiA008013005.C * der(PWB0CabiA008013005.T) = PWB0CabiA008013005.port.Q_flow; PWB0CabiA009013005.T = PWB0CabiA009013005.port.T; PWB0CabiA009013005.der_T = der(PWB0CabiA009013005.T); PWB0CabiA009013005.C * der(PWB0CabiA009013005.T) = PWB0CabiA009013005.port.Q_flow; PWB0CabiA010013005.T = PWB0CabiA010013005.port.T; PWB0CabiA010013005.der_T = der(PWB0CabiA010013005.T); PWB0CabiA010013005.C * der(PWB0CabiA010013005.T) = PWB0CabiA010013005.port.Q_flow; PWB0CabiA011013005.T = PWB0CabiA011013005.port.T; PWB0CabiA011013005.der_T = der(PWB0CabiA011013005.T); PWB0CabiA011013005.C * der(PWB0CabiA011013005.T) = PWB0CabiA011013005.port.Q_flow; PWB0CabiA003014005.T = PWB0CabiA003014005.port.T; PWB0CabiA003014005.der_T = der(PWB0CabiA003014005.T); PWB0CabiA003014005.C * der(PWB0CabiA003014005.T) = PWB0CabiA003014005.port.Q_flow; PWB0CabiA004014005.T = PWB0CabiA004014005.port.T; PWB0CabiA004014005.der_T = der(PWB0CabiA004014005.T); PWB0CabiA004014005.C * der(PWB0CabiA004014005.T) = PWB0CabiA004014005.port.Q_flow; PWB0CabiA005014005.T = PWB0CabiA005014005.port.T; PWB0CabiA005014005.der_T = der(PWB0CabiA005014005.T); PWB0CabiA005014005.C * der(PWB0CabiA005014005.T) = PWB0CabiA005014005.port.Q_flow; PWB0CabiA006014005.T = PWB0CabiA006014005.port.T; PWB0CabiA006014005.der_T = der(PWB0CabiA006014005.T); PWB0CabiA006014005.C * der(PWB0CabiA006014005.T) = PWB0CabiA006014005.port.Q_flow; PWB0CabiA007014005.T = PWB0CabiA007014005.port.T; PWB0CabiA007014005.der_T = der(PWB0CabiA007014005.T); PWB0CabiA007014005.C * der(PWB0CabiA007014005.T) = PWB0CabiA007014005.port.Q_flow; PWB0CabiA008014005.T = PWB0CabiA008014005.port.T; PWB0CabiA008014005.der_T = der(PWB0CabiA008014005.T); PWB0CabiA008014005.C * der(PWB0CabiA008014005.T) = PWB0CabiA008014005.port.Q_flow; PWB0CabiA009014005.T = PWB0CabiA009014005.port.T; PWB0CabiA009014005.der_T = der(PWB0CabiA009014005.T); PWB0CabiA009014005.C * der(PWB0CabiA009014005.T) = PWB0CabiA009014005.port.Q_flow; PWB0CabiA010014005.T = PWB0CabiA010014005.port.T; PWB0CabiA010014005.der_T = der(PWB0CabiA010014005.T); PWB0CabiA010014005.C * der(PWB0CabiA010014005.T) = PWB0CabiA010014005.port.Q_flow; PWB0CabiA011014005.T = PWB0CabiA011014005.port.T; PWB0CabiA011014005.der_T = der(PWB0CabiA011014005.T); PWB0CabiA011014005.C * der(PWB0CabiA011014005.T) = PWB0CabiA011014005.port.Q_flow; PWB0CabiA003006005.T = PWB0CabiA003006005.port.T; PWB0CabiA003006005.der_T = der(PWB0CabiA003006005.T); PWB0CabiA003006005.C * der(PWB0CabiA003006005.T) = PWB0CabiA003006005.port.Q_flow; PWB0CabiA004006005.T = PWB0CabiA004006005.port.T; PWB0CabiA004006005.der_T = der(PWB0CabiA004006005.T); PWB0CabiA004006005.C * der(PWB0CabiA004006005.T) = PWB0CabiA004006005.port.Q_flow; PWB0CabiA005006005.T = PWB0CabiA005006005.port.T; PWB0CabiA005006005.der_T = der(PWB0CabiA005006005.T); PWB0CabiA005006005.C * der(PWB0CabiA005006005.T) = PWB0CabiA005006005.port.Q_flow; PWB0CabiA006006005.T = PWB0CabiA006006005.port.T; PWB0CabiA006006005.der_T = der(PWB0CabiA006006005.T); PWB0CabiA006006005.C * der(PWB0CabiA006006005.T) = PWB0CabiA006006005.port.Q_flow; PWB0CabiA007006005.T = PWB0CabiA007006005.port.T; PWB0CabiA007006005.der_T = der(PWB0CabiA007006005.T); PWB0CabiA007006005.C * der(PWB0CabiA007006005.T) = PWB0CabiA007006005.port.Q_flow; PWB0CabiA008006005.T = PWB0CabiA008006005.port.T; PWB0CabiA008006005.der_T = der(PWB0CabiA008006005.T); PWB0CabiA008006005.C * der(PWB0CabiA008006005.T) = PWB0CabiA008006005.port.Q_flow; PWB0CabiA009006005.T = PWB0CabiA009006005.port.T; PWB0CabiA009006005.der_T = der(PWB0CabiA009006005.T); PWB0CabiA009006005.C * der(PWB0CabiA009006005.T) = PWB0CabiA009006005.port.Q_flow; PWB0CabiA010006005.T = PWB0CabiA010006005.port.T; PWB0CabiA010006005.der_T = der(PWB0CabiA010006005.T); PWB0CabiA010006005.C * der(PWB0CabiA010006005.T) = PWB0CabiA010006005.port.Q_flow; PWB0CabiA011006005.T = PWB0CabiA011006005.port.T; PWB0CabiA011006005.der_T = der(PWB0CabiA011006005.T); PWB0CabiA011006005.C * der(PWB0CabiA011006005.T) = PWB0CabiA011006005.port.Q_flow; PWB0CabiA003007005.T = PWB0CabiA003007005.port.T; PWB0CabiA003007005.der_T = der(PWB0CabiA003007005.T); PWB0CabiA003007005.C * der(PWB0CabiA003007005.T) = PWB0CabiA003007005.port.Q_flow; PWB0CabiA004007005.T = PWB0CabiA004007005.port.T; PWB0CabiA004007005.der_T = der(PWB0CabiA004007005.T); PWB0CabiA004007005.C * der(PWB0CabiA004007005.T) = PWB0CabiA004007005.port.Q_flow; PWB0CabiA005007005.T = PWB0CabiA005007005.port.T; PWB0CabiA005007005.der_T = der(PWB0CabiA005007005.T); PWB0CabiA005007005.C * der(PWB0CabiA005007005.T) = PWB0CabiA005007005.port.Q_flow; PWB0CabiA006007005.T = PWB0CabiA006007005.port.T; PWB0CabiA006007005.der_T = der(PWB0CabiA006007005.T); PWB0CabiA006007005.C * der(PWB0CabiA006007005.T) = PWB0CabiA006007005.port.Q_flow; PWB0CabiA007007005.T = PWB0CabiA007007005.port.T; PWB0CabiA007007005.der_T = der(PWB0CabiA007007005.T); PWB0CabiA007007005.C * der(PWB0CabiA007007005.T) = PWB0CabiA007007005.port.Q_flow; PWB0CabiA008007005.T = PWB0CabiA008007005.port.T; PWB0CabiA008007005.der_T = der(PWB0CabiA008007005.T); PWB0CabiA008007005.C * der(PWB0CabiA008007005.T) = PWB0CabiA008007005.port.Q_flow; PWB0CabiA009007005.T = PWB0CabiA009007005.port.T; PWB0CabiA009007005.der_T = der(PWB0CabiA009007005.T); PWB0CabiA009007005.C * der(PWB0CabiA009007005.T) = PWB0CabiA009007005.port.Q_flow; PWB0CabiA010007005.T = PWB0CabiA010007005.port.T; PWB0CabiA010007005.der_T = der(PWB0CabiA010007005.T); PWB0CabiA010007005.C * der(PWB0CabiA010007005.T) = PWB0CabiA010007005.port.Q_flow; PWB0CabiA011007005.T = PWB0CabiA011007005.port.T; PWB0CabiA011007005.der_T = der(PWB0CabiA011007005.T); PWB0CabiA011007005.C * der(PWB0CabiA011007005.T) = PWB0CabiA011007005.port.Q_flow; PWB0CabiA003008005.T = PWB0CabiA003008005.port.T; PWB0CabiA003008005.der_T = der(PWB0CabiA003008005.T); PWB0CabiA003008005.C * der(PWB0CabiA003008005.T) = PWB0CabiA003008005.port.Q_flow; PWB0CabiA004008005.T = PWB0CabiA004008005.port.T; PWB0CabiA004008005.der_T = der(PWB0CabiA004008005.T); PWB0CabiA004008005.C * der(PWB0CabiA004008005.T) = PWB0CabiA004008005.port.Q_flow; PWB0CabiA005008005.T = PWB0CabiA005008005.port.T; PWB0CabiA005008005.der_T = der(PWB0CabiA005008005.T); PWB0CabiA005008005.C * der(PWB0CabiA005008005.T) = PWB0CabiA005008005.port.Q_flow; PWB0CabiA006008005.T = PWB0CabiA006008005.port.T; PWB0CabiA006008005.der_T = der(PWB0CabiA006008005.T); PWB0CabiA006008005.C * der(PWB0CabiA006008005.T) = PWB0CabiA006008005.port.Q_flow; PWB0CabiA007008005.T = PWB0CabiA007008005.port.T; PWB0CabiA007008005.der_T = der(PWB0CabiA007008005.T); PWB0CabiA007008005.C * der(PWB0CabiA007008005.T) = PWB0CabiA007008005.port.Q_flow; PWB0CabiA008008005.T = PWB0CabiA008008005.port.T; PWB0CabiA008008005.der_T = der(PWB0CabiA008008005.T); PWB0CabiA008008005.C * der(PWB0CabiA008008005.T) = PWB0CabiA008008005.port.Q_flow; PWB0CabiA009008005.T = PWB0CabiA009008005.port.T; PWB0CabiA009008005.der_T = der(PWB0CabiA009008005.T); PWB0CabiA009008005.C * der(PWB0CabiA009008005.T) = PWB0CabiA009008005.port.Q_flow; PWB0CabiA010008005.T = PWB0CabiA010008005.port.T; PWB0CabiA010008005.der_T = der(PWB0CabiA010008005.T); PWB0CabiA010008005.C * der(PWB0CabiA010008005.T) = PWB0CabiA010008005.port.Q_flow; PWB0CabiA011008005.T = PWB0CabiA011008005.port.T; PWB0CabiA011008005.der_T = der(PWB0CabiA011008005.T); PWB0CabiA011008005.C * der(PWB0CabiA011008005.T) = PWB0CabiA011008005.port.Q_flow; PWB0CabiA003009005.T = PWB0CabiA003009005.port.T; PWB0CabiA003009005.der_T = der(PWB0CabiA003009005.T); PWB0CabiA003009005.C * der(PWB0CabiA003009005.T) = PWB0CabiA003009005.port.Q_flow; PWB0CabiA004009005.T = PWB0CabiA004009005.port.T; PWB0CabiA004009005.der_T = der(PWB0CabiA004009005.T); PWB0CabiA004009005.C * der(PWB0CabiA004009005.T) = PWB0CabiA004009005.port.Q_flow; PWB0CabiA005009005.T = PWB0CabiA005009005.port.T; PWB0CabiA005009005.der_T = der(PWB0CabiA005009005.T); PWB0CabiA005009005.C * der(PWB0CabiA005009005.T) = PWB0CabiA005009005.port.Q_flow; PWB0CabiA006009005.T = PWB0CabiA006009005.port.T; PWB0CabiA006009005.der_T = der(PWB0CabiA006009005.T); PWB0CabiA006009005.C * der(PWB0CabiA006009005.T) = PWB0CabiA006009005.port.Q_flow; PWB0CabiA007009005.T = PWB0CabiA007009005.port.T; PWB0CabiA007009005.der_T = der(PWB0CabiA007009005.T); PWB0CabiA007009005.C * der(PWB0CabiA007009005.T) = PWB0CabiA007009005.port.Q_flow; PWB0CabiA008009005.T = PWB0CabiA008009005.port.T; PWB0CabiA008009005.der_T = der(PWB0CabiA008009005.T); PWB0CabiA008009005.C * der(PWB0CabiA008009005.T) = PWB0CabiA008009005.port.Q_flow; PWB0CabiA009009005.T = PWB0CabiA009009005.port.T; PWB0CabiA009009005.der_T = der(PWB0CabiA009009005.T); PWB0CabiA009009005.C * der(PWB0CabiA009009005.T) = PWB0CabiA009009005.port.Q_flow; PWB0CabiA010009005.T = PWB0CabiA010009005.port.T; PWB0CabiA010009005.der_T = der(PWB0CabiA010009005.T); PWB0CabiA010009005.C * der(PWB0CabiA010009005.T) = PWB0CabiA010009005.port.Q_flow; PWB0CabiA011009005.T = PWB0CabiA011009005.port.T; PWB0CabiA011009005.der_T = der(PWB0CabiA011009005.T); PWB0CabiA011009005.C * der(PWB0CabiA011009005.T) = PWB0CabiA011009005.port.Q_flow; PWB0CabiA003010005.T = PWB0CabiA003010005.port.T; PWB0CabiA003010005.der_T = der(PWB0CabiA003010005.T); PWB0CabiA003010005.C * der(PWB0CabiA003010005.T) = PWB0CabiA003010005.port.Q_flow; PWB0CabiA004010005.T = PWB0CabiA004010005.port.T; PWB0CabiA004010005.der_T = der(PWB0CabiA004010005.T); PWB0CabiA004010005.C * der(PWB0CabiA004010005.T) = PWB0CabiA004010005.port.Q_flow; PWB0CabiA005010005.T = PWB0CabiA005010005.port.T; PWB0CabiA005010005.der_T = der(PWB0CabiA005010005.T); PWB0CabiA005010005.C * der(PWB0CabiA005010005.T) = PWB0CabiA005010005.port.Q_flow; PWB0CabiA006010005.T = PWB0CabiA006010005.port.T; PWB0CabiA006010005.der_T = der(PWB0CabiA006010005.T); PWB0CabiA006010005.C * der(PWB0CabiA006010005.T) = PWB0CabiA006010005.port.Q_flow; PWB0CabiA007010005.T = PWB0CabiA007010005.port.T; PWB0CabiA007010005.der_T = der(PWB0CabiA007010005.T); PWB0CabiA007010005.C * der(PWB0CabiA007010005.T) = PWB0CabiA007010005.port.Q_flow; PWB0CabiA008010005.T = PWB0CabiA008010005.port.T; PWB0CabiA008010005.der_T = der(PWB0CabiA008010005.T); PWB0CabiA008010005.C * der(PWB0CabiA008010005.T) = PWB0CabiA008010005.port.Q_flow; PWB0CabiA009010005.T = PWB0CabiA009010005.port.T; PWB0CabiA009010005.der_T = der(PWB0CabiA009010005.T); PWB0CabiA009010005.C * der(PWB0CabiA009010005.T) = PWB0CabiA009010005.port.Q_flow; PWB0CabiA010010005.T = PWB0CabiA010010005.port.T; PWB0CabiA010010005.der_T = der(PWB0CabiA010010005.T); PWB0CabiA010010005.C * der(PWB0CabiA010010005.T) = PWB0CabiA010010005.port.Q_flow; PWB0CabiA011010005.T = PWB0CabiA011010005.port.T; PWB0CabiA011010005.der_T = der(PWB0CabiA011010005.T); PWB0CabiA011010005.C * der(PWB0CabiA011010005.T) = PWB0CabiA011010005.port.Q_flow; PWB0CabiA003003005.T = PWB0CabiA003003005.port.T; PWB0CabiA003003005.der_T = der(PWB0CabiA003003005.T); PWB0CabiA003003005.C * der(PWB0CabiA003003005.T) = PWB0CabiA003003005.port.Q_flow; PWB0CabiA004003005.T = PWB0CabiA004003005.port.T; PWB0CabiA004003005.der_T = der(PWB0CabiA004003005.T); PWB0CabiA004003005.C * der(PWB0CabiA004003005.T) = PWB0CabiA004003005.port.Q_flow; PWB0CabiA005003005.T = PWB0CabiA005003005.port.T; PWB0CabiA005003005.der_T = der(PWB0CabiA005003005.T); PWB0CabiA005003005.C * der(PWB0CabiA005003005.T) = PWB0CabiA005003005.port.Q_flow; PWB0CabiA006003005.T = PWB0CabiA006003005.port.T; PWB0CabiA006003005.der_T = der(PWB0CabiA006003005.T); PWB0CabiA006003005.C * der(PWB0CabiA006003005.T) = PWB0CabiA006003005.port.Q_flow; PWB0CabiA007003005.T = PWB0CabiA007003005.port.T; PWB0CabiA007003005.der_T = der(PWB0CabiA007003005.T); PWB0CabiA007003005.C * der(PWB0CabiA007003005.T) = PWB0CabiA007003005.port.Q_flow; PWB0CabiA008003005.T = PWB0CabiA008003005.port.T; PWB0CabiA008003005.der_T = der(PWB0CabiA008003005.T); PWB0CabiA008003005.C * der(PWB0CabiA008003005.T) = PWB0CabiA008003005.port.Q_flow; PWB0CabiA009003005.T = PWB0CabiA009003005.port.T; PWB0CabiA009003005.der_T = der(PWB0CabiA009003005.T); PWB0CabiA009003005.C * der(PWB0CabiA009003005.T) = PWB0CabiA009003005.port.Q_flow; PWB0CabiA010003005.T = PWB0CabiA010003005.port.T; PWB0CabiA010003005.der_T = der(PWB0CabiA010003005.T); PWB0CabiA010003005.C * der(PWB0CabiA010003005.T) = PWB0CabiA010003005.port.Q_flow; PWB0CabiA011003005.T = PWB0CabiA011003005.port.T; PWB0CabiA011003005.der_T = der(PWB0CabiA011003005.T); PWB0CabiA011003005.C * der(PWB0CabiA011003005.T) = PWB0CabiA011003005.port.Q_flow; PWB0CabiA003004005.T = PWB0CabiA003004005.port.T; PWB0CabiA003004005.der_T = der(PWB0CabiA003004005.T); PWB0CabiA003004005.C * der(PWB0CabiA003004005.T) = PWB0CabiA003004005.port.Q_flow; PWB0CabiA004004005.T = PWB0CabiA004004005.port.T; PWB0CabiA004004005.der_T = der(PWB0CabiA004004005.T); PWB0CabiA004004005.C * der(PWB0CabiA004004005.T) = PWB0CabiA004004005.port.Q_flow; PWB0CabiA005004005.T = PWB0CabiA005004005.port.T; PWB0CabiA005004005.der_T = der(PWB0CabiA005004005.T); PWB0CabiA005004005.C * der(PWB0CabiA005004005.T) = PWB0CabiA005004005.port.Q_flow; PWB0CabiA006004005.T = PWB0CabiA006004005.port.T; PWB0CabiA006004005.der_T = der(PWB0CabiA006004005.T); PWB0CabiA006004005.C * der(PWB0CabiA006004005.T) = PWB0CabiA006004005.port.Q_flow; PWB0CabiA007004005.T = PWB0CabiA007004005.port.T; PWB0CabiA007004005.der_T = der(PWB0CabiA007004005.T); PWB0CabiA007004005.C * der(PWB0CabiA007004005.T) = PWB0CabiA007004005.port.Q_flow; PWB0CabiA008004005.T = PWB0CabiA008004005.port.T; PWB0CabiA008004005.der_T = der(PWB0CabiA008004005.T); PWB0CabiA008004005.C * der(PWB0CabiA008004005.T) = PWB0CabiA008004005.port.Q_flow; PWB0CabiA009004005.T = PWB0CabiA009004005.port.T; PWB0CabiA009004005.der_T = der(PWB0CabiA009004005.T); PWB0CabiA009004005.C * der(PWB0CabiA009004005.T) = PWB0CabiA009004005.port.Q_flow; PWB0CabiA010004005.T = PWB0CabiA010004005.port.T; PWB0CabiA010004005.der_T = der(PWB0CabiA010004005.T); PWB0CabiA010004005.C * der(PWB0CabiA010004005.T) = PWB0CabiA010004005.port.Q_flow; PWB0CabiA011004005.T = PWB0CabiA011004005.port.T; PWB0CabiA011004005.der_T = der(PWB0CabiA011004005.T); PWB0CabiA011004005.C * der(PWB0CabiA011004005.T) = PWB0CabiA011004005.port.Q_flow; PWB0CabiA003005005.T = PWB0CabiA003005005.port.T; PWB0CabiA003005005.der_T = der(PWB0CabiA003005005.T); PWB0CabiA003005005.C * der(PWB0CabiA003005005.T) = PWB0CabiA003005005.port.Q_flow; PWB0CabiA004005005.T = PWB0CabiA004005005.port.T; PWB0CabiA004005005.der_T = der(PWB0CabiA004005005.T); PWB0CabiA004005005.C * der(PWB0CabiA004005005.T) = PWB0CabiA004005005.port.Q_flow; PWB0CabiA005005005.T = PWB0CabiA005005005.port.T; PWB0CabiA005005005.der_T = der(PWB0CabiA005005005.T); PWB0CabiA005005005.C * der(PWB0CabiA005005005.T) = PWB0CabiA005005005.port.Q_flow; PWB0CabiA006005005.T = PWB0CabiA006005005.port.T; PWB0CabiA006005005.der_T = der(PWB0CabiA006005005.T); PWB0CabiA006005005.C * der(PWB0CabiA006005005.T) = PWB0CabiA006005005.port.Q_flow; PWB0CabiA007005005.T = PWB0CabiA007005005.port.T; PWB0CabiA007005005.der_T = der(PWB0CabiA007005005.T); PWB0CabiA007005005.C * der(PWB0CabiA007005005.T) = PWB0CabiA007005005.port.Q_flow; PWB0CabiA008005005.T = PWB0CabiA008005005.port.T; PWB0CabiA008005005.der_T = der(PWB0CabiA008005005.T); PWB0CabiA008005005.C * der(PWB0CabiA008005005.T) = PWB0CabiA008005005.port.Q_flow; PWB0CabiA009005005.T = PWB0CabiA009005005.port.T; PWB0CabiA009005005.der_T = der(PWB0CabiA009005005.T); PWB0CabiA009005005.C * der(PWB0CabiA009005005.T) = PWB0CabiA009005005.port.Q_flow; PWB0CabiA010005005.T = PWB0CabiA010005005.port.T; PWB0CabiA010005005.der_T = der(PWB0CabiA010005005.T); PWB0CabiA010005005.C * der(PWB0CabiA010005005.T) = PWB0CabiA010005005.port.Q_flow; PWB0CabiA011005005.T = PWB0CabiA011005005.port.T; PWB0CabiA011005005.der_T = der(PWB0CabiA011005005.T); PWB0CabiA011005005.C * der(PWB0CabiA011005005.T) = PWB0CabiA011005005.port.Q_flow; IC50CabiA006004006.T = IC50CabiA006004006.port.T; IC50CabiA006004006.der_T = der(IC50CabiA006004006.T); IC50CabiA006004006.C * der(IC50CabiA006004006.T) = IC50CabiA006004006.port.Q_flow; IC50CabiA007004006.T = IC50CabiA007004006.port.T; IC50CabiA007004006.der_T = der(IC50CabiA007004006.T); IC50CabiA007004006.C * der(IC50CabiA007004006.T) = IC50CabiA007004006.port.Q_flow; IC50CabiA008004006.T = IC50CabiA008004006.port.T; IC50CabiA008004006.der_T = der(IC50CabiA008004006.T); IC50CabiA008004006.C * der(IC50CabiA008004006.T) = IC50CabiA008004006.port.Q_flow; IC50CabiA009004006.T = IC50CabiA009004006.port.T; IC50CabiA009004006.der_T = der(IC50CabiA009004006.T); IC50CabiA009004006.C * der(IC50CabiA009004006.T) = IC50CabiA009004006.port.Q_flow; IC50CabiA006005006.T = IC50CabiA006005006.port.T; IC50CabiA006005006.der_T = der(IC50CabiA006005006.T); IC50CabiA006005006.C * der(IC50CabiA006005006.T) = IC50CabiA006005006.port.Q_flow; IC50CabiA007005006.T = IC50CabiA007005006.port.T; IC50CabiA007005006.der_T = der(IC50CabiA007005006.T); IC50CabiA007005006.C * der(IC50CabiA007005006.T) = IC50CabiA007005006.port.Q_flow; IC50CabiA008005006.T = IC50CabiA008005006.port.T; IC50CabiA008005006.der_T = der(IC50CabiA008005006.T); IC50CabiA008005006.C * der(IC50CabiA008005006.T) = IC50CabiA008005006.port.Q_flow; IC50CabiA009005006.T = IC50CabiA009005006.port.T; IC50CabiA009005006.der_T = der(IC50CabiA009005006.T); IC50CabiA009005006.C * der(IC50CabiA009005006.T) = IC50CabiA009005006.port.Q_flow; IC50CabiA006006006.T = IC50CabiA006006006.port.T; IC50CabiA006006006.der_T = der(IC50CabiA006006006.T); IC50CabiA006006006.C * der(IC50CabiA006006006.T) = IC50CabiA006006006.port.Q_flow; IC50CabiA007006006.T = IC50CabiA007006006.port.T; IC50CabiA007006006.der_T = der(IC50CabiA007006006.T); IC50CabiA007006006.C * der(IC50CabiA007006006.T) = IC50CabiA007006006.port.Q_flow; IC50CabiA008006006.T = IC50CabiA008006006.port.T; IC50CabiA008006006.der_T = der(IC50CabiA008006006.T); IC50CabiA008006006.C * der(IC50CabiA008006006.T) = IC50CabiA008006006.port.Q_flow; IC50CabiA009006006.T = IC50CabiA009006006.port.T; IC50CabiA009006006.der_T = der(IC50CabiA009006006.T); IC50CabiA009006006.C * der(IC50CabiA009006006.T) = IC50CabiA009006006.port.Q_flow; IC40CabiA008009006.T = IC40CabiA008009006.port.T; IC40CabiA008009006.der_T = der(IC40CabiA008009006.T); IC40CabiA008009006.C * der(IC40CabiA008009006.T) = IC40CabiA008009006.port.Q_flow; IC40CabiA009009006.T = IC40CabiA009009006.port.T; IC40CabiA009009006.der_T = der(IC40CabiA009009006.T); IC40CabiA009009006.C * der(IC40CabiA009009006.T) = IC40CabiA009009006.port.Q_flow; IC40CabiA010009006.T = IC40CabiA010009006.port.T; IC40CabiA010009006.der_T = der(IC40CabiA010009006.T); IC40CabiA010009006.C * der(IC40CabiA010009006.T) = IC40CabiA010009006.port.Q_flow; IC40CabiA008010006.T = IC40CabiA008010006.port.T; IC40CabiA008010006.der_T = der(IC40CabiA008010006.T); IC40CabiA008010006.C * der(IC40CabiA008010006.T) = IC40CabiA008010006.port.Q_flow; IC40CabiA009010006.T = IC40CabiA009010006.port.T; IC40CabiA009010006.der_T = der(IC40CabiA009010006.T); IC40CabiA009010006.C * der(IC40CabiA009010006.T) = IC40CabiA009010006.port.Q_flow; IC40CabiA010010006.T = IC40CabiA010010006.port.T; IC40CabiA010010006.der_T = der(IC40CabiA010010006.T); IC40CabiA010010006.C * der(IC40CabiA010010006.T) = IC40CabiA010010006.port.Q_flow; IC40CabiA008011006.T = IC40CabiA008011006.port.T; IC40CabiA008011006.der_T = der(IC40CabiA008011006.T); IC40CabiA008011006.C * der(IC40CabiA008011006.T) = IC40CabiA008011006.port.Q_flow; IC40CabiA009011006.T = IC40CabiA009011006.port.T; IC40CabiA009011006.der_T = der(IC40CabiA009011006.T); IC40CabiA009011006.C * der(IC40CabiA009011006.T) = IC40CabiA009011006.port.Q_flow; IC40CabiA010011006.T = IC40CabiA010011006.port.T; IC40CabiA010011006.der_T = der(IC40CabiA010011006.T); IC40CabiA010011006.C * der(IC40CabiA010011006.T) = IC40CabiA010011006.port.Q_flow; IC10CabiA004011006.T = IC10CabiA004011006.port.T; IC10CabiA004011006.der_T = der(IC10CabiA004011006.T); IC10CabiA004011006.C * der(IC10CabiA004011006.T) = IC10CabiA004011006.port.Q_flow; IC10CabiA005011006.T = IC10CabiA005011006.port.T; IC10CabiA005011006.der_T = der(IC10CabiA005011006.T); IC10CabiA005011006.C * der(IC10CabiA005011006.T) = IC10CabiA005011006.port.Q_flow; IC10CabiA006011006.T = IC10CabiA006011006.port.T; IC10CabiA006011006.der_T = der(IC10CabiA006011006.T); IC10CabiA006011006.C * der(IC10CabiA006011006.T) = IC10CabiA006011006.port.Q_flow; IC10CabiA004012006.T = IC10CabiA004012006.port.T; IC10CabiA004012006.der_T = der(IC10CabiA004012006.T); IC10CabiA004012006.C * der(IC10CabiA004012006.T) = IC10CabiA004012006.port.Q_flow; IC10CabiA005012006.T = IC10CabiA005012006.port.T; IC10CabiA005012006.der_T = der(IC10CabiA005012006.T); IC10CabiA005012006.C * der(IC10CabiA005012006.T) = IC10CabiA005012006.port.Q_flow; IC10CabiA006012006.T = IC10CabiA006012006.port.T; IC10CabiA006012006.der_T = der(IC10CabiA006012006.T); IC10CabiA006012006.C * der(IC10CabiA006012006.T) = IC10CabiA006012006.port.Q_flow; IC10CabiA004013006.T = IC10CabiA004013006.port.T; IC10CabiA004013006.der_T = der(IC10CabiA004013006.T); IC10CabiA004013006.C * der(IC10CabiA004013006.T) = IC10CabiA004013006.port.Q_flow; IC10CabiA005013006.T = IC10CabiA005013006.port.T; IC10CabiA005013006.der_T = der(IC10CabiA005013006.T); IC10CabiA005013006.C * der(IC10CabiA005013006.T) = IC10CabiA005013006.port.Q_flow; IC10CabiA006013006.T = IC10CabiA006013006.port.T; IC10CabiA006013006.der_T = der(IC10CabiA006013006.T); IC10CabiA006013006.C * der(IC10CabiA006013006.T) = IC10CabiA006013006.port.Q_flow; TC_1_2.Q_flow = TC_1_2.G * TC_1_2.dT; TC_1_2.dT = TC_1_2.port_a.T - TC_1_2.port_b.T; TC_1_2.port_a.Q_flow = TC_1_2.Q_flow; TC_1_2.port_b.Q_flow = -TC_1_2.Q_flow; TC_1_14.Q_flow = TC_1_14.G * TC_1_14.dT; TC_1_14.dT = TC_1_14.port_a.T - TC_1_14.port_b.T; TC_1_14.port_a.Q_flow = TC_1_14.Q_flow; TC_1_14.port_b.Q_flow = -TC_1_14.Q_flow; TC_1_424.Q_flow = TC_1_424.G * TC_1_424.dT; TC_1_424.dT = TC_1_424.port_a.T - TC_1_424.port_b.T; TC_1_424.port_a.Q_flow = TC_1_424.Q_flow; TC_1_424.port_b.Q_flow = -TC_1_424.Q_flow; TC_2_3.Q_flow = TC_2_3.G * TC_2_3.dT; TC_2_3.dT = TC_2_3.port_a.T - TC_2_3.port_b.T; TC_2_3.port_a.Q_flow = TC_2_3.Q_flow; TC_2_3.port_b.Q_flow = -TC_2_3.Q_flow; TC_2_15.Q_flow = TC_2_15.G * TC_2_15.dT; TC_2_15.dT = TC_2_15.port_a.T - TC_2_15.port_b.T; TC_2_15.port_a.Q_flow = TC_2_15.Q_flow; TC_2_15.port_b.Q_flow = -TC_2_15.Q_flow; TC_2_209.Q_flow = TC_2_209.G * TC_2_209.dT; TC_2_209.dT = TC_2_209.port_a.T - TC_2_209.port_b.T; TC_2_209.port_a.Q_flow = TC_2_209.Q_flow; TC_2_209.port_b.Q_flow = -TC_2_209.Q_flow; TC_3_4.Q_flow = TC_3_4.G * TC_3_4.dT; TC_3_4.dT = TC_3_4.port_a.T - TC_3_4.port_b.T; TC_3_4.port_a.Q_flow = TC_3_4.Q_flow; TC_3_4.port_b.Q_flow = -TC_3_4.Q_flow; TC_3_16.Q_flow = TC_3_16.G * TC_3_16.dT; TC_3_16.dT = TC_3_16.port_a.T - TC_3_16.port_b.T; TC_3_16.port_a.Q_flow = TC_3_16.Q_flow; TC_3_16.port_b.Q_flow = -TC_3_16.Q_flow; TC_3_210.Q_flow = TC_3_210.G * TC_3_210.dT; TC_3_210.dT = TC_3_210.port_a.T - TC_3_210.port_b.T; TC_3_210.port_a.Q_flow = TC_3_210.Q_flow; TC_3_210.port_b.Q_flow = -TC_3_210.Q_flow; TC_4_5.Q_flow = TC_4_5.G * TC_4_5.dT; TC_4_5.dT = TC_4_5.port_a.T - TC_4_5.port_b.T; TC_4_5.port_a.Q_flow = TC_4_5.Q_flow; TC_4_5.port_b.Q_flow = -TC_4_5.Q_flow; TC_4_17.Q_flow = TC_4_17.G * TC_4_17.dT; TC_4_17.dT = TC_4_17.port_a.T - TC_4_17.port_b.T; TC_4_17.port_a.Q_flow = TC_4_17.Q_flow; TC_4_17.port_b.Q_flow = -TC_4_17.Q_flow; TC_4_211.Q_flow = TC_4_211.G * TC_4_211.dT; TC_4_211.dT = TC_4_211.port_a.T - TC_4_211.port_b.T; TC_4_211.port_a.Q_flow = TC_4_211.Q_flow; TC_4_211.port_b.Q_flow = -TC_4_211.Q_flow; TC_5_6.Q_flow = TC_5_6.G * TC_5_6.dT; TC_5_6.dT = TC_5_6.port_a.T - TC_5_6.port_b.T; TC_5_6.port_a.Q_flow = TC_5_6.Q_flow; TC_5_6.port_b.Q_flow = -TC_5_6.Q_flow; TC_5_18.Q_flow = TC_5_18.G * TC_5_18.dT; TC_5_18.dT = TC_5_18.port_a.T - TC_5_18.port_b.T; TC_5_18.port_a.Q_flow = TC_5_18.Q_flow; TC_5_18.port_b.Q_flow = -TC_5_18.Q_flow; TC_5_212.Q_flow = TC_5_212.G * TC_5_212.dT; TC_5_212.dT = TC_5_212.port_a.T - TC_5_212.port_b.T; TC_5_212.port_a.Q_flow = TC_5_212.Q_flow; TC_5_212.port_b.Q_flow = -TC_5_212.Q_flow; TC_6_7.Q_flow = TC_6_7.G * TC_6_7.dT; TC_6_7.dT = TC_6_7.port_a.T - TC_6_7.port_b.T; TC_6_7.port_a.Q_flow = TC_6_7.Q_flow; TC_6_7.port_b.Q_flow = -TC_6_7.Q_flow; TC_6_19.Q_flow = TC_6_19.G * TC_6_19.dT; TC_6_19.dT = TC_6_19.port_a.T - TC_6_19.port_b.T; TC_6_19.port_a.Q_flow = TC_6_19.Q_flow; TC_6_19.port_b.Q_flow = -TC_6_19.Q_flow; TC_6_213.Q_flow = TC_6_213.G * TC_6_213.dT; TC_6_213.dT = TC_6_213.port_a.T - TC_6_213.port_b.T; TC_6_213.port_a.Q_flow = TC_6_213.Q_flow; TC_6_213.port_b.Q_flow = -TC_6_213.Q_flow; TC_7_8.Q_flow = TC_7_8.G * TC_7_8.dT; TC_7_8.dT = TC_7_8.port_a.T - TC_7_8.port_b.T; TC_7_8.port_a.Q_flow = TC_7_8.Q_flow; TC_7_8.port_b.Q_flow = -TC_7_8.Q_flow; TC_7_20.Q_flow = TC_7_20.G * TC_7_20.dT; TC_7_20.dT = TC_7_20.port_a.T - TC_7_20.port_b.T; TC_7_20.port_a.Q_flow = TC_7_20.Q_flow; TC_7_20.port_b.Q_flow = -TC_7_20.Q_flow; TC_7_214.Q_flow = TC_7_214.G * TC_7_214.dT; TC_7_214.dT = TC_7_214.port_a.T - TC_7_214.port_b.T; TC_7_214.port_a.Q_flow = TC_7_214.Q_flow; TC_7_214.port_b.Q_flow = -TC_7_214.Q_flow; TC_8_9.Q_flow = TC_8_9.G * TC_8_9.dT; TC_8_9.dT = TC_8_9.port_a.T - TC_8_9.port_b.T; TC_8_9.port_a.Q_flow = TC_8_9.Q_flow; TC_8_9.port_b.Q_flow = -TC_8_9.Q_flow; TC_8_21.Q_flow = TC_8_21.G * TC_8_21.dT; TC_8_21.dT = TC_8_21.port_a.T - TC_8_21.port_b.T; TC_8_21.port_a.Q_flow = TC_8_21.Q_flow; TC_8_21.port_b.Q_flow = -TC_8_21.Q_flow; TC_8_215.Q_flow = TC_8_215.G * TC_8_215.dT; TC_8_215.dT = TC_8_215.port_a.T - TC_8_215.port_b.T; TC_8_215.port_a.Q_flow = TC_8_215.Q_flow; TC_8_215.port_b.Q_flow = -TC_8_215.Q_flow; TC_9_10.Q_flow = TC_9_10.G * TC_9_10.dT; TC_9_10.dT = TC_9_10.port_a.T - TC_9_10.port_b.T; TC_9_10.port_a.Q_flow = TC_9_10.Q_flow; TC_9_10.port_b.Q_flow = -TC_9_10.Q_flow; TC_9_22.Q_flow = TC_9_22.G * TC_9_22.dT; TC_9_22.dT = TC_9_22.port_a.T - TC_9_22.port_b.T; TC_9_22.port_a.Q_flow = TC_9_22.Q_flow; TC_9_22.port_b.Q_flow = -TC_9_22.Q_flow; TC_9_216.Q_flow = TC_9_216.G * TC_9_216.dT; TC_9_216.dT = TC_9_216.port_a.T - TC_9_216.port_b.T; TC_9_216.port_a.Q_flow = TC_9_216.Q_flow; TC_9_216.port_b.Q_flow = -TC_9_216.Q_flow; TC_10_11.Q_flow = TC_10_11.G * TC_10_11.dT; TC_10_11.dT = TC_10_11.port_a.T - TC_10_11.port_b.T; TC_10_11.port_a.Q_flow = TC_10_11.Q_flow; TC_10_11.port_b.Q_flow = -TC_10_11.Q_flow; TC_10_23.Q_flow = TC_10_23.G * TC_10_23.dT; TC_10_23.dT = TC_10_23.port_a.T - TC_10_23.port_b.T; TC_10_23.port_a.Q_flow = TC_10_23.Q_flow; TC_10_23.port_b.Q_flow = -TC_10_23.Q_flow; TC_10_217.Q_flow = TC_10_217.G * TC_10_217.dT; TC_10_217.dT = TC_10_217.port_a.T - TC_10_217.port_b.T; TC_10_217.port_a.Q_flow = TC_10_217.Q_flow; TC_10_217.port_b.Q_flow = -TC_10_217.Q_flow; TC_11_12.Q_flow = TC_11_12.G * TC_11_12.dT; TC_11_12.dT = TC_11_12.port_a.T - TC_11_12.port_b.T; TC_11_12.port_a.Q_flow = TC_11_12.Q_flow; TC_11_12.port_b.Q_flow = -TC_11_12.Q_flow; TC_11_24.Q_flow = TC_11_24.G * TC_11_24.dT; TC_11_24.dT = TC_11_24.port_a.T - TC_11_24.port_b.T; TC_11_24.port_a.Q_flow = TC_11_24.Q_flow; TC_11_24.port_b.Q_flow = -TC_11_24.Q_flow; TC_11_218.Q_flow = TC_11_218.G * TC_11_218.dT; TC_11_218.dT = TC_11_218.port_a.T - TC_11_218.port_b.T; TC_11_218.port_a.Q_flow = TC_11_218.Q_flow; TC_11_218.port_b.Q_flow = -TC_11_218.Q_flow; TC_12_13.Q_flow = TC_12_13.G * TC_12_13.dT; TC_12_13.dT = TC_12_13.port_a.T - TC_12_13.port_b.T; TC_12_13.port_a.Q_flow = TC_12_13.Q_flow; TC_12_13.port_b.Q_flow = -TC_12_13.Q_flow; TC_12_25.Q_flow = TC_12_25.G * TC_12_25.dT; TC_12_25.dT = TC_12_25.port_a.T - TC_12_25.port_b.T; TC_12_25.port_a.Q_flow = TC_12_25.Q_flow; TC_12_25.port_b.Q_flow = -TC_12_25.Q_flow; TC_12_219.Q_flow = TC_12_219.G * TC_12_219.dT; TC_12_219.dT = TC_12_219.port_a.T - TC_12_219.port_b.T; TC_12_219.port_a.Q_flow = TC_12_219.Q_flow; TC_12_219.port_b.Q_flow = -TC_12_219.Q_flow; TC_13_26.Q_flow = TC_13_26.G * TC_13_26.dT; TC_13_26.dT = TC_13_26.port_a.T - TC_13_26.port_b.T; TC_13_26.port_a.Q_flow = TC_13_26.Q_flow; TC_13_26.port_b.Q_flow = -TC_13_26.Q_flow; TC_13_220.Q_flow = TC_13_220.G * TC_13_220.dT; TC_13_220.dT = TC_13_220.port_a.T - TC_13_220.port_b.T; TC_13_220.port_a.Q_flow = TC_13_220.Q_flow; TC_13_220.port_b.Q_flow = -TC_13_220.Q_flow; TC_14_15.Q_flow = TC_14_15.G * TC_14_15.dT; TC_14_15.dT = TC_14_15.port_a.T - TC_14_15.port_b.T; TC_14_15.port_a.Q_flow = TC_14_15.Q_flow; TC_14_15.port_b.Q_flow = -TC_14_15.Q_flow; TC_14_27.Q_flow = TC_14_27.G * TC_14_27.dT; TC_14_27.dT = TC_14_27.port_a.T - TC_14_27.port_b.T; TC_14_27.port_a.Q_flow = TC_14_27.Q_flow; TC_14_27.port_b.Q_flow = -TC_14_27.Q_flow; TC_14_221.Q_flow = TC_14_221.G * TC_14_221.dT; TC_14_221.dT = TC_14_221.port_a.T - TC_14_221.port_b.T; TC_14_221.port_a.Q_flow = TC_14_221.Q_flow; TC_14_221.port_b.Q_flow = -TC_14_221.Q_flow; TC_15_16.Q_flow = TC_15_16.G * TC_15_16.dT; TC_15_16.dT = TC_15_16.port_a.T - TC_15_16.port_b.T; TC_15_16.port_a.Q_flow = TC_15_16.Q_flow; TC_15_16.port_b.Q_flow = -TC_15_16.Q_flow; TC_15_28.Q_flow = TC_15_28.G * TC_15_28.dT; TC_15_28.dT = TC_15_28.port_a.T - TC_15_28.port_b.T; TC_15_28.port_a.Q_flow = TC_15_28.Q_flow; TC_15_28.port_b.Q_flow = -TC_15_28.Q_flow; TC_15_1477.Q_flow = TC_15_1477.G * TC_15_1477.dT; TC_15_1477.dT = TC_15_1477.port_a.T - TC_15_1477.port_b.T; TC_15_1477.port_a.Q_flow = TC_15_1477.Q_flow; TC_15_1477.port_b.Q_flow = -TC_15_1477.Q_flow; TC_16_17.Q_flow = TC_16_17.G * TC_16_17.dT; TC_16_17.dT = TC_16_17.port_a.T - TC_16_17.port_b.T; TC_16_17.port_a.Q_flow = TC_16_17.Q_flow; TC_16_17.port_b.Q_flow = -TC_16_17.Q_flow; TC_16_29.Q_flow = TC_16_29.G * TC_16_29.dT; TC_16_29.dT = TC_16_29.port_a.T - TC_16_29.port_b.T; TC_16_29.port_a.Q_flow = TC_16_29.Q_flow; TC_16_29.port_b.Q_flow = -TC_16_29.Q_flow; TC_16_1478.Q_flow = TC_16_1478.G * TC_16_1478.dT; TC_16_1478.dT = TC_16_1478.port_a.T - TC_16_1478.port_b.T; TC_16_1478.port_a.Q_flow = TC_16_1478.Q_flow; TC_16_1478.port_b.Q_flow = -TC_16_1478.Q_flow; TC_17_18.Q_flow = TC_17_18.G * TC_17_18.dT; TC_17_18.dT = TC_17_18.port_a.T - TC_17_18.port_b.T; TC_17_18.port_a.Q_flow = TC_17_18.Q_flow; TC_17_18.port_b.Q_flow = -TC_17_18.Q_flow; TC_17_30.Q_flow = TC_17_30.G * TC_17_30.dT; TC_17_30.dT = TC_17_30.port_a.T - TC_17_30.port_b.T; TC_17_30.port_a.Q_flow = TC_17_30.Q_flow; TC_17_30.port_b.Q_flow = -TC_17_30.Q_flow; TC_17_1479.Q_flow = TC_17_1479.G * TC_17_1479.dT; TC_17_1479.dT = TC_17_1479.port_a.T - TC_17_1479.port_b.T; TC_17_1479.port_a.Q_flow = TC_17_1479.Q_flow; TC_17_1479.port_b.Q_flow = -TC_17_1479.Q_flow; TC_18_19.Q_flow = TC_18_19.G * TC_18_19.dT; TC_18_19.dT = TC_18_19.port_a.T - TC_18_19.port_b.T; TC_18_19.port_a.Q_flow = TC_18_19.Q_flow; TC_18_19.port_b.Q_flow = -TC_18_19.Q_flow; TC_18_31.Q_flow = TC_18_31.G * TC_18_31.dT; TC_18_31.dT = TC_18_31.port_a.T - TC_18_31.port_b.T; TC_18_31.port_a.Q_flow = TC_18_31.Q_flow; TC_18_31.port_b.Q_flow = -TC_18_31.Q_flow; TC_18_1480.Q_flow = TC_18_1480.G * TC_18_1480.dT; TC_18_1480.dT = TC_18_1480.port_a.T - TC_18_1480.port_b.T; TC_18_1480.port_a.Q_flow = TC_18_1480.Q_flow; TC_18_1480.port_b.Q_flow = -TC_18_1480.Q_flow; TC_19_20.Q_flow = TC_19_20.G * TC_19_20.dT; TC_19_20.dT = TC_19_20.port_a.T - TC_19_20.port_b.T; TC_19_20.port_a.Q_flow = TC_19_20.Q_flow; TC_19_20.port_b.Q_flow = -TC_19_20.Q_flow; TC_19_32.Q_flow = TC_19_32.G * TC_19_32.dT; TC_19_32.dT = TC_19_32.port_a.T - TC_19_32.port_b.T; TC_19_32.port_a.Q_flow = TC_19_32.Q_flow; TC_19_32.port_b.Q_flow = -TC_19_32.Q_flow; TC_19_1481.Q_flow = TC_19_1481.G * TC_19_1481.dT; TC_19_1481.dT = TC_19_1481.port_a.T - TC_19_1481.port_b.T; TC_19_1481.port_a.Q_flow = TC_19_1481.Q_flow; TC_19_1481.port_b.Q_flow = -TC_19_1481.Q_flow; TC_20_21.Q_flow = TC_20_21.G * TC_20_21.dT; TC_20_21.dT = TC_20_21.port_a.T - TC_20_21.port_b.T; TC_20_21.port_a.Q_flow = TC_20_21.Q_flow; TC_20_21.port_b.Q_flow = -TC_20_21.Q_flow; TC_20_33.Q_flow = TC_20_33.G * TC_20_33.dT; TC_20_33.dT = TC_20_33.port_a.T - TC_20_33.port_b.T; TC_20_33.port_a.Q_flow = TC_20_33.Q_flow; TC_20_33.port_b.Q_flow = -TC_20_33.Q_flow; TC_20_1482.Q_flow = TC_20_1482.G * TC_20_1482.dT; TC_20_1482.dT = TC_20_1482.port_a.T - TC_20_1482.port_b.T; TC_20_1482.port_a.Q_flow = TC_20_1482.Q_flow; TC_20_1482.port_b.Q_flow = -TC_20_1482.Q_flow; TC_21_22.Q_flow = TC_21_22.G * TC_21_22.dT; TC_21_22.dT = TC_21_22.port_a.T - TC_21_22.port_b.T; TC_21_22.port_a.Q_flow = TC_21_22.Q_flow; TC_21_22.port_b.Q_flow = -TC_21_22.Q_flow; TC_21_34.Q_flow = TC_21_34.G * TC_21_34.dT; TC_21_34.dT = TC_21_34.port_a.T - TC_21_34.port_b.T; TC_21_34.port_a.Q_flow = TC_21_34.Q_flow; TC_21_34.port_b.Q_flow = -TC_21_34.Q_flow; TC_21_1483.Q_flow = TC_21_1483.G * TC_21_1483.dT; TC_21_1483.dT = TC_21_1483.port_a.T - TC_21_1483.port_b.T; TC_21_1483.port_a.Q_flow = TC_21_1483.Q_flow; TC_21_1483.port_b.Q_flow = -TC_21_1483.Q_flow; TC_22_23.Q_flow = TC_22_23.G * TC_22_23.dT; TC_22_23.dT = TC_22_23.port_a.T - TC_22_23.port_b.T; TC_22_23.port_a.Q_flow = TC_22_23.Q_flow; TC_22_23.port_b.Q_flow = -TC_22_23.Q_flow; TC_22_35.Q_flow = TC_22_35.G * TC_22_35.dT; TC_22_35.dT = TC_22_35.port_a.T - TC_22_35.port_b.T; TC_22_35.port_a.Q_flow = TC_22_35.Q_flow; TC_22_35.port_b.Q_flow = -TC_22_35.Q_flow; TC_22_1484.Q_flow = TC_22_1484.G * TC_22_1484.dT; TC_22_1484.dT = TC_22_1484.port_a.T - TC_22_1484.port_b.T; TC_22_1484.port_a.Q_flow = TC_22_1484.Q_flow; TC_22_1484.port_b.Q_flow = -TC_22_1484.Q_flow; TC_23_24.Q_flow = TC_23_24.G * TC_23_24.dT; TC_23_24.dT = TC_23_24.port_a.T - TC_23_24.port_b.T; TC_23_24.port_a.Q_flow = TC_23_24.Q_flow; TC_23_24.port_b.Q_flow = -TC_23_24.Q_flow; TC_23_36.Q_flow = TC_23_36.G * TC_23_36.dT; TC_23_36.dT = TC_23_36.port_a.T - TC_23_36.port_b.T; TC_23_36.port_a.Q_flow = TC_23_36.Q_flow; TC_23_36.port_b.Q_flow = -TC_23_36.Q_flow; TC_23_1485.Q_flow = TC_23_1485.G * TC_23_1485.dT; TC_23_1485.dT = TC_23_1485.port_a.T - TC_23_1485.port_b.T; TC_23_1485.port_a.Q_flow = TC_23_1485.Q_flow; TC_23_1485.port_b.Q_flow = -TC_23_1485.Q_flow; TC_24_25.Q_flow = TC_24_25.G * TC_24_25.dT; TC_24_25.dT = TC_24_25.port_a.T - TC_24_25.port_b.T; TC_24_25.port_a.Q_flow = TC_24_25.Q_flow; TC_24_25.port_b.Q_flow = -TC_24_25.Q_flow; TC_24_37.Q_flow = TC_24_37.G * TC_24_37.dT; TC_24_37.dT = TC_24_37.port_a.T - TC_24_37.port_b.T; TC_24_37.port_a.Q_flow = TC_24_37.Q_flow; TC_24_37.port_b.Q_flow = -TC_24_37.Q_flow; TC_24_1486.Q_flow = TC_24_1486.G * TC_24_1486.dT; TC_24_1486.dT = TC_24_1486.port_a.T - TC_24_1486.port_b.T; TC_24_1486.port_a.Q_flow = TC_24_1486.Q_flow; TC_24_1486.port_b.Q_flow = -TC_24_1486.Q_flow; TC_25_26.Q_flow = TC_25_26.G * TC_25_26.dT; TC_25_26.dT = TC_25_26.port_a.T - TC_25_26.port_b.T; TC_25_26.port_a.Q_flow = TC_25_26.Q_flow; TC_25_26.port_b.Q_flow = -TC_25_26.Q_flow; TC_25_38.Q_flow = TC_25_38.G * TC_25_38.dT; TC_25_38.dT = TC_25_38.port_a.T - TC_25_38.port_b.T; TC_25_38.port_a.Q_flow = TC_25_38.Q_flow; TC_25_38.port_b.Q_flow = -TC_25_38.Q_flow; TC_25_1487.Q_flow = TC_25_1487.G * TC_25_1487.dT; TC_25_1487.dT = TC_25_1487.port_a.T - TC_25_1487.port_b.T; TC_25_1487.port_a.Q_flow = TC_25_1487.Q_flow; TC_25_1487.port_b.Q_flow = -TC_25_1487.Q_flow; TC_26_39.Q_flow = TC_26_39.G * TC_26_39.dT; TC_26_39.dT = TC_26_39.port_a.T - TC_26_39.port_b.T; TC_26_39.port_a.Q_flow = TC_26_39.Q_flow; TC_26_39.port_b.Q_flow = -TC_26_39.Q_flow; TC_26_222.Q_flow = TC_26_222.G * TC_26_222.dT; TC_26_222.dT = TC_26_222.port_a.T - TC_26_222.port_b.T; TC_26_222.port_a.Q_flow = TC_26_222.Q_flow; TC_26_222.port_b.Q_flow = -TC_26_222.Q_flow; TC_27_28.Q_flow = TC_27_28.G * TC_27_28.dT; TC_27_28.dT = TC_27_28.port_a.T - TC_27_28.port_b.T; TC_27_28.port_a.Q_flow = TC_27_28.Q_flow; TC_27_28.port_b.Q_flow = -TC_27_28.Q_flow; TC_27_40.Q_flow = TC_27_40.G * TC_27_40.dT; TC_27_40.dT = TC_27_40.port_a.T - TC_27_40.port_b.T; TC_27_40.port_a.Q_flow = TC_27_40.Q_flow; TC_27_40.port_b.Q_flow = -TC_27_40.Q_flow; TC_27_223.Q_flow = TC_27_223.G * TC_27_223.dT; TC_27_223.dT = TC_27_223.port_a.T - TC_27_223.port_b.T; TC_27_223.port_a.Q_flow = TC_27_223.Q_flow; TC_27_223.port_b.Q_flow = -TC_27_223.Q_flow; TC_28_29.Q_flow = TC_28_29.G * TC_28_29.dT; TC_28_29.dT = TC_28_29.port_a.T - TC_28_29.port_b.T; TC_28_29.port_a.Q_flow = TC_28_29.Q_flow; TC_28_29.port_b.Q_flow = -TC_28_29.Q_flow; TC_28_41.Q_flow = TC_28_41.G * TC_28_41.dT; TC_28_41.dT = TC_28_41.port_a.T - TC_28_41.port_b.T; TC_28_41.port_a.Q_flow = TC_28_41.Q_flow; TC_28_41.port_b.Q_flow = -TC_28_41.Q_flow; TC_28_1466.Q_flow = TC_28_1466.G * TC_28_1466.dT; TC_28_1466.dT = TC_28_1466.port_a.T - TC_28_1466.port_b.T; TC_28_1466.port_a.Q_flow = TC_28_1466.Q_flow; TC_28_1466.port_b.Q_flow = -TC_28_1466.Q_flow; TC_29_30.Q_flow = TC_29_30.G * TC_29_30.dT; TC_29_30.dT = TC_29_30.port_a.T - TC_29_30.port_b.T; TC_29_30.port_a.Q_flow = TC_29_30.Q_flow; TC_29_30.port_b.Q_flow = -TC_29_30.Q_flow; TC_29_42.Q_flow = TC_29_42.G * TC_29_42.dT; TC_29_42.dT = TC_29_42.port_a.T - TC_29_42.port_b.T; TC_29_42.port_a.Q_flow = TC_29_42.Q_flow; TC_29_42.port_b.Q_flow = -TC_29_42.Q_flow; TC_29_1467.Q_flow = TC_29_1467.G * TC_29_1467.dT; TC_29_1467.dT = TC_29_1467.port_a.T - TC_29_1467.port_b.T; TC_29_1467.port_a.Q_flow = TC_29_1467.Q_flow; TC_29_1467.port_b.Q_flow = -TC_29_1467.Q_flow; TC_30_31.Q_flow = TC_30_31.G * TC_30_31.dT; TC_30_31.dT = TC_30_31.port_a.T - TC_30_31.port_b.T; TC_30_31.port_a.Q_flow = TC_30_31.Q_flow; TC_30_31.port_b.Q_flow = -TC_30_31.Q_flow; TC_30_43.Q_flow = TC_30_43.G * TC_30_43.dT; TC_30_43.dT = TC_30_43.port_a.T - TC_30_43.port_b.T; TC_30_43.port_a.Q_flow = TC_30_43.Q_flow; TC_30_43.port_b.Q_flow = -TC_30_43.Q_flow; TC_30_1468.Q_flow = TC_30_1468.G * TC_30_1468.dT; TC_30_1468.dT = TC_30_1468.port_a.T - TC_30_1468.port_b.T; TC_30_1468.port_a.Q_flow = TC_30_1468.Q_flow; TC_30_1468.port_b.Q_flow = -TC_30_1468.Q_flow; TC_31_32.Q_flow = TC_31_32.G * TC_31_32.dT; TC_31_32.dT = TC_31_32.port_a.T - TC_31_32.port_b.T; TC_31_32.port_a.Q_flow = TC_31_32.Q_flow; TC_31_32.port_b.Q_flow = -TC_31_32.Q_flow; TC_31_44.Q_flow = TC_31_44.G * TC_31_44.dT; TC_31_44.dT = TC_31_44.port_a.T - TC_31_44.port_b.T; TC_31_44.port_a.Q_flow = TC_31_44.Q_flow; TC_31_44.port_b.Q_flow = -TC_31_44.Q_flow; TC_31_1469.Q_flow = TC_31_1469.G * TC_31_1469.dT; TC_31_1469.dT = TC_31_1469.port_a.T - TC_31_1469.port_b.T; TC_31_1469.port_a.Q_flow = TC_31_1469.Q_flow; TC_31_1469.port_b.Q_flow = -TC_31_1469.Q_flow; TC_32_33.Q_flow = TC_32_33.G * TC_32_33.dT; TC_32_33.dT = TC_32_33.port_a.T - TC_32_33.port_b.T; TC_32_33.port_a.Q_flow = TC_32_33.Q_flow; TC_32_33.port_b.Q_flow = -TC_32_33.Q_flow; TC_32_45.Q_flow = TC_32_45.G * TC_32_45.dT; TC_32_45.dT = TC_32_45.port_a.T - TC_32_45.port_b.T; TC_32_45.port_a.Q_flow = TC_32_45.Q_flow; TC_32_45.port_b.Q_flow = -TC_32_45.Q_flow; TC_32_1470.Q_flow = TC_32_1470.G * TC_32_1470.dT; TC_32_1470.dT = TC_32_1470.port_a.T - TC_32_1470.port_b.T; TC_32_1470.port_a.Q_flow = TC_32_1470.Q_flow; TC_32_1470.port_b.Q_flow = -TC_32_1470.Q_flow; TC_33_34.Q_flow = TC_33_34.G * TC_33_34.dT; TC_33_34.dT = TC_33_34.port_a.T - TC_33_34.port_b.T; TC_33_34.port_a.Q_flow = TC_33_34.Q_flow; TC_33_34.port_b.Q_flow = -TC_33_34.Q_flow; TC_33_46.Q_flow = TC_33_46.G * TC_33_46.dT; TC_33_46.dT = TC_33_46.port_a.T - TC_33_46.port_b.T; TC_33_46.port_a.Q_flow = TC_33_46.Q_flow; TC_33_46.port_b.Q_flow = -TC_33_46.Q_flow; TC_33_1471.Q_flow = TC_33_1471.G * TC_33_1471.dT; TC_33_1471.dT = TC_33_1471.port_a.T - TC_33_1471.port_b.T; TC_33_1471.port_a.Q_flow = TC_33_1471.Q_flow; TC_33_1471.port_b.Q_flow = -TC_33_1471.Q_flow; TC_34_35.Q_flow = TC_34_35.G * TC_34_35.dT; TC_34_35.dT = TC_34_35.port_a.T - TC_34_35.port_b.T; TC_34_35.port_a.Q_flow = TC_34_35.Q_flow; TC_34_35.port_b.Q_flow = -TC_34_35.Q_flow; TC_34_47.Q_flow = TC_34_47.G * TC_34_47.dT; TC_34_47.dT = TC_34_47.port_a.T - TC_34_47.port_b.T; TC_34_47.port_a.Q_flow = TC_34_47.Q_flow; TC_34_47.port_b.Q_flow = -TC_34_47.Q_flow; TC_34_1472.Q_flow = TC_34_1472.G * TC_34_1472.dT; TC_34_1472.dT = TC_34_1472.port_a.T - TC_34_1472.port_b.T; TC_34_1472.port_a.Q_flow = TC_34_1472.Q_flow; TC_34_1472.port_b.Q_flow = -TC_34_1472.Q_flow; TC_35_36.Q_flow = TC_35_36.G * TC_35_36.dT; TC_35_36.dT = TC_35_36.port_a.T - TC_35_36.port_b.T; TC_35_36.port_a.Q_flow = TC_35_36.Q_flow; TC_35_36.port_b.Q_flow = -TC_35_36.Q_flow; TC_35_48.Q_flow = TC_35_48.G * TC_35_48.dT; TC_35_48.dT = TC_35_48.port_a.T - TC_35_48.port_b.T; TC_35_48.port_a.Q_flow = TC_35_48.Q_flow; TC_35_48.port_b.Q_flow = -TC_35_48.Q_flow; TC_35_1473.Q_flow = TC_35_1473.G * TC_35_1473.dT; TC_35_1473.dT = TC_35_1473.port_a.T - TC_35_1473.port_b.T; TC_35_1473.port_a.Q_flow = TC_35_1473.Q_flow; TC_35_1473.port_b.Q_flow = -TC_35_1473.Q_flow; TC_36_37.Q_flow = TC_36_37.G * TC_36_37.dT; TC_36_37.dT = TC_36_37.port_a.T - TC_36_37.port_b.T; TC_36_37.port_a.Q_flow = TC_36_37.Q_flow; TC_36_37.port_b.Q_flow = -TC_36_37.Q_flow; TC_36_49.Q_flow = TC_36_49.G * TC_36_49.dT; TC_36_49.dT = TC_36_49.port_a.T - TC_36_49.port_b.T; TC_36_49.port_a.Q_flow = TC_36_49.Q_flow; TC_36_49.port_b.Q_flow = -TC_36_49.Q_flow; TC_36_1474.Q_flow = TC_36_1474.G * TC_36_1474.dT; TC_36_1474.dT = TC_36_1474.port_a.T - TC_36_1474.port_b.T; TC_36_1474.port_a.Q_flow = TC_36_1474.Q_flow; TC_36_1474.port_b.Q_flow = -TC_36_1474.Q_flow; TC_37_38.Q_flow = TC_37_38.G * TC_37_38.dT; TC_37_38.dT = TC_37_38.port_a.T - TC_37_38.port_b.T; TC_37_38.port_a.Q_flow = TC_37_38.Q_flow; TC_37_38.port_b.Q_flow = -TC_37_38.Q_flow; TC_37_50.Q_flow = TC_37_50.G * TC_37_50.dT; TC_37_50.dT = TC_37_50.port_a.T - TC_37_50.port_b.T; TC_37_50.port_a.Q_flow = TC_37_50.Q_flow; TC_37_50.port_b.Q_flow = -TC_37_50.Q_flow; TC_37_1475.Q_flow = TC_37_1475.G * TC_37_1475.dT; TC_37_1475.dT = TC_37_1475.port_a.T - TC_37_1475.port_b.T; TC_37_1475.port_a.Q_flow = TC_37_1475.Q_flow; TC_37_1475.port_b.Q_flow = -TC_37_1475.Q_flow; TC_38_39.Q_flow = TC_38_39.G * TC_38_39.dT; TC_38_39.dT = TC_38_39.port_a.T - TC_38_39.port_b.T; TC_38_39.port_a.Q_flow = TC_38_39.Q_flow; TC_38_39.port_b.Q_flow = -TC_38_39.Q_flow; TC_38_51.Q_flow = TC_38_51.G * TC_38_51.dT; TC_38_51.dT = TC_38_51.port_a.T - TC_38_51.port_b.T; TC_38_51.port_a.Q_flow = TC_38_51.Q_flow; TC_38_51.port_b.Q_flow = -TC_38_51.Q_flow; TC_38_1476.Q_flow = TC_38_1476.G * TC_38_1476.dT; TC_38_1476.dT = TC_38_1476.port_a.T - TC_38_1476.port_b.T; TC_38_1476.port_a.Q_flow = TC_38_1476.Q_flow; TC_38_1476.port_b.Q_flow = -TC_38_1476.Q_flow; TC_39_52.Q_flow = TC_39_52.G * TC_39_52.dT; TC_39_52.dT = TC_39_52.port_a.T - TC_39_52.port_b.T; TC_39_52.port_a.Q_flow = TC_39_52.Q_flow; TC_39_52.port_b.Q_flow = -TC_39_52.Q_flow; TC_39_224.Q_flow = TC_39_224.G * TC_39_224.dT; TC_39_224.dT = TC_39_224.port_a.T - TC_39_224.port_b.T; TC_39_224.port_a.Q_flow = TC_39_224.Q_flow; TC_39_224.port_b.Q_flow = -TC_39_224.Q_flow; TC_40_41.Q_flow = TC_40_41.G * TC_40_41.dT; TC_40_41.dT = TC_40_41.port_a.T - TC_40_41.port_b.T; TC_40_41.port_a.Q_flow = TC_40_41.Q_flow; TC_40_41.port_b.Q_flow = -TC_40_41.Q_flow; TC_40_53.Q_flow = TC_40_53.G * TC_40_53.dT; TC_40_53.dT = TC_40_53.port_a.T - TC_40_53.port_b.T; TC_40_53.port_a.Q_flow = TC_40_53.Q_flow; TC_40_53.port_b.Q_flow = -TC_40_53.Q_flow; TC_40_225.Q_flow = TC_40_225.G * TC_40_225.dT; TC_40_225.dT = TC_40_225.port_a.T - TC_40_225.port_b.T; TC_40_225.port_a.Q_flow = TC_40_225.Q_flow; TC_40_225.port_b.Q_flow = -TC_40_225.Q_flow; TC_41_42.Q_flow = TC_41_42.G * TC_41_42.dT; TC_41_42.dT = TC_41_42.port_a.T - TC_41_42.port_b.T; TC_41_42.port_a.Q_flow = TC_41_42.Q_flow; TC_41_42.port_b.Q_flow = -TC_41_42.Q_flow; TC_41_54.Q_flow = TC_41_54.G * TC_41_54.dT; TC_41_54.dT = TC_41_54.port_a.T - TC_41_54.port_b.T; TC_41_54.port_a.Q_flow = TC_41_54.Q_flow; TC_41_54.port_b.Q_flow = -TC_41_54.Q_flow; TC_41_1461.Q_flow = TC_41_1461.G * TC_41_1461.dT; TC_41_1461.dT = TC_41_1461.port_a.T - TC_41_1461.port_b.T; TC_41_1461.port_a.Q_flow = TC_41_1461.Q_flow; TC_41_1461.port_b.Q_flow = -TC_41_1461.Q_flow; TC_42_43.Q_flow = TC_42_43.G * TC_42_43.dT; TC_42_43.dT = TC_42_43.port_a.T - TC_42_43.port_b.T; TC_42_43.port_a.Q_flow = TC_42_43.Q_flow; TC_42_43.port_b.Q_flow = -TC_42_43.Q_flow; TC_42_55.Q_flow = TC_42_55.G * TC_42_55.dT; TC_42_55.dT = TC_42_55.port_a.T - TC_42_55.port_b.T; TC_42_55.port_a.Q_flow = TC_42_55.Q_flow; TC_42_55.port_b.Q_flow = -TC_42_55.Q_flow; TC_42_1462.Q_flow = TC_42_1462.G * TC_42_1462.dT; TC_42_1462.dT = TC_42_1462.port_a.T - TC_42_1462.port_b.T; TC_42_1462.port_a.Q_flow = TC_42_1462.Q_flow; TC_42_1462.port_b.Q_flow = -TC_42_1462.Q_flow; TC_43_44.Q_flow = TC_43_44.G * TC_43_44.dT; TC_43_44.dT = TC_43_44.port_a.T - TC_43_44.port_b.T; TC_43_44.port_a.Q_flow = TC_43_44.Q_flow; TC_43_44.port_b.Q_flow = -TC_43_44.Q_flow; TC_43_56.Q_flow = TC_43_56.G * TC_43_56.dT; TC_43_56.dT = TC_43_56.port_a.T - TC_43_56.port_b.T; TC_43_56.port_a.Q_flow = TC_43_56.Q_flow; TC_43_56.port_b.Q_flow = -TC_43_56.Q_flow; TC_43_813.Q_flow = TC_43_813.G * TC_43_813.dT; TC_43_813.dT = TC_43_813.port_a.T - TC_43_813.port_b.T; TC_43_813.port_a.Q_flow = TC_43_813.Q_flow; TC_43_813.port_b.Q_flow = -TC_43_813.Q_flow; TC_44_45.Q_flow = TC_44_45.G * TC_44_45.dT; TC_44_45.dT = TC_44_45.port_a.T - TC_44_45.port_b.T; TC_44_45.port_a.Q_flow = TC_44_45.Q_flow; TC_44_45.port_b.Q_flow = -TC_44_45.Q_flow; TC_44_57.Q_flow = TC_44_57.G * TC_44_57.dT; TC_44_57.dT = TC_44_57.port_a.T - TC_44_57.port_b.T; TC_44_57.port_a.Q_flow = TC_44_57.Q_flow; TC_44_57.port_b.Q_flow = -TC_44_57.Q_flow; TC_44_814.Q_flow = TC_44_814.G * TC_44_814.dT; TC_44_814.dT = TC_44_814.port_a.T - TC_44_814.port_b.T; TC_44_814.port_a.Q_flow = TC_44_814.Q_flow; TC_44_814.port_b.Q_flow = -TC_44_814.Q_flow; TC_45_46.Q_flow = TC_45_46.G * TC_45_46.dT; TC_45_46.dT = TC_45_46.port_a.T - TC_45_46.port_b.T; TC_45_46.port_a.Q_flow = TC_45_46.Q_flow; TC_45_46.port_b.Q_flow = -TC_45_46.Q_flow; TC_45_58.Q_flow = TC_45_58.G * TC_45_58.dT; TC_45_58.dT = TC_45_58.port_a.T - TC_45_58.port_b.T; TC_45_58.port_a.Q_flow = TC_45_58.Q_flow; TC_45_58.port_b.Q_flow = -TC_45_58.Q_flow; TC_45_815.Q_flow = TC_45_815.G * TC_45_815.dT; TC_45_815.dT = TC_45_815.port_a.T - TC_45_815.port_b.T; TC_45_815.port_a.Q_flow = TC_45_815.Q_flow; TC_45_815.port_b.Q_flow = -TC_45_815.Q_flow; TC_46_47.Q_flow = TC_46_47.G * TC_46_47.dT; TC_46_47.dT = TC_46_47.port_a.T - TC_46_47.port_b.T; TC_46_47.port_a.Q_flow = TC_46_47.Q_flow; TC_46_47.port_b.Q_flow = -TC_46_47.Q_flow; TC_46_59.Q_flow = TC_46_59.G * TC_46_59.dT; TC_46_59.dT = TC_46_59.port_a.T - TC_46_59.port_b.T; TC_46_59.port_a.Q_flow = TC_46_59.Q_flow; TC_46_59.port_b.Q_flow = -TC_46_59.Q_flow; TC_46_816.Q_flow = TC_46_816.G * TC_46_816.dT; TC_46_816.dT = TC_46_816.port_a.T - TC_46_816.port_b.T; TC_46_816.port_a.Q_flow = TC_46_816.Q_flow; TC_46_816.port_b.Q_flow = -TC_46_816.Q_flow; TC_47_48.Q_flow = TC_47_48.G * TC_47_48.dT; TC_47_48.dT = TC_47_48.port_a.T - TC_47_48.port_b.T; TC_47_48.port_a.Q_flow = TC_47_48.Q_flow; TC_47_48.port_b.Q_flow = -TC_47_48.Q_flow; TC_47_60.Q_flow = TC_47_60.G * TC_47_60.dT; TC_47_60.dT = TC_47_60.port_a.T - TC_47_60.port_b.T; TC_47_60.port_a.Q_flow = TC_47_60.Q_flow; TC_47_60.port_b.Q_flow = -TC_47_60.Q_flow; TC_47_817.Q_flow = TC_47_817.G * TC_47_817.dT; TC_47_817.dT = TC_47_817.port_a.T - TC_47_817.port_b.T; TC_47_817.port_a.Q_flow = TC_47_817.Q_flow; TC_47_817.port_b.Q_flow = -TC_47_817.Q_flow; TC_48_49.Q_flow = TC_48_49.G * TC_48_49.dT; TC_48_49.dT = TC_48_49.port_a.T - TC_48_49.port_b.T; TC_48_49.port_a.Q_flow = TC_48_49.Q_flow; TC_48_49.port_b.Q_flow = -TC_48_49.Q_flow; TC_48_61.Q_flow = TC_48_61.G * TC_48_61.dT; TC_48_61.dT = TC_48_61.port_a.T - TC_48_61.port_b.T; TC_48_61.port_a.Q_flow = TC_48_61.Q_flow; TC_48_61.port_b.Q_flow = -TC_48_61.Q_flow; TC_48_818.Q_flow = TC_48_818.G * TC_48_818.dT; TC_48_818.dT = TC_48_818.port_a.T - TC_48_818.port_b.T; TC_48_818.port_a.Q_flow = TC_48_818.Q_flow; TC_48_818.port_b.Q_flow = -TC_48_818.Q_flow; TC_49_50.Q_flow = TC_49_50.G * TC_49_50.dT; TC_49_50.dT = TC_49_50.port_a.T - TC_49_50.port_b.T; TC_49_50.port_a.Q_flow = TC_49_50.Q_flow; TC_49_50.port_b.Q_flow = -TC_49_50.Q_flow; TC_49_62.Q_flow = TC_49_62.G * TC_49_62.dT; TC_49_62.dT = TC_49_62.port_a.T - TC_49_62.port_b.T; TC_49_62.port_a.Q_flow = TC_49_62.Q_flow; TC_49_62.port_b.Q_flow = -TC_49_62.Q_flow; TC_49_819.Q_flow = TC_49_819.G * TC_49_819.dT; TC_49_819.dT = TC_49_819.port_a.T - TC_49_819.port_b.T; TC_49_819.port_a.Q_flow = TC_49_819.Q_flow; TC_49_819.port_b.Q_flow = -TC_49_819.Q_flow; TC_50_51.Q_flow = TC_50_51.G * TC_50_51.dT; TC_50_51.dT = TC_50_51.port_a.T - TC_50_51.port_b.T; TC_50_51.port_a.Q_flow = TC_50_51.Q_flow; TC_50_51.port_b.Q_flow = -TC_50_51.Q_flow; TC_50_63.Q_flow = TC_50_63.G * TC_50_63.dT; TC_50_63.dT = TC_50_63.port_a.T - TC_50_63.port_b.T; TC_50_63.port_a.Q_flow = TC_50_63.Q_flow; TC_50_63.port_b.Q_flow = -TC_50_63.Q_flow; TC_50_820.Q_flow = TC_50_820.G * TC_50_820.dT; TC_50_820.dT = TC_50_820.port_a.T - TC_50_820.port_b.T; TC_50_820.port_a.Q_flow = TC_50_820.Q_flow; TC_50_820.port_b.Q_flow = -TC_50_820.Q_flow; TC_51_52.Q_flow = TC_51_52.G * TC_51_52.dT; TC_51_52.dT = TC_51_52.port_a.T - TC_51_52.port_b.T; TC_51_52.port_a.Q_flow = TC_51_52.Q_flow; TC_51_52.port_b.Q_flow = -TC_51_52.Q_flow; TC_51_64.Q_flow = TC_51_64.G * TC_51_64.dT; TC_51_64.dT = TC_51_64.port_a.T - TC_51_64.port_b.T; TC_51_64.port_a.Q_flow = TC_51_64.Q_flow; TC_51_64.port_b.Q_flow = -TC_51_64.Q_flow; TC_51_1463.Q_flow = TC_51_1463.G * TC_51_1463.dT; TC_51_1463.dT = TC_51_1463.port_a.T - TC_51_1463.port_b.T; TC_51_1463.port_a.Q_flow = TC_51_1463.Q_flow; TC_51_1463.port_b.Q_flow = -TC_51_1463.Q_flow; TC_52_65.Q_flow = TC_52_65.G * TC_52_65.dT; TC_52_65.dT = TC_52_65.port_a.T - TC_52_65.port_b.T; TC_52_65.port_a.Q_flow = TC_52_65.Q_flow; TC_52_65.port_b.Q_flow = -TC_52_65.Q_flow; TC_52_226.Q_flow = TC_52_226.G * TC_52_226.dT; TC_52_226.dT = TC_52_226.port_a.T - TC_52_226.port_b.T; TC_52_226.port_a.Q_flow = TC_52_226.Q_flow; TC_52_226.port_b.Q_flow = -TC_52_226.Q_flow; TC_53_54.Q_flow = TC_53_54.G * TC_53_54.dT; TC_53_54.dT = TC_53_54.port_a.T - TC_53_54.port_b.T; TC_53_54.port_a.Q_flow = TC_53_54.Q_flow; TC_53_54.port_b.Q_flow = -TC_53_54.Q_flow; TC_53_66.Q_flow = TC_53_66.G * TC_53_66.dT; TC_53_66.dT = TC_53_66.port_a.T - TC_53_66.port_b.T; TC_53_66.port_a.Q_flow = TC_53_66.Q_flow; TC_53_66.port_b.Q_flow = -TC_53_66.Q_flow; TC_53_227.Q_flow = TC_53_227.G * TC_53_227.dT; TC_53_227.dT = TC_53_227.port_a.T - TC_53_227.port_b.T; TC_53_227.port_a.Q_flow = TC_53_227.Q_flow; TC_53_227.port_b.Q_flow = -TC_53_227.Q_flow; TC_54_55.Q_flow = TC_54_55.G * TC_54_55.dT; TC_54_55.dT = TC_54_55.port_a.T - TC_54_55.port_b.T; TC_54_55.port_a.Q_flow = TC_54_55.Q_flow; TC_54_55.port_b.Q_flow = -TC_54_55.Q_flow; TC_54_67.Q_flow = TC_54_67.G * TC_54_67.dT; TC_54_67.dT = TC_54_67.port_a.T - TC_54_67.port_b.T; TC_54_67.port_a.Q_flow = TC_54_67.Q_flow; TC_54_67.port_b.Q_flow = -TC_54_67.Q_flow; TC_54_1464.Q_flow = TC_54_1464.G * TC_54_1464.dT; TC_54_1464.dT = TC_54_1464.port_a.T - TC_54_1464.port_b.T; TC_54_1464.port_a.Q_flow = TC_54_1464.Q_flow; TC_54_1464.port_b.Q_flow = -TC_54_1464.Q_flow; TC_55_56.Q_flow = TC_55_56.G * TC_55_56.dT; TC_55_56.dT = TC_55_56.port_a.T - TC_55_56.port_b.T; TC_55_56.port_a.Q_flow = TC_55_56.Q_flow; TC_55_56.port_b.Q_flow = -TC_55_56.Q_flow; TC_55_68.Q_flow = TC_55_68.G * TC_55_68.dT; TC_55_68.dT = TC_55_68.port_a.T - TC_55_68.port_b.T; TC_55_68.port_a.Q_flow = TC_55_68.Q_flow; TC_55_68.port_b.Q_flow = -TC_55_68.Q_flow; TC_55_1465.Q_flow = TC_55_1465.G * TC_55_1465.dT; TC_55_1465.dT = TC_55_1465.port_a.T - TC_55_1465.port_b.T; TC_55_1465.port_a.Q_flow = TC_55_1465.Q_flow; TC_55_1465.port_b.Q_flow = -TC_55_1465.Q_flow; TC_56_57.Q_flow = TC_56_57.G * TC_56_57.dT; TC_56_57.dT = TC_56_57.port_a.T - TC_56_57.port_b.T; TC_56_57.port_a.Q_flow = TC_56_57.Q_flow; TC_56_57.port_b.Q_flow = -TC_56_57.Q_flow; TC_56_69.Q_flow = TC_56_69.G * TC_56_69.dT; TC_56_69.dT = TC_56_69.port_a.T - TC_56_69.port_b.T; TC_56_69.port_a.Q_flow = TC_56_69.Q_flow; TC_56_69.port_b.Q_flow = -TC_56_69.Q_flow; TC_56_741.Q_flow = TC_56_741.G * TC_56_741.dT; TC_56_741.dT = TC_56_741.port_a.T - TC_56_741.port_b.T; TC_56_741.port_a.Q_flow = TC_56_741.Q_flow; TC_56_741.port_b.Q_flow = -TC_56_741.Q_flow; TC_57_58.Q_flow = TC_57_58.G * TC_57_58.dT; TC_57_58.dT = TC_57_58.port_a.T - TC_57_58.port_b.T; TC_57_58.port_a.Q_flow = TC_57_58.Q_flow; TC_57_58.port_b.Q_flow = -TC_57_58.Q_flow; TC_57_70.Q_flow = TC_57_70.G * TC_57_70.dT; TC_57_70.dT = TC_57_70.port_a.T - TC_57_70.port_b.T; TC_57_70.port_a.Q_flow = TC_57_70.Q_flow; TC_57_70.port_b.Q_flow = -TC_57_70.Q_flow; TC_57_742.Q_flow = TC_57_742.G * TC_57_742.dT; TC_57_742.dT = TC_57_742.port_a.T - TC_57_742.port_b.T; TC_57_742.port_a.Q_flow = TC_57_742.Q_flow; TC_57_742.port_b.Q_flow = -TC_57_742.Q_flow; TC_58_59.Q_flow = TC_58_59.G * TC_58_59.dT; TC_58_59.dT = TC_58_59.port_a.T - TC_58_59.port_b.T; TC_58_59.port_a.Q_flow = TC_58_59.Q_flow; TC_58_59.port_b.Q_flow = -TC_58_59.Q_flow; TC_58_71.Q_flow = TC_58_71.G * TC_58_71.dT; TC_58_71.dT = TC_58_71.port_a.T - TC_58_71.port_b.T; TC_58_71.port_a.Q_flow = TC_58_71.Q_flow; TC_58_71.port_b.Q_flow = -TC_58_71.Q_flow; TC_58_743.Q_flow = TC_58_743.G * TC_58_743.dT; TC_58_743.dT = TC_58_743.port_a.T - TC_58_743.port_b.T; TC_58_743.port_a.Q_flow = TC_58_743.Q_flow; TC_58_743.port_b.Q_flow = -TC_58_743.Q_flow; TC_59_60.Q_flow = TC_59_60.G * TC_59_60.dT; TC_59_60.dT = TC_59_60.port_a.T - TC_59_60.port_b.T; TC_59_60.port_a.Q_flow = TC_59_60.Q_flow; TC_59_60.port_b.Q_flow = -TC_59_60.Q_flow; TC_59_72.Q_flow = TC_59_72.G * TC_59_72.dT; TC_59_72.dT = TC_59_72.port_a.T - TC_59_72.port_b.T; TC_59_72.port_a.Q_flow = TC_59_72.Q_flow; TC_59_72.port_b.Q_flow = -TC_59_72.Q_flow; TC_59_744.Q_flow = TC_59_744.G * TC_59_744.dT; TC_59_744.dT = TC_59_744.port_a.T - TC_59_744.port_b.T; TC_59_744.port_a.Q_flow = TC_59_744.Q_flow; TC_59_744.port_b.Q_flow = -TC_59_744.Q_flow; TC_60_61.Q_flow = TC_60_61.G * TC_60_61.dT; TC_60_61.dT = TC_60_61.port_a.T - TC_60_61.port_b.T; TC_60_61.port_a.Q_flow = TC_60_61.Q_flow; TC_60_61.port_b.Q_flow = -TC_60_61.Q_flow; TC_60_73.Q_flow = TC_60_73.G * TC_60_73.dT; TC_60_73.dT = TC_60_73.port_a.T - TC_60_73.port_b.T; TC_60_73.port_a.Q_flow = TC_60_73.Q_flow; TC_60_73.port_b.Q_flow = -TC_60_73.Q_flow; TC_60_745.Q_flow = TC_60_745.G * TC_60_745.dT; TC_60_745.dT = TC_60_745.port_a.T - TC_60_745.port_b.T; TC_60_745.port_a.Q_flow = TC_60_745.Q_flow; TC_60_745.port_b.Q_flow = -TC_60_745.Q_flow; TC_61_62.Q_flow = TC_61_62.G * TC_61_62.dT; TC_61_62.dT = TC_61_62.port_a.T - TC_61_62.port_b.T; TC_61_62.port_a.Q_flow = TC_61_62.Q_flow; TC_61_62.port_b.Q_flow = -TC_61_62.Q_flow; TC_61_74.Q_flow = TC_61_74.G * TC_61_74.dT; TC_61_74.dT = TC_61_74.port_a.T - TC_61_74.port_b.T; TC_61_74.port_a.Q_flow = TC_61_74.Q_flow; TC_61_74.port_b.Q_flow = -TC_61_74.Q_flow; TC_61_746.Q_flow = TC_61_746.G * TC_61_746.dT; TC_61_746.dT = TC_61_746.port_a.T - TC_61_746.port_b.T; TC_61_746.port_a.Q_flow = TC_61_746.Q_flow; TC_61_746.port_b.Q_flow = -TC_61_746.Q_flow; TC_62_63.Q_flow = TC_62_63.G * TC_62_63.dT; TC_62_63.dT = TC_62_63.port_a.T - TC_62_63.port_b.T; TC_62_63.port_a.Q_flow = TC_62_63.Q_flow; TC_62_63.port_b.Q_flow = -TC_62_63.Q_flow; TC_62_75.Q_flow = TC_62_75.G * TC_62_75.dT; TC_62_75.dT = TC_62_75.port_a.T - TC_62_75.port_b.T; TC_62_75.port_a.Q_flow = TC_62_75.Q_flow; TC_62_75.port_b.Q_flow = -TC_62_75.Q_flow; TC_62_747.Q_flow = TC_62_747.G * TC_62_747.dT; TC_62_747.dT = TC_62_747.port_a.T - TC_62_747.port_b.T; TC_62_747.port_a.Q_flow = TC_62_747.Q_flow; TC_62_747.port_b.Q_flow = -TC_62_747.Q_flow; TC_63_64.Q_flow = TC_63_64.G * TC_63_64.dT; TC_63_64.dT = TC_63_64.port_a.T - TC_63_64.port_b.T; TC_63_64.port_a.Q_flow = TC_63_64.Q_flow; TC_63_64.port_b.Q_flow = -TC_63_64.Q_flow; TC_63_76.Q_flow = TC_63_76.G * TC_63_76.dT; TC_63_76.dT = TC_63_76.port_a.T - TC_63_76.port_b.T; TC_63_76.port_a.Q_flow = TC_63_76.Q_flow; TC_63_76.port_b.Q_flow = -TC_63_76.Q_flow; TC_63_748.Q_flow = TC_63_748.G * TC_63_748.dT; TC_63_748.dT = TC_63_748.port_a.T - TC_63_748.port_b.T; TC_63_748.port_a.Q_flow = TC_63_748.Q_flow; TC_63_748.port_b.Q_flow = -TC_63_748.Q_flow; TC_64_65.Q_flow = TC_64_65.G * TC_64_65.dT; TC_64_65.dT = TC_64_65.port_a.T - TC_64_65.port_b.T; TC_64_65.port_a.Q_flow = TC_64_65.Q_flow; TC_64_65.port_b.Q_flow = -TC_64_65.Q_flow; TC_64_77.Q_flow = TC_64_77.G * TC_64_77.dT; TC_64_77.dT = TC_64_77.port_a.T - TC_64_77.port_b.T; TC_64_77.port_a.Q_flow = TC_64_77.Q_flow; TC_64_77.port_b.Q_flow = -TC_64_77.Q_flow; TC_64_1414.Q_flow = TC_64_1414.G * TC_64_1414.dT; TC_64_1414.dT = TC_64_1414.port_a.T - TC_64_1414.port_b.T; TC_64_1414.port_a.Q_flow = TC_64_1414.Q_flow; TC_64_1414.port_b.Q_flow = -TC_64_1414.Q_flow; TC_65_78.Q_flow = TC_65_78.G * TC_65_78.dT; TC_65_78.dT = TC_65_78.port_a.T - TC_65_78.port_b.T; TC_65_78.port_a.Q_flow = TC_65_78.Q_flow; TC_65_78.port_b.Q_flow = -TC_65_78.Q_flow; TC_65_228.Q_flow = TC_65_228.G * TC_65_228.dT; TC_65_228.dT = TC_65_228.port_a.T - TC_65_228.port_b.T; TC_65_228.port_a.Q_flow = TC_65_228.Q_flow; TC_65_228.port_b.Q_flow = -TC_65_228.Q_flow; TC_66_67.Q_flow = TC_66_67.G * TC_66_67.dT; TC_66_67.dT = TC_66_67.port_a.T - TC_66_67.port_b.T; TC_66_67.port_a.Q_flow = TC_66_67.Q_flow; TC_66_67.port_b.Q_flow = -TC_66_67.Q_flow; TC_66_79.Q_flow = TC_66_79.G * TC_66_79.dT; TC_66_79.dT = TC_66_79.port_a.T - TC_66_79.port_b.T; TC_66_79.port_a.Q_flow = TC_66_79.Q_flow; TC_66_79.port_b.Q_flow = -TC_66_79.Q_flow; TC_66_229.Q_flow = TC_66_229.G * TC_66_229.dT; TC_66_229.dT = TC_66_229.port_a.T - TC_66_229.port_b.T; TC_66_229.port_a.Q_flow = TC_66_229.Q_flow; TC_66_229.port_b.Q_flow = -TC_66_229.Q_flow; TC_67_68.Q_flow = TC_67_68.G * TC_67_68.dT; TC_67_68.dT = TC_67_68.port_a.T - TC_67_68.port_b.T; TC_67_68.port_a.Q_flow = TC_67_68.Q_flow; TC_67_68.port_b.Q_flow = -TC_67_68.Q_flow; TC_67_80.Q_flow = TC_67_80.G * TC_67_80.dT; TC_67_80.dT = TC_67_80.port_a.T - TC_67_80.port_b.T; TC_67_80.port_a.Q_flow = TC_67_80.Q_flow; TC_67_80.port_b.Q_flow = -TC_67_80.Q_flow; TC_67_1415.Q_flow = TC_67_1415.G * TC_67_1415.dT; TC_67_1415.dT = TC_67_1415.port_a.T - TC_67_1415.port_b.T; TC_67_1415.port_a.Q_flow = TC_67_1415.Q_flow; TC_67_1415.port_b.Q_flow = -TC_67_1415.Q_flow; TC_68_69.Q_flow = TC_68_69.G * TC_68_69.dT; TC_68_69.dT = TC_68_69.port_a.T - TC_68_69.port_b.T; TC_68_69.port_a.Q_flow = TC_68_69.Q_flow; TC_68_69.port_b.Q_flow = -TC_68_69.Q_flow; TC_68_81.Q_flow = TC_68_81.G * TC_68_81.dT; TC_68_81.dT = TC_68_81.port_a.T - TC_68_81.port_b.T; TC_68_81.port_a.Q_flow = TC_68_81.Q_flow; TC_68_81.port_b.Q_flow = -TC_68_81.Q_flow; TC_68_1416.Q_flow = TC_68_1416.G * TC_68_1416.dT; TC_68_1416.dT = TC_68_1416.port_a.T - TC_68_1416.port_b.T; TC_68_1416.port_a.Q_flow = TC_68_1416.Q_flow; TC_68_1416.port_b.Q_flow = -TC_68_1416.Q_flow; TC_69_70.Q_flow = TC_69_70.G * TC_69_70.dT; TC_69_70.dT = TC_69_70.port_a.T - TC_69_70.port_b.T; TC_69_70.port_a.Q_flow = TC_69_70.Q_flow; TC_69_70.port_b.Q_flow = -TC_69_70.Q_flow; TC_69_82.Q_flow = TC_69_82.G * TC_69_82.dT; TC_69_82.dT = TC_69_82.port_a.T - TC_69_82.port_b.T; TC_69_82.port_a.Q_flow = TC_69_82.Q_flow; TC_69_82.port_b.Q_flow = -TC_69_82.Q_flow; TC_69_749.Q_flow = TC_69_749.G * TC_69_749.dT; TC_69_749.dT = TC_69_749.port_a.T - TC_69_749.port_b.T; TC_69_749.port_a.Q_flow = TC_69_749.Q_flow; TC_69_749.port_b.Q_flow = -TC_69_749.Q_flow; TC_70_71.Q_flow = TC_70_71.G * TC_70_71.dT; TC_70_71.dT = TC_70_71.port_a.T - TC_70_71.port_b.T; TC_70_71.port_a.Q_flow = TC_70_71.Q_flow; TC_70_71.port_b.Q_flow = -TC_70_71.Q_flow; TC_70_83.Q_flow = TC_70_83.G * TC_70_83.dT; TC_70_83.dT = TC_70_83.port_a.T - TC_70_83.port_b.T; TC_70_83.port_a.Q_flow = TC_70_83.Q_flow; TC_70_83.port_b.Q_flow = -TC_70_83.Q_flow; TC_70_750.Q_flow = TC_70_750.G * TC_70_750.dT; TC_70_750.dT = TC_70_750.port_a.T - TC_70_750.port_b.T; TC_70_750.port_a.Q_flow = TC_70_750.Q_flow; TC_70_750.port_b.Q_flow = -TC_70_750.Q_flow; TC_71_72.Q_flow = TC_71_72.G * TC_71_72.dT; TC_71_72.dT = TC_71_72.port_a.T - TC_71_72.port_b.T; TC_71_72.port_a.Q_flow = TC_71_72.Q_flow; TC_71_72.port_b.Q_flow = -TC_71_72.Q_flow; TC_71_84.Q_flow = TC_71_84.G * TC_71_84.dT; TC_71_84.dT = TC_71_84.port_a.T - TC_71_84.port_b.T; TC_71_84.port_a.Q_flow = TC_71_84.Q_flow; TC_71_84.port_b.Q_flow = -TC_71_84.Q_flow; TC_71_751.Q_flow = TC_71_751.G * TC_71_751.dT; TC_71_751.dT = TC_71_751.port_a.T - TC_71_751.port_b.T; TC_71_751.port_a.Q_flow = TC_71_751.Q_flow; TC_71_751.port_b.Q_flow = -TC_71_751.Q_flow; TC_72_73.Q_flow = TC_72_73.G * TC_72_73.dT; TC_72_73.dT = TC_72_73.port_a.T - TC_72_73.port_b.T; TC_72_73.port_a.Q_flow = TC_72_73.Q_flow; TC_72_73.port_b.Q_flow = -TC_72_73.Q_flow; TC_72_85.Q_flow = TC_72_85.G * TC_72_85.dT; TC_72_85.dT = TC_72_85.port_a.T - TC_72_85.port_b.T; TC_72_85.port_a.Q_flow = TC_72_85.Q_flow; TC_72_85.port_b.Q_flow = -TC_72_85.Q_flow; TC_72_752.Q_flow = TC_72_752.G * TC_72_752.dT; TC_72_752.dT = TC_72_752.port_a.T - TC_72_752.port_b.T; TC_72_752.port_a.Q_flow = TC_72_752.Q_flow; TC_72_752.port_b.Q_flow = -TC_72_752.Q_flow; TC_73_74.Q_flow = TC_73_74.G * TC_73_74.dT; TC_73_74.dT = TC_73_74.port_a.T - TC_73_74.port_b.T; TC_73_74.port_a.Q_flow = TC_73_74.Q_flow; TC_73_74.port_b.Q_flow = -TC_73_74.Q_flow; TC_73_86.Q_flow = TC_73_86.G * TC_73_86.dT; TC_73_86.dT = TC_73_86.port_a.T - TC_73_86.port_b.T; TC_73_86.port_a.Q_flow = TC_73_86.Q_flow; TC_73_86.port_b.Q_flow = -TC_73_86.Q_flow; TC_73_753.Q_flow = TC_73_753.G * TC_73_753.dT; TC_73_753.dT = TC_73_753.port_a.T - TC_73_753.port_b.T; TC_73_753.port_a.Q_flow = TC_73_753.Q_flow; TC_73_753.port_b.Q_flow = -TC_73_753.Q_flow; TC_74_75.Q_flow = TC_74_75.G * TC_74_75.dT; TC_74_75.dT = TC_74_75.port_a.T - TC_74_75.port_b.T; TC_74_75.port_a.Q_flow = TC_74_75.Q_flow; TC_74_75.port_b.Q_flow = -TC_74_75.Q_flow; TC_74_87.Q_flow = TC_74_87.G * TC_74_87.dT; TC_74_87.dT = TC_74_87.port_a.T - TC_74_87.port_b.T; TC_74_87.port_a.Q_flow = TC_74_87.Q_flow; TC_74_87.port_b.Q_flow = -TC_74_87.Q_flow; TC_74_754.Q_flow = TC_74_754.G * TC_74_754.dT; TC_74_754.dT = TC_74_754.port_a.T - TC_74_754.port_b.T; TC_74_754.port_a.Q_flow = TC_74_754.Q_flow; TC_74_754.port_b.Q_flow = -TC_74_754.Q_flow; TC_75_76.Q_flow = TC_75_76.G * TC_75_76.dT; TC_75_76.dT = TC_75_76.port_a.T - TC_75_76.port_b.T; TC_75_76.port_a.Q_flow = TC_75_76.Q_flow; TC_75_76.port_b.Q_flow = -TC_75_76.Q_flow; TC_75_88.Q_flow = TC_75_88.G * TC_75_88.dT; TC_75_88.dT = TC_75_88.port_a.T - TC_75_88.port_b.T; TC_75_88.port_a.Q_flow = TC_75_88.Q_flow; TC_75_88.port_b.Q_flow = -TC_75_88.Q_flow; TC_75_755.Q_flow = TC_75_755.G * TC_75_755.dT; TC_75_755.dT = TC_75_755.port_a.T - TC_75_755.port_b.T; TC_75_755.port_a.Q_flow = TC_75_755.Q_flow; TC_75_755.port_b.Q_flow = -TC_75_755.Q_flow; TC_76_77.Q_flow = TC_76_77.G * TC_76_77.dT; TC_76_77.dT = TC_76_77.port_a.T - TC_76_77.port_b.T; TC_76_77.port_a.Q_flow = TC_76_77.Q_flow; TC_76_77.port_b.Q_flow = -TC_76_77.Q_flow; TC_76_89.Q_flow = TC_76_89.G * TC_76_89.dT; TC_76_89.dT = TC_76_89.port_a.T - TC_76_89.port_b.T; TC_76_89.port_a.Q_flow = TC_76_89.Q_flow; TC_76_89.port_b.Q_flow = -TC_76_89.Q_flow; TC_76_756.Q_flow = TC_76_756.G * TC_76_756.dT; TC_76_756.dT = TC_76_756.port_a.T - TC_76_756.port_b.T; TC_76_756.port_a.Q_flow = TC_76_756.Q_flow; TC_76_756.port_b.Q_flow = -TC_76_756.Q_flow; TC_77_78.Q_flow = TC_77_78.G * TC_77_78.dT; TC_77_78.dT = TC_77_78.port_a.T - TC_77_78.port_b.T; TC_77_78.port_a.Q_flow = TC_77_78.Q_flow; TC_77_78.port_b.Q_flow = -TC_77_78.Q_flow; TC_77_90.Q_flow = TC_77_90.G * TC_77_90.dT; TC_77_90.dT = TC_77_90.port_a.T - TC_77_90.port_b.T; TC_77_90.port_a.Q_flow = TC_77_90.Q_flow; TC_77_90.port_b.Q_flow = -TC_77_90.Q_flow; TC_77_1417.Q_flow = TC_77_1417.G * TC_77_1417.dT; TC_77_1417.dT = TC_77_1417.port_a.T - TC_77_1417.port_b.T; TC_77_1417.port_a.Q_flow = TC_77_1417.Q_flow; TC_77_1417.port_b.Q_flow = -TC_77_1417.Q_flow; TC_78_91.Q_flow = TC_78_91.G * TC_78_91.dT; TC_78_91.dT = TC_78_91.port_a.T - TC_78_91.port_b.T; TC_78_91.port_a.Q_flow = TC_78_91.Q_flow; TC_78_91.port_b.Q_flow = -TC_78_91.Q_flow; TC_78_230.Q_flow = TC_78_230.G * TC_78_230.dT; TC_78_230.dT = TC_78_230.port_a.T - TC_78_230.port_b.T; TC_78_230.port_a.Q_flow = TC_78_230.Q_flow; TC_78_230.port_b.Q_flow = -TC_78_230.Q_flow; TC_79_80.Q_flow = TC_79_80.G * TC_79_80.dT; TC_79_80.dT = TC_79_80.port_a.T - TC_79_80.port_b.T; TC_79_80.port_a.Q_flow = TC_79_80.Q_flow; TC_79_80.port_b.Q_flow = -TC_79_80.Q_flow; TC_79_92.Q_flow = TC_79_92.G * TC_79_92.dT; TC_79_92.dT = TC_79_92.port_a.T - TC_79_92.port_b.T; TC_79_92.port_a.Q_flow = TC_79_92.Q_flow; TC_79_92.port_b.Q_flow = -TC_79_92.Q_flow; TC_79_231.Q_flow = TC_79_231.G * TC_79_231.dT; TC_79_231.dT = TC_79_231.port_a.T - TC_79_231.port_b.T; TC_79_231.port_a.Q_flow = TC_79_231.Q_flow; TC_79_231.port_b.Q_flow = -TC_79_231.Q_flow; TC_80_81.Q_flow = TC_80_81.G * TC_80_81.dT; TC_80_81.dT = TC_80_81.port_a.T - TC_80_81.port_b.T; TC_80_81.port_a.Q_flow = TC_80_81.Q_flow; TC_80_81.port_b.Q_flow = -TC_80_81.Q_flow; TC_80_93.Q_flow = TC_80_93.G * TC_80_93.dT; TC_80_93.dT = TC_80_93.port_a.T - TC_80_93.port_b.T; TC_80_93.port_a.Q_flow = TC_80_93.Q_flow; TC_80_93.port_b.Q_flow = -TC_80_93.Q_flow; TC_80_1418.Q_flow = TC_80_1418.G * TC_80_1418.dT; TC_80_1418.dT = TC_80_1418.port_a.T - TC_80_1418.port_b.T; TC_80_1418.port_a.Q_flow = TC_80_1418.Q_flow; TC_80_1418.port_b.Q_flow = -TC_80_1418.Q_flow; TC_81_82.Q_flow = TC_81_82.G * TC_81_82.dT; TC_81_82.dT = TC_81_82.port_a.T - TC_81_82.port_b.T; TC_81_82.port_a.Q_flow = TC_81_82.Q_flow; TC_81_82.port_b.Q_flow = -TC_81_82.Q_flow; TC_81_94.Q_flow = TC_81_94.G * TC_81_94.dT; TC_81_94.dT = TC_81_94.port_a.T - TC_81_94.port_b.T; TC_81_94.port_a.Q_flow = TC_81_94.Q_flow; TC_81_94.port_b.Q_flow = -TC_81_94.Q_flow; TC_81_1419.Q_flow = TC_81_1419.G * TC_81_1419.dT; TC_81_1419.dT = TC_81_1419.port_a.T - TC_81_1419.port_b.T; TC_81_1419.port_a.Q_flow = TC_81_1419.Q_flow; TC_81_1419.port_b.Q_flow = -TC_81_1419.Q_flow; TC_82_83.Q_flow = TC_82_83.G * TC_82_83.dT; TC_82_83.dT = TC_82_83.port_a.T - TC_82_83.port_b.T; TC_82_83.port_a.Q_flow = TC_82_83.Q_flow; TC_82_83.port_b.Q_flow = -TC_82_83.Q_flow; TC_82_95.Q_flow = TC_82_95.G * TC_82_95.dT; TC_82_95.dT = TC_82_95.port_a.T - TC_82_95.port_b.T; TC_82_95.port_a.Q_flow = TC_82_95.Q_flow; TC_82_95.port_b.Q_flow = -TC_82_95.Q_flow; TC_82_757.Q_flow = TC_82_757.G * TC_82_757.dT; TC_82_757.dT = TC_82_757.port_a.T - TC_82_757.port_b.T; TC_82_757.port_a.Q_flow = TC_82_757.Q_flow; TC_82_757.port_b.Q_flow = -TC_82_757.Q_flow; TC_83_84.Q_flow = TC_83_84.G * TC_83_84.dT; TC_83_84.dT = TC_83_84.port_a.T - TC_83_84.port_b.T; TC_83_84.port_a.Q_flow = TC_83_84.Q_flow; TC_83_84.port_b.Q_flow = -TC_83_84.Q_flow; TC_83_96.Q_flow = TC_83_96.G * TC_83_96.dT; TC_83_96.dT = TC_83_96.port_a.T - TC_83_96.port_b.T; TC_83_96.port_a.Q_flow = TC_83_96.Q_flow; TC_83_96.port_b.Q_flow = -TC_83_96.Q_flow; TC_83_758.Q_flow = TC_83_758.G * TC_83_758.dT; TC_83_758.dT = TC_83_758.port_a.T - TC_83_758.port_b.T; TC_83_758.port_a.Q_flow = TC_83_758.Q_flow; TC_83_758.port_b.Q_flow = -TC_83_758.Q_flow; TC_84_85.Q_flow = TC_84_85.G * TC_84_85.dT; TC_84_85.dT = TC_84_85.port_a.T - TC_84_85.port_b.T; TC_84_85.port_a.Q_flow = TC_84_85.Q_flow; TC_84_85.port_b.Q_flow = -TC_84_85.Q_flow; TC_84_97.Q_flow = TC_84_97.G * TC_84_97.dT; TC_84_97.dT = TC_84_97.port_a.T - TC_84_97.port_b.T; TC_84_97.port_a.Q_flow = TC_84_97.Q_flow; TC_84_97.port_b.Q_flow = -TC_84_97.Q_flow; TC_84_759.Q_flow = TC_84_759.G * TC_84_759.dT; TC_84_759.dT = TC_84_759.port_a.T - TC_84_759.port_b.T; TC_84_759.port_a.Q_flow = TC_84_759.Q_flow; TC_84_759.port_b.Q_flow = -TC_84_759.Q_flow; TC_85_86.Q_flow = TC_85_86.G * TC_85_86.dT; TC_85_86.dT = TC_85_86.port_a.T - TC_85_86.port_b.T; TC_85_86.port_a.Q_flow = TC_85_86.Q_flow; TC_85_86.port_b.Q_flow = -TC_85_86.Q_flow; TC_85_98.Q_flow = TC_85_98.G * TC_85_98.dT; TC_85_98.dT = TC_85_98.port_a.T - TC_85_98.port_b.T; TC_85_98.port_a.Q_flow = TC_85_98.Q_flow; TC_85_98.port_b.Q_flow = -TC_85_98.Q_flow; TC_85_760.Q_flow = TC_85_760.G * TC_85_760.dT; TC_85_760.dT = TC_85_760.port_a.T - TC_85_760.port_b.T; TC_85_760.port_a.Q_flow = TC_85_760.Q_flow; TC_85_760.port_b.Q_flow = -TC_85_760.Q_flow; TC_86_87.Q_flow = TC_86_87.G * TC_86_87.dT; TC_86_87.dT = TC_86_87.port_a.T - TC_86_87.port_b.T; TC_86_87.port_a.Q_flow = TC_86_87.Q_flow; TC_86_87.port_b.Q_flow = -TC_86_87.Q_flow; TC_86_99.Q_flow = TC_86_99.G * TC_86_99.dT; TC_86_99.dT = TC_86_99.port_a.T - TC_86_99.port_b.T; TC_86_99.port_a.Q_flow = TC_86_99.Q_flow; TC_86_99.port_b.Q_flow = -TC_86_99.Q_flow; TC_86_761.Q_flow = TC_86_761.G * TC_86_761.dT; TC_86_761.dT = TC_86_761.port_a.T - TC_86_761.port_b.T; TC_86_761.port_a.Q_flow = TC_86_761.Q_flow; TC_86_761.port_b.Q_flow = -TC_86_761.Q_flow; TC_87_88.Q_flow = TC_87_88.G * TC_87_88.dT; TC_87_88.dT = TC_87_88.port_a.T - TC_87_88.port_b.T; TC_87_88.port_a.Q_flow = TC_87_88.Q_flow; TC_87_88.port_b.Q_flow = -TC_87_88.Q_flow; TC_87_100.Q_flow = TC_87_100.G * TC_87_100.dT; TC_87_100.dT = TC_87_100.port_a.T - TC_87_100.port_b.T; TC_87_100.port_a.Q_flow = TC_87_100.Q_flow; TC_87_100.port_b.Q_flow = -TC_87_100.Q_flow; TC_87_762.Q_flow = TC_87_762.G * TC_87_762.dT; TC_87_762.dT = TC_87_762.port_a.T - TC_87_762.port_b.T; TC_87_762.port_a.Q_flow = TC_87_762.Q_flow; TC_87_762.port_b.Q_flow = -TC_87_762.Q_flow; TC_88_89.Q_flow = TC_88_89.G * TC_88_89.dT; TC_88_89.dT = TC_88_89.port_a.T - TC_88_89.port_b.T; TC_88_89.port_a.Q_flow = TC_88_89.Q_flow; TC_88_89.port_b.Q_flow = -TC_88_89.Q_flow; TC_88_101.Q_flow = TC_88_101.G * TC_88_101.dT; TC_88_101.dT = TC_88_101.port_a.T - TC_88_101.port_b.T; TC_88_101.port_a.Q_flow = TC_88_101.Q_flow; TC_88_101.port_b.Q_flow = -TC_88_101.Q_flow; TC_88_763.Q_flow = TC_88_763.G * TC_88_763.dT; TC_88_763.dT = TC_88_763.port_a.T - TC_88_763.port_b.T; TC_88_763.port_a.Q_flow = TC_88_763.Q_flow; TC_88_763.port_b.Q_flow = -TC_88_763.Q_flow; TC_89_90.Q_flow = TC_89_90.G * TC_89_90.dT; TC_89_90.dT = TC_89_90.port_a.T - TC_89_90.port_b.T; TC_89_90.port_a.Q_flow = TC_89_90.Q_flow; TC_89_90.port_b.Q_flow = -TC_89_90.Q_flow; TC_89_102.Q_flow = TC_89_102.G * TC_89_102.dT; TC_89_102.dT = TC_89_102.port_a.T - TC_89_102.port_b.T; TC_89_102.port_a.Q_flow = TC_89_102.Q_flow; TC_89_102.port_b.Q_flow = -TC_89_102.Q_flow; TC_89_764.Q_flow = TC_89_764.G * TC_89_764.dT; TC_89_764.dT = TC_89_764.port_a.T - TC_89_764.port_b.T; TC_89_764.port_a.Q_flow = TC_89_764.Q_flow; TC_89_764.port_b.Q_flow = -TC_89_764.Q_flow; TC_90_91.Q_flow = TC_90_91.G * TC_90_91.dT; TC_90_91.dT = TC_90_91.port_a.T - TC_90_91.port_b.T; TC_90_91.port_a.Q_flow = TC_90_91.Q_flow; TC_90_91.port_b.Q_flow = -TC_90_91.Q_flow; TC_90_103.Q_flow = TC_90_103.G * TC_90_103.dT; TC_90_103.dT = TC_90_103.port_a.T - TC_90_103.port_b.T; TC_90_103.port_a.Q_flow = TC_90_103.Q_flow; TC_90_103.port_b.Q_flow = -TC_90_103.Q_flow; TC_90_1420.Q_flow = TC_90_1420.G * TC_90_1420.dT; TC_90_1420.dT = TC_90_1420.port_a.T - TC_90_1420.port_b.T; TC_90_1420.port_a.Q_flow = TC_90_1420.Q_flow; TC_90_1420.port_b.Q_flow = -TC_90_1420.Q_flow; TC_91_104.Q_flow = TC_91_104.G * TC_91_104.dT; TC_91_104.dT = TC_91_104.port_a.T - TC_91_104.port_b.T; TC_91_104.port_a.Q_flow = TC_91_104.Q_flow; TC_91_104.port_b.Q_flow = -TC_91_104.Q_flow; TC_91_232.Q_flow = TC_91_232.G * TC_91_232.dT; TC_91_232.dT = TC_91_232.port_a.T - TC_91_232.port_b.T; TC_91_232.port_a.Q_flow = TC_91_232.Q_flow; TC_91_232.port_b.Q_flow = -TC_91_232.Q_flow; TC_92_93.Q_flow = TC_92_93.G * TC_92_93.dT; TC_92_93.dT = TC_92_93.port_a.T - TC_92_93.port_b.T; TC_92_93.port_a.Q_flow = TC_92_93.Q_flow; TC_92_93.port_b.Q_flow = -TC_92_93.Q_flow; TC_92_105.Q_flow = TC_92_105.G * TC_92_105.dT; TC_92_105.dT = TC_92_105.port_a.T - TC_92_105.port_b.T; TC_92_105.port_a.Q_flow = TC_92_105.Q_flow; TC_92_105.port_b.Q_flow = -TC_92_105.Q_flow; TC_92_233.Q_flow = TC_92_233.G * TC_92_233.dT; TC_92_233.dT = TC_92_233.port_a.T - TC_92_233.port_b.T; TC_92_233.port_a.Q_flow = TC_92_233.Q_flow; TC_92_233.port_b.Q_flow = -TC_92_233.Q_flow; TC_93_94.Q_flow = TC_93_94.G * TC_93_94.dT; TC_93_94.dT = TC_93_94.port_a.T - TC_93_94.port_b.T; TC_93_94.port_a.Q_flow = TC_93_94.Q_flow; TC_93_94.port_b.Q_flow = -TC_93_94.Q_flow; TC_93_106.Q_flow = TC_93_106.G * TC_93_106.dT; TC_93_106.dT = TC_93_106.port_a.T - TC_93_106.port_b.T; TC_93_106.port_a.Q_flow = TC_93_106.Q_flow; TC_93_106.port_b.Q_flow = -TC_93_106.Q_flow; TC_93_1421.Q_flow = TC_93_1421.G * TC_93_1421.dT; TC_93_1421.dT = TC_93_1421.port_a.T - TC_93_1421.port_b.T; TC_93_1421.port_a.Q_flow = TC_93_1421.Q_flow; TC_93_1421.port_b.Q_flow = -TC_93_1421.Q_flow; TC_94_95.Q_flow = TC_94_95.G * TC_94_95.dT; TC_94_95.dT = TC_94_95.port_a.T - TC_94_95.port_b.T; TC_94_95.port_a.Q_flow = TC_94_95.Q_flow; TC_94_95.port_b.Q_flow = -TC_94_95.Q_flow; TC_94_107.Q_flow = TC_94_107.G * TC_94_107.dT; TC_94_107.dT = TC_94_107.port_a.T - TC_94_107.port_b.T; TC_94_107.port_a.Q_flow = TC_94_107.Q_flow; TC_94_107.port_b.Q_flow = -TC_94_107.Q_flow; TC_94_1422.Q_flow = TC_94_1422.G * TC_94_1422.dT; TC_94_1422.dT = TC_94_1422.port_a.T - TC_94_1422.port_b.T; TC_94_1422.port_a.Q_flow = TC_94_1422.Q_flow; TC_94_1422.port_b.Q_flow = -TC_94_1422.Q_flow; TC_95_96.Q_flow = TC_95_96.G * TC_95_96.dT; TC_95_96.dT = TC_95_96.port_a.T - TC_95_96.port_b.T; TC_95_96.port_a.Q_flow = TC_95_96.Q_flow; TC_95_96.port_b.Q_flow = -TC_95_96.Q_flow; TC_95_108.Q_flow = TC_95_108.G * TC_95_108.dT; TC_95_108.dT = TC_95_108.port_a.T - TC_95_108.port_b.T; TC_95_108.port_a.Q_flow = TC_95_108.Q_flow; TC_95_108.port_b.Q_flow = -TC_95_108.Q_flow; TC_95_765.Q_flow = TC_95_765.G * TC_95_765.dT; TC_95_765.dT = TC_95_765.port_a.T - TC_95_765.port_b.T; TC_95_765.port_a.Q_flow = TC_95_765.Q_flow; TC_95_765.port_b.Q_flow = -TC_95_765.Q_flow; TC_96_97.Q_flow = TC_96_97.G * TC_96_97.dT; TC_96_97.dT = TC_96_97.port_a.T - TC_96_97.port_b.T; TC_96_97.port_a.Q_flow = TC_96_97.Q_flow; TC_96_97.port_b.Q_flow = -TC_96_97.Q_flow; TC_96_109.Q_flow = TC_96_109.G * TC_96_109.dT; TC_96_109.dT = TC_96_109.port_a.T - TC_96_109.port_b.T; TC_96_109.port_a.Q_flow = TC_96_109.Q_flow; TC_96_109.port_b.Q_flow = -TC_96_109.Q_flow; TC_96_766.Q_flow = TC_96_766.G * TC_96_766.dT; TC_96_766.dT = TC_96_766.port_a.T - TC_96_766.port_b.T; TC_96_766.port_a.Q_flow = TC_96_766.Q_flow; TC_96_766.port_b.Q_flow = -TC_96_766.Q_flow; TC_97_98.Q_flow = TC_97_98.G * TC_97_98.dT; TC_97_98.dT = TC_97_98.port_a.T - TC_97_98.port_b.T; TC_97_98.port_a.Q_flow = TC_97_98.Q_flow; TC_97_98.port_b.Q_flow = -TC_97_98.Q_flow; TC_97_110.Q_flow = TC_97_110.G * TC_97_110.dT; TC_97_110.dT = TC_97_110.port_a.T - TC_97_110.port_b.T; TC_97_110.port_a.Q_flow = TC_97_110.Q_flow; TC_97_110.port_b.Q_flow = -TC_97_110.Q_flow; TC_97_767.Q_flow = TC_97_767.G * TC_97_767.dT; TC_97_767.dT = TC_97_767.port_a.T - TC_97_767.port_b.T; TC_97_767.port_a.Q_flow = TC_97_767.Q_flow; TC_97_767.port_b.Q_flow = -TC_97_767.Q_flow; TC_98_99.Q_flow = TC_98_99.G * TC_98_99.dT; TC_98_99.dT = TC_98_99.port_a.T - TC_98_99.port_b.T; TC_98_99.port_a.Q_flow = TC_98_99.Q_flow; TC_98_99.port_b.Q_flow = -TC_98_99.Q_flow; TC_98_111.Q_flow = TC_98_111.G * TC_98_111.dT; TC_98_111.dT = TC_98_111.port_a.T - TC_98_111.port_b.T; TC_98_111.port_a.Q_flow = TC_98_111.Q_flow; TC_98_111.port_b.Q_flow = -TC_98_111.Q_flow; TC_98_768.Q_flow = TC_98_768.G * TC_98_768.dT; TC_98_768.dT = TC_98_768.port_a.T - TC_98_768.port_b.T; TC_98_768.port_a.Q_flow = TC_98_768.Q_flow; TC_98_768.port_b.Q_flow = -TC_98_768.Q_flow; TC_99_100.Q_flow = TC_99_100.G * TC_99_100.dT; TC_99_100.dT = TC_99_100.port_a.T - TC_99_100.port_b.T; TC_99_100.port_a.Q_flow = TC_99_100.Q_flow; TC_99_100.port_b.Q_flow = -TC_99_100.Q_flow; TC_99_112.Q_flow = TC_99_112.G * TC_99_112.dT; TC_99_112.dT = TC_99_112.port_a.T - TC_99_112.port_b.T; TC_99_112.port_a.Q_flow = TC_99_112.Q_flow; TC_99_112.port_b.Q_flow = -TC_99_112.Q_flow; TC_99_769.Q_flow = TC_99_769.G * TC_99_769.dT; TC_99_769.dT = TC_99_769.port_a.T - TC_99_769.port_b.T; TC_99_769.port_a.Q_flow = TC_99_769.Q_flow; TC_99_769.port_b.Q_flow = -TC_99_769.Q_flow; TC_100_101.Q_flow = TC_100_101.G * TC_100_101.dT; TC_100_101.dT = TC_100_101.port_a.T - TC_100_101.port_b.T; TC_100_101.port_a.Q_flow = TC_100_101.Q_flow; TC_100_101.port_b.Q_flow = -TC_100_101.Q_flow; TC_100_113.Q_flow = TC_100_113.G * TC_100_113.dT; TC_100_113.dT = TC_100_113.port_a.T - TC_100_113.port_b.T; TC_100_113.port_a.Q_flow = TC_100_113.Q_flow; TC_100_113.port_b.Q_flow = -TC_100_113.Q_flow; TC_100_770.Q_flow = TC_100_770.G * TC_100_770.dT; TC_100_770.dT = TC_100_770.port_a.T - TC_100_770.port_b.T; TC_100_770.port_a.Q_flow = TC_100_770.Q_flow; TC_100_770.port_b.Q_flow = -TC_100_770.Q_flow; TC_101_102.Q_flow = TC_101_102.G * TC_101_102.dT; TC_101_102.dT = TC_101_102.port_a.T - TC_101_102.port_b.T; TC_101_102.port_a.Q_flow = TC_101_102.Q_flow; TC_101_102.port_b.Q_flow = -TC_101_102.Q_flow; TC_101_114.Q_flow = TC_101_114.G * TC_101_114.dT; TC_101_114.dT = TC_101_114.port_a.T - TC_101_114.port_b.T; TC_101_114.port_a.Q_flow = TC_101_114.Q_flow; TC_101_114.port_b.Q_flow = -TC_101_114.Q_flow; TC_101_771.Q_flow = TC_101_771.G * TC_101_771.dT; TC_101_771.dT = TC_101_771.port_a.T - TC_101_771.port_b.T; TC_101_771.port_a.Q_flow = TC_101_771.Q_flow; TC_101_771.port_b.Q_flow = -TC_101_771.Q_flow; TC_102_103.Q_flow = TC_102_103.G * TC_102_103.dT; TC_102_103.dT = TC_102_103.port_a.T - TC_102_103.port_b.T; TC_102_103.port_a.Q_flow = TC_102_103.Q_flow; TC_102_103.port_b.Q_flow = -TC_102_103.Q_flow; TC_102_115.Q_flow = TC_102_115.G * TC_102_115.dT; TC_102_115.dT = TC_102_115.port_a.T - TC_102_115.port_b.T; TC_102_115.port_a.Q_flow = TC_102_115.Q_flow; TC_102_115.port_b.Q_flow = -TC_102_115.Q_flow; TC_102_772.Q_flow = TC_102_772.G * TC_102_772.dT; TC_102_772.dT = TC_102_772.port_a.T - TC_102_772.port_b.T; TC_102_772.port_a.Q_flow = TC_102_772.Q_flow; TC_102_772.port_b.Q_flow = -TC_102_772.Q_flow; TC_103_104.Q_flow = TC_103_104.G * TC_103_104.dT; TC_103_104.dT = TC_103_104.port_a.T - TC_103_104.port_b.T; TC_103_104.port_a.Q_flow = TC_103_104.Q_flow; TC_103_104.port_b.Q_flow = -TC_103_104.Q_flow; TC_103_116.Q_flow = TC_103_116.G * TC_103_116.dT; TC_103_116.dT = TC_103_116.port_a.T - TC_103_116.port_b.T; TC_103_116.port_a.Q_flow = TC_103_116.Q_flow; TC_103_116.port_b.Q_flow = -TC_103_116.Q_flow; TC_103_1423.Q_flow = TC_103_1423.G * TC_103_1423.dT; TC_103_1423.dT = TC_103_1423.port_a.T - TC_103_1423.port_b.T; TC_103_1423.port_a.Q_flow = TC_103_1423.Q_flow; TC_103_1423.port_b.Q_flow = -TC_103_1423.Q_flow; TC_104_117.Q_flow = TC_104_117.G * TC_104_117.dT; TC_104_117.dT = TC_104_117.port_a.T - TC_104_117.port_b.T; TC_104_117.port_a.Q_flow = TC_104_117.Q_flow; TC_104_117.port_b.Q_flow = -TC_104_117.Q_flow; TC_104_234.Q_flow = TC_104_234.G * TC_104_234.dT; TC_104_234.dT = TC_104_234.port_a.T - TC_104_234.port_b.T; TC_104_234.port_a.Q_flow = TC_104_234.Q_flow; TC_104_234.port_b.Q_flow = -TC_104_234.Q_flow; TC_105_106.Q_flow = TC_105_106.G * TC_105_106.dT; TC_105_106.dT = TC_105_106.port_a.T - TC_105_106.port_b.T; TC_105_106.port_a.Q_flow = TC_105_106.Q_flow; TC_105_106.port_b.Q_flow = -TC_105_106.Q_flow; TC_105_118.Q_flow = TC_105_118.G * TC_105_118.dT; TC_105_118.dT = TC_105_118.port_a.T - TC_105_118.port_b.T; TC_105_118.port_a.Q_flow = TC_105_118.Q_flow; TC_105_118.port_b.Q_flow = -TC_105_118.Q_flow; TC_105_235.Q_flow = TC_105_235.G * TC_105_235.dT; TC_105_235.dT = TC_105_235.port_a.T - TC_105_235.port_b.T; TC_105_235.port_a.Q_flow = TC_105_235.Q_flow; TC_105_235.port_b.Q_flow = -TC_105_235.Q_flow; TC_106_107.Q_flow = TC_106_107.G * TC_106_107.dT; TC_106_107.dT = TC_106_107.port_a.T - TC_106_107.port_b.T; TC_106_107.port_a.Q_flow = TC_106_107.Q_flow; TC_106_107.port_b.Q_flow = -TC_106_107.Q_flow; TC_106_119.Q_flow = TC_106_119.G * TC_106_119.dT; TC_106_119.dT = TC_106_119.port_a.T - TC_106_119.port_b.T; TC_106_119.port_a.Q_flow = TC_106_119.Q_flow; TC_106_119.port_b.Q_flow = -TC_106_119.Q_flow; TC_106_1424.Q_flow = TC_106_1424.G * TC_106_1424.dT; TC_106_1424.dT = TC_106_1424.port_a.T - TC_106_1424.port_b.T; TC_106_1424.port_a.Q_flow = TC_106_1424.Q_flow; TC_106_1424.port_b.Q_flow = -TC_106_1424.Q_flow; TC_107_108.Q_flow = TC_107_108.G * TC_107_108.dT; TC_107_108.dT = TC_107_108.port_a.T - TC_107_108.port_b.T; TC_107_108.port_a.Q_flow = TC_107_108.Q_flow; TC_107_108.port_b.Q_flow = -TC_107_108.Q_flow; TC_107_120.Q_flow = TC_107_120.G * TC_107_120.dT; TC_107_120.dT = TC_107_120.port_a.T - TC_107_120.port_b.T; TC_107_120.port_a.Q_flow = TC_107_120.Q_flow; TC_107_120.port_b.Q_flow = -TC_107_120.Q_flow; TC_107_1425.Q_flow = TC_107_1425.G * TC_107_1425.dT; TC_107_1425.dT = TC_107_1425.port_a.T - TC_107_1425.port_b.T; TC_107_1425.port_a.Q_flow = TC_107_1425.Q_flow; TC_107_1425.port_b.Q_flow = -TC_107_1425.Q_flow; TC_108_109.Q_flow = TC_108_109.G * TC_108_109.dT; TC_108_109.dT = TC_108_109.port_a.T - TC_108_109.port_b.T; TC_108_109.port_a.Q_flow = TC_108_109.Q_flow; TC_108_109.port_b.Q_flow = -TC_108_109.Q_flow; TC_108_121.Q_flow = TC_108_121.G * TC_108_121.dT; TC_108_121.dT = TC_108_121.port_a.T - TC_108_121.port_b.T; TC_108_121.port_a.Q_flow = TC_108_121.Q_flow; TC_108_121.port_b.Q_flow = -TC_108_121.Q_flow; TC_108_773.Q_flow = TC_108_773.G * TC_108_773.dT; TC_108_773.dT = TC_108_773.port_a.T - TC_108_773.port_b.T; TC_108_773.port_a.Q_flow = TC_108_773.Q_flow; TC_108_773.port_b.Q_flow = -TC_108_773.Q_flow; TC_109_110.Q_flow = TC_109_110.G * TC_109_110.dT; TC_109_110.dT = TC_109_110.port_a.T - TC_109_110.port_b.T; TC_109_110.port_a.Q_flow = TC_109_110.Q_flow; TC_109_110.port_b.Q_flow = -TC_109_110.Q_flow; TC_109_122.Q_flow = TC_109_122.G * TC_109_122.dT; TC_109_122.dT = TC_109_122.port_a.T - TC_109_122.port_b.T; TC_109_122.port_a.Q_flow = TC_109_122.Q_flow; TC_109_122.port_b.Q_flow = -TC_109_122.Q_flow; TC_109_774.Q_flow = TC_109_774.G * TC_109_774.dT; TC_109_774.dT = TC_109_774.port_a.T - TC_109_774.port_b.T; TC_109_774.port_a.Q_flow = TC_109_774.Q_flow; TC_109_774.port_b.Q_flow = -TC_109_774.Q_flow; TC_110_111.Q_flow = TC_110_111.G * TC_110_111.dT; TC_110_111.dT = TC_110_111.port_a.T - TC_110_111.port_b.T; TC_110_111.port_a.Q_flow = TC_110_111.Q_flow; TC_110_111.port_b.Q_flow = -TC_110_111.Q_flow; TC_110_123.Q_flow = TC_110_123.G * TC_110_123.dT; TC_110_123.dT = TC_110_123.port_a.T - TC_110_123.port_b.T; TC_110_123.port_a.Q_flow = TC_110_123.Q_flow; TC_110_123.port_b.Q_flow = -TC_110_123.Q_flow; TC_110_775.Q_flow = TC_110_775.G * TC_110_775.dT; TC_110_775.dT = TC_110_775.port_a.T - TC_110_775.port_b.T; TC_110_775.port_a.Q_flow = TC_110_775.Q_flow; TC_110_775.port_b.Q_flow = -TC_110_775.Q_flow; TC_111_112.Q_flow = TC_111_112.G * TC_111_112.dT; TC_111_112.dT = TC_111_112.port_a.T - TC_111_112.port_b.T; TC_111_112.port_a.Q_flow = TC_111_112.Q_flow; TC_111_112.port_b.Q_flow = -TC_111_112.Q_flow; TC_111_124.Q_flow = TC_111_124.G * TC_111_124.dT; TC_111_124.dT = TC_111_124.port_a.T - TC_111_124.port_b.T; TC_111_124.port_a.Q_flow = TC_111_124.Q_flow; TC_111_124.port_b.Q_flow = -TC_111_124.Q_flow; TC_111_776.Q_flow = TC_111_776.G * TC_111_776.dT; TC_111_776.dT = TC_111_776.port_a.T - TC_111_776.port_b.T; TC_111_776.port_a.Q_flow = TC_111_776.Q_flow; TC_111_776.port_b.Q_flow = -TC_111_776.Q_flow; TC_112_113.Q_flow = TC_112_113.G * TC_112_113.dT; TC_112_113.dT = TC_112_113.port_a.T - TC_112_113.port_b.T; TC_112_113.port_a.Q_flow = TC_112_113.Q_flow; TC_112_113.port_b.Q_flow = -TC_112_113.Q_flow; TC_112_125.Q_flow = TC_112_125.G * TC_112_125.dT; TC_112_125.dT = TC_112_125.port_a.T - TC_112_125.port_b.T; TC_112_125.port_a.Q_flow = TC_112_125.Q_flow; TC_112_125.port_b.Q_flow = -TC_112_125.Q_flow; TC_112_777.Q_flow = TC_112_777.G * TC_112_777.dT; TC_112_777.dT = TC_112_777.port_a.T - TC_112_777.port_b.T; TC_112_777.port_a.Q_flow = TC_112_777.Q_flow; TC_112_777.port_b.Q_flow = -TC_112_777.Q_flow; TC_113_114.Q_flow = TC_113_114.G * TC_113_114.dT; TC_113_114.dT = TC_113_114.port_a.T - TC_113_114.port_b.T; TC_113_114.port_a.Q_flow = TC_113_114.Q_flow; TC_113_114.port_b.Q_flow = -TC_113_114.Q_flow; TC_113_126.Q_flow = TC_113_126.G * TC_113_126.dT; TC_113_126.dT = TC_113_126.port_a.T - TC_113_126.port_b.T; TC_113_126.port_a.Q_flow = TC_113_126.Q_flow; TC_113_126.port_b.Q_flow = -TC_113_126.Q_flow; TC_113_778.Q_flow = TC_113_778.G * TC_113_778.dT; TC_113_778.dT = TC_113_778.port_a.T - TC_113_778.port_b.T; TC_113_778.port_a.Q_flow = TC_113_778.Q_flow; TC_113_778.port_b.Q_flow = -TC_113_778.Q_flow; TC_114_115.Q_flow = TC_114_115.G * TC_114_115.dT; TC_114_115.dT = TC_114_115.port_a.T - TC_114_115.port_b.T; TC_114_115.port_a.Q_flow = TC_114_115.Q_flow; TC_114_115.port_b.Q_flow = -TC_114_115.Q_flow; TC_114_127.Q_flow = TC_114_127.G * TC_114_127.dT; TC_114_127.dT = TC_114_127.port_a.T - TC_114_127.port_b.T; TC_114_127.port_a.Q_flow = TC_114_127.Q_flow; TC_114_127.port_b.Q_flow = -TC_114_127.Q_flow; TC_114_779.Q_flow = TC_114_779.G * TC_114_779.dT; TC_114_779.dT = TC_114_779.port_a.T - TC_114_779.port_b.T; TC_114_779.port_a.Q_flow = TC_114_779.Q_flow; TC_114_779.port_b.Q_flow = -TC_114_779.Q_flow; TC_115_116.Q_flow = TC_115_116.G * TC_115_116.dT; TC_115_116.dT = TC_115_116.port_a.T - TC_115_116.port_b.T; TC_115_116.port_a.Q_flow = TC_115_116.Q_flow; TC_115_116.port_b.Q_flow = -TC_115_116.Q_flow; TC_115_128.Q_flow = TC_115_128.G * TC_115_128.dT; TC_115_128.dT = TC_115_128.port_a.T - TC_115_128.port_b.T; TC_115_128.port_a.Q_flow = TC_115_128.Q_flow; TC_115_128.port_b.Q_flow = -TC_115_128.Q_flow; TC_115_780.Q_flow = TC_115_780.G * TC_115_780.dT; TC_115_780.dT = TC_115_780.port_a.T - TC_115_780.port_b.T; TC_115_780.port_a.Q_flow = TC_115_780.Q_flow; TC_115_780.port_b.Q_flow = -TC_115_780.Q_flow; TC_116_117.Q_flow = TC_116_117.G * TC_116_117.dT; TC_116_117.dT = TC_116_117.port_a.T - TC_116_117.port_b.T; TC_116_117.port_a.Q_flow = TC_116_117.Q_flow; TC_116_117.port_b.Q_flow = -TC_116_117.Q_flow; TC_116_129.Q_flow = TC_116_129.G * TC_116_129.dT; TC_116_129.dT = TC_116_129.port_a.T - TC_116_129.port_b.T; TC_116_129.port_a.Q_flow = TC_116_129.Q_flow; TC_116_129.port_b.Q_flow = -TC_116_129.Q_flow; TC_116_1426.Q_flow = TC_116_1426.G * TC_116_1426.dT; TC_116_1426.dT = TC_116_1426.port_a.T - TC_116_1426.port_b.T; TC_116_1426.port_a.Q_flow = TC_116_1426.Q_flow; TC_116_1426.port_b.Q_flow = -TC_116_1426.Q_flow; TC_117_130.Q_flow = TC_117_130.G * TC_117_130.dT; TC_117_130.dT = TC_117_130.port_a.T - TC_117_130.port_b.T; TC_117_130.port_a.Q_flow = TC_117_130.Q_flow; TC_117_130.port_b.Q_flow = -TC_117_130.Q_flow; TC_117_236.Q_flow = TC_117_236.G * TC_117_236.dT; TC_117_236.dT = TC_117_236.port_a.T - TC_117_236.port_b.T; TC_117_236.port_a.Q_flow = TC_117_236.Q_flow; TC_117_236.port_b.Q_flow = -TC_117_236.Q_flow; TC_118_119.Q_flow = TC_118_119.G * TC_118_119.dT; TC_118_119.dT = TC_118_119.port_a.T - TC_118_119.port_b.T; TC_118_119.port_a.Q_flow = TC_118_119.Q_flow; TC_118_119.port_b.Q_flow = -TC_118_119.Q_flow; TC_118_131.Q_flow = TC_118_131.G * TC_118_131.dT; TC_118_131.dT = TC_118_131.port_a.T - TC_118_131.port_b.T; TC_118_131.port_a.Q_flow = TC_118_131.Q_flow; TC_118_131.port_b.Q_flow = -TC_118_131.Q_flow; TC_118_237.Q_flow = TC_118_237.G * TC_118_237.dT; TC_118_237.dT = TC_118_237.port_a.T - TC_118_237.port_b.T; TC_118_237.port_a.Q_flow = TC_118_237.Q_flow; TC_118_237.port_b.Q_flow = -TC_118_237.Q_flow; TC_119_120.Q_flow = TC_119_120.G * TC_119_120.dT; TC_119_120.dT = TC_119_120.port_a.T - TC_119_120.port_b.T; TC_119_120.port_a.Q_flow = TC_119_120.Q_flow; TC_119_120.port_b.Q_flow = -TC_119_120.Q_flow; TC_119_132.Q_flow = TC_119_132.G * TC_119_132.dT; TC_119_132.dT = TC_119_132.port_a.T - TC_119_132.port_b.T; TC_119_132.port_a.Q_flow = TC_119_132.Q_flow; TC_119_132.port_b.Q_flow = -TC_119_132.Q_flow; TC_119_1427.Q_flow = TC_119_1427.G * TC_119_1427.dT; TC_119_1427.dT = TC_119_1427.port_a.T - TC_119_1427.port_b.T; TC_119_1427.port_a.Q_flow = TC_119_1427.Q_flow; TC_119_1427.port_b.Q_flow = -TC_119_1427.Q_flow; TC_120_121.Q_flow = TC_120_121.G * TC_120_121.dT; TC_120_121.dT = TC_120_121.port_a.T - TC_120_121.port_b.T; TC_120_121.port_a.Q_flow = TC_120_121.Q_flow; TC_120_121.port_b.Q_flow = -TC_120_121.Q_flow; TC_120_133.Q_flow = TC_120_133.G * TC_120_133.dT; TC_120_133.dT = TC_120_133.port_a.T - TC_120_133.port_b.T; TC_120_133.port_a.Q_flow = TC_120_133.Q_flow; TC_120_133.port_b.Q_flow = -TC_120_133.Q_flow; TC_120_1428.Q_flow = TC_120_1428.G * TC_120_1428.dT; TC_120_1428.dT = TC_120_1428.port_a.T - TC_120_1428.port_b.T; TC_120_1428.port_a.Q_flow = TC_120_1428.Q_flow; TC_120_1428.port_b.Q_flow = -TC_120_1428.Q_flow; TC_121_122.Q_flow = TC_121_122.G * TC_121_122.dT; TC_121_122.dT = TC_121_122.port_a.T - TC_121_122.port_b.T; TC_121_122.port_a.Q_flow = TC_121_122.Q_flow; TC_121_122.port_b.Q_flow = -TC_121_122.Q_flow; TC_121_134.Q_flow = TC_121_134.G * TC_121_134.dT; TC_121_134.dT = TC_121_134.port_a.T - TC_121_134.port_b.T; TC_121_134.port_a.Q_flow = TC_121_134.Q_flow; TC_121_134.port_b.Q_flow = -TC_121_134.Q_flow; TC_121_781.Q_flow = TC_121_781.G * TC_121_781.dT; TC_121_781.dT = TC_121_781.port_a.T - TC_121_781.port_b.T; TC_121_781.port_a.Q_flow = TC_121_781.Q_flow; TC_121_781.port_b.Q_flow = -TC_121_781.Q_flow; TC_122_123.Q_flow = TC_122_123.G * TC_122_123.dT; TC_122_123.dT = TC_122_123.port_a.T - TC_122_123.port_b.T; TC_122_123.port_a.Q_flow = TC_122_123.Q_flow; TC_122_123.port_b.Q_flow = -TC_122_123.Q_flow; TC_122_135.Q_flow = TC_122_135.G * TC_122_135.dT; TC_122_135.dT = TC_122_135.port_a.T - TC_122_135.port_b.T; TC_122_135.port_a.Q_flow = TC_122_135.Q_flow; TC_122_135.port_b.Q_flow = -TC_122_135.Q_flow; TC_122_782.Q_flow = TC_122_782.G * TC_122_782.dT; TC_122_782.dT = TC_122_782.port_a.T - TC_122_782.port_b.T; TC_122_782.port_a.Q_flow = TC_122_782.Q_flow; TC_122_782.port_b.Q_flow = -TC_122_782.Q_flow; TC_123_124.Q_flow = TC_123_124.G * TC_123_124.dT; TC_123_124.dT = TC_123_124.port_a.T - TC_123_124.port_b.T; TC_123_124.port_a.Q_flow = TC_123_124.Q_flow; TC_123_124.port_b.Q_flow = -TC_123_124.Q_flow; TC_123_136.Q_flow = TC_123_136.G * TC_123_136.dT; TC_123_136.dT = TC_123_136.port_a.T - TC_123_136.port_b.T; TC_123_136.port_a.Q_flow = TC_123_136.Q_flow; TC_123_136.port_b.Q_flow = -TC_123_136.Q_flow; TC_123_783.Q_flow = TC_123_783.G * TC_123_783.dT; TC_123_783.dT = TC_123_783.port_a.T - TC_123_783.port_b.T; TC_123_783.port_a.Q_flow = TC_123_783.Q_flow; TC_123_783.port_b.Q_flow = -TC_123_783.Q_flow; TC_124_125.Q_flow = TC_124_125.G * TC_124_125.dT; TC_124_125.dT = TC_124_125.port_a.T - TC_124_125.port_b.T; TC_124_125.port_a.Q_flow = TC_124_125.Q_flow; TC_124_125.port_b.Q_flow = -TC_124_125.Q_flow; TC_124_137.Q_flow = TC_124_137.G * TC_124_137.dT; TC_124_137.dT = TC_124_137.port_a.T - TC_124_137.port_b.T; TC_124_137.port_a.Q_flow = TC_124_137.Q_flow; TC_124_137.port_b.Q_flow = -TC_124_137.Q_flow; TC_124_784.Q_flow = TC_124_784.G * TC_124_784.dT; TC_124_784.dT = TC_124_784.port_a.T - TC_124_784.port_b.T; TC_124_784.port_a.Q_flow = TC_124_784.Q_flow; TC_124_784.port_b.Q_flow = -TC_124_784.Q_flow; TC_125_126.Q_flow = TC_125_126.G * TC_125_126.dT; TC_125_126.dT = TC_125_126.port_a.T - TC_125_126.port_b.T; TC_125_126.port_a.Q_flow = TC_125_126.Q_flow; TC_125_126.port_b.Q_flow = -TC_125_126.Q_flow; TC_125_138.Q_flow = TC_125_138.G * TC_125_138.dT; TC_125_138.dT = TC_125_138.port_a.T - TC_125_138.port_b.T; TC_125_138.port_a.Q_flow = TC_125_138.Q_flow; TC_125_138.port_b.Q_flow = -TC_125_138.Q_flow; TC_125_785.Q_flow = TC_125_785.G * TC_125_785.dT; TC_125_785.dT = TC_125_785.port_a.T - TC_125_785.port_b.T; TC_125_785.port_a.Q_flow = TC_125_785.Q_flow; TC_125_785.port_b.Q_flow = -TC_125_785.Q_flow; TC_126_127.Q_flow = TC_126_127.G * TC_126_127.dT; TC_126_127.dT = TC_126_127.port_a.T - TC_126_127.port_b.T; TC_126_127.port_a.Q_flow = TC_126_127.Q_flow; TC_126_127.port_b.Q_flow = -TC_126_127.Q_flow; TC_126_139.Q_flow = TC_126_139.G * TC_126_139.dT; TC_126_139.dT = TC_126_139.port_a.T - TC_126_139.port_b.T; TC_126_139.port_a.Q_flow = TC_126_139.Q_flow; TC_126_139.port_b.Q_flow = -TC_126_139.Q_flow; TC_126_786.Q_flow = TC_126_786.G * TC_126_786.dT; TC_126_786.dT = TC_126_786.port_a.T - TC_126_786.port_b.T; TC_126_786.port_a.Q_flow = TC_126_786.Q_flow; TC_126_786.port_b.Q_flow = -TC_126_786.Q_flow; TC_127_128.Q_flow = TC_127_128.G * TC_127_128.dT; TC_127_128.dT = TC_127_128.port_a.T - TC_127_128.port_b.T; TC_127_128.port_a.Q_flow = TC_127_128.Q_flow; TC_127_128.port_b.Q_flow = -TC_127_128.Q_flow; TC_127_140.Q_flow = TC_127_140.G * TC_127_140.dT; TC_127_140.dT = TC_127_140.port_a.T - TC_127_140.port_b.T; TC_127_140.port_a.Q_flow = TC_127_140.Q_flow; TC_127_140.port_b.Q_flow = -TC_127_140.Q_flow; TC_127_787.Q_flow = TC_127_787.G * TC_127_787.dT; TC_127_787.dT = TC_127_787.port_a.T - TC_127_787.port_b.T; TC_127_787.port_a.Q_flow = TC_127_787.Q_flow; TC_127_787.port_b.Q_flow = -TC_127_787.Q_flow; TC_128_129.Q_flow = TC_128_129.G * TC_128_129.dT; TC_128_129.dT = TC_128_129.port_a.T - TC_128_129.port_b.T; TC_128_129.port_a.Q_flow = TC_128_129.Q_flow; TC_128_129.port_b.Q_flow = -TC_128_129.Q_flow; TC_128_141.Q_flow = TC_128_141.G * TC_128_141.dT; TC_128_141.dT = TC_128_141.port_a.T - TC_128_141.port_b.T; TC_128_141.port_a.Q_flow = TC_128_141.Q_flow; TC_128_141.port_b.Q_flow = -TC_128_141.Q_flow; TC_128_788.Q_flow = TC_128_788.G * TC_128_788.dT; TC_128_788.dT = TC_128_788.port_a.T - TC_128_788.port_b.T; TC_128_788.port_a.Q_flow = TC_128_788.Q_flow; TC_128_788.port_b.Q_flow = -TC_128_788.Q_flow; TC_129_130.Q_flow = TC_129_130.G * TC_129_130.dT; TC_129_130.dT = TC_129_130.port_a.T - TC_129_130.port_b.T; TC_129_130.port_a.Q_flow = TC_129_130.Q_flow; TC_129_130.port_b.Q_flow = -TC_129_130.Q_flow; TC_129_142.Q_flow = TC_129_142.G * TC_129_142.dT; TC_129_142.dT = TC_129_142.port_a.T - TC_129_142.port_b.T; TC_129_142.port_a.Q_flow = TC_129_142.Q_flow; TC_129_142.port_b.Q_flow = -TC_129_142.Q_flow; TC_129_1429.Q_flow = TC_129_1429.G * TC_129_1429.dT; TC_129_1429.dT = TC_129_1429.port_a.T - TC_129_1429.port_b.T; TC_129_1429.port_a.Q_flow = TC_129_1429.Q_flow; TC_129_1429.port_b.Q_flow = -TC_129_1429.Q_flow; TC_130_143.Q_flow = TC_130_143.G * TC_130_143.dT; TC_130_143.dT = TC_130_143.port_a.T - TC_130_143.port_b.T; TC_130_143.port_a.Q_flow = TC_130_143.Q_flow; TC_130_143.port_b.Q_flow = -TC_130_143.Q_flow; TC_130_238.Q_flow = TC_130_238.G * TC_130_238.dT; TC_130_238.dT = TC_130_238.port_a.T - TC_130_238.port_b.T; TC_130_238.port_a.Q_flow = TC_130_238.Q_flow; TC_130_238.port_b.Q_flow = -TC_130_238.Q_flow; TC_131_132.Q_flow = TC_131_132.G * TC_131_132.dT; TC_131_132.dT = TC_131_132.port_a.T - TC_131_132.port_b.T; TC_131_132.port_a.Q_flow = TC_131_132.Q_flow; TC_131_132.port_b.Q_flow = -TC_131_132.Q_flow; TC_131_144.Q_flow = TC_131_144.G * TC_131_144.dT; TC_131_144.dT = TC_131_144.port_a.T - TC_131_144.port_b.T; TC_131_144.port_a.Q_flow = TC_131_144.Q_flow; TC_131_144.port_b.Q_flow = -TC_131_144.Q_flow; TC_131_239.Q_flow = TC_131_239.G * TC_131_239.dT; TC_131_239.dT = TC_131_239.port_a.T - TC_131_239.port_b.T; TC_131_239.port_a.Q_flow = TC_131_239.Q_flow; TC_131_239.port_b.Q_flow = -TC_131_239.Q_flow; TC_132_133.Q_flow = TC_132_133.G * TC_132_133.dT; TC_132_133.dT = TC_132_133.port_a.T - TC_132_133.port_b.T; TC_132_133.port_a.Q_flow = TC_132_133.Q_flow; TC_132_133.port_b.Q_flow = -TC_132_133.Q_flow; TC_132_145.Q_flow = TC_132_145.G * TC_132_145.dT; TC_132_145.dT = TC_132_145.port_a.T - TC_132_145.port_b.T; TC_132_145.port_a.Q_flow = TC_132_145.Q_flow; TC_132_145.port_b.Q_flow = -TC_132_145.Q_flow; TC_132_1430.Q_flow = TC_132_1430.G * TC_132_1430.dT; TC_132_1430.dT = TC_132_1430.port_a.T - TC_132_1430.port_b.T; TC_132_1430.port_a.Q_flow = TC_132_1430.Q_flow; TC_132_1430.port_b.Q_flow = -TC_132_1430.Q_flow; TC_133_134.Q_flow = TC_133_134.G * TC_133_134.dT; TC_133_134.dT = TC_133_134.port_a.T - TC_133_134.port_b.T; TC_133_134.port_a.Q_flow = TC_133_134.Q_flow; TC_133_134.port_b.Q_flow = -TC_133_134.Q_flow; TC_133_146.Q_flow = TC_133_146.G * TC_133_146.dT; TC_133_146.dT = TC_133_146.port_a.T - TC_133_146.port_b.T; TC_133_146.port_a.Q_flow = TC_133_146.Q_flow; TC_133_146.port_b.Q_flow = -TC_133_146.Q_flow; TC_133_1431.Q_flow = TC_133_1431.G * TC_133_1431.dT; TC_133_1431.dT = TC_133_1431.port_a.T - TC_133_1431.port_b.T; TC_133_1431.port_a.Q_flow = TC_133_1431.Q_flow; TC_133_1431.port_b.Q_flow = -TC_133_1431.Q_flow; TC_134_135.Q_flow = TC_134_135.G * TC_134_135.dT; TC_134_135.dT = TC_134_135.port_a.T - TC_134_135.port_b.T; TC_134_135.port_a.Q_flow = TC_134_135.Q_flow; TC_134_135.port_b.Q_flow = -TC_134_135.Q_flow; TC_134_147.Q_flow = TC_134_147.G * TC_134_147.dT; TC_134_147.dT = TC_134_147.port_a.T - TC_134_147.port_b.T; TC_134_147.port_a.Q_flow = TC_134_147.Q_flow; TC_134_147.port_b.Q_flow = -TC_134_147.Q_flow; TC_134_789.Q_flow = TC_134_789.G * TC_134_789.dT; TC_134_789.dT = TC_134_789.port_a.T - TC_134_789.port_b.T; TC_134_789.port_a.Q_flow = TC_134_789.Q_flow; TC_134_789.port_b.Q_flow = -TC_134_789.Q_flow; TC_135_136.Q_flow = TC_135_136.G * TC_135_136.dT; TC_135_136.dT = TC_135_136.port_a.T - TC_135_136.port_b.T; TC_135_136.port_a.Q_flow = TC_135_136.Q_flow; TC_135_136.port_b.Q_flow = -TC_135_136.Q_flow; TC_135_148.Q_flow = TC_135_148.G * TC_135_148.dT; TC_135_148.dT = TC_135_148.port_a.T - TC_135_148.port_b.T; TC_135_148.port_a.Q_flow = TC_135_148.Q_flow; TC_135_148.port_b.Q_flow = -TC_135_148.Q_flow; TC_135_790.Q_flow = TC_135_790.G * TC_135_790.dT; TC_135_790.dT = TC_135_790.port_a.T - TC_135_790.port_b.T; TC_135_790.port_a.Q_flow = TC_135_790.Q_flow; TC_135_790.port_b.Q_flow = -TC_135_790.Q_flow; TC_136_137.Q_flow = TC_136_137.G * TC_136_137.dT; TC_136_137.dT = TC_136_137.port_a.T - TC_136_137.port_b.T; TC_136_137.port_a.Q_flow = TC_136_137.Q_flow; TC_136_137.port_b.Q_flow = -TC_136_137.Q_flow; TC_136_149.Q_flow = TC_136_149.G * TC_136_149.dT; TC_136_149.dT = TC_136_149.port_a.T - TC_136_149.port_b.T; TC_136_149.port_a.Q_flow = TC_136_149.Q_flow; TC_136_149.port_b.Q_flow = -TC_136_149.Q_flow; TC_136_791.Q_flow = TC_136_791.G * TC_136_791.dT; TC_136_791.dT = TC_136_791.port_a.T - TC_136_791.port_b.T; TC_136_791.port_a.Q_flow = TC_136_791.Q_flow; TC_136_791.port_b.Q_flow = -TC_136_791.Q_flow; TC_137_138.Q_flow = TC_137_138.G * TC_137_138.dT; TC_137_138.dT = TC_137_138.port_a.T - TC_137_138.port_b.T; TC_137_138.port_a.Q_flow = TC_137_138.Q_flow; TC_137_138.port_b.Q_flow = -TC_137_138.Q_flow; TC_137_150.Q_flow = TC_137_150.G * TC_137_150.dT; TC_137_150.dT = TC_137_150.port_a.T - TC_137_150.port_b.T; TC_137_150.port_a.Q_flow = TC_137_150.Q_flow; TC_137_150.port_b.Q_flow = -TC_137_150.Q_flow; TC_137_792.Q_flow = TC_137_792.G * TC_137_792.dT; TC_137_792.dT = TC_137_792.port_a.T - TC_137_792.port_b.T; TC_137_792.port_a.Q_flow = TC_137_792.Q_flow; TC_137_792.port_b.Q_flow = -TC_137_792.Q_flow; TC_138_139.Q_flow = TC_138_139.G * TC_138_139.dT; TC_138_139.dT = TC_138_139.port_a.T - TC_138_139.port_b.T; TC_138_139.port_a.Q_flow = TC_138_139.Q_flow; TC_138_139.port_b.Q_flow = -TC_138_139.Q_flow; TC_138_151.Q_flow = TC_138_151.G * TC_138_151.dT; TC_138_151.dT = TC_138_151.port_a.T - TC_138_151.port_b.T; TC_138_151.port_a.Q_flow = TC_138_151.Q_flow; TC_138_151.port_b.Q_flow = -TC_138_151.Q_flow; TC_138_793.Q_flow = TC_138_793.G * TC_138_793.dT; TC_138_793.dT = TC_138_793.port_a.T - TC_138_793.port_b.T; TC_138_793.port_a.Q_flow = TC_138_793.Q_flow; TC_138_793.port_b.Q_flow = -TC_138_793.Q_flow; TC_139_140.Q_flow = TC_139_140.G * TC_139_140.dT; TC_139_140.dT = TC_139_140.port_a.T - TC_139_140.port_b.T; TC_139_140.port_a.Q_flow = TC_139_140.Q_flow; TC_139_140.port_b.Q_flow = -TC_139_140.Q_flow; TC_139_152.Q_flow = TC_139_152.G * TC_139_152.dT; TC_139_152.dT = TC_139_152.port_a.T - TC_139_152.port_b.T; TC_139_152.port_a.Q_flow = TC_139_152.Q_flow; TC_139_152.port_b.Q_flow = -TC_139_152.Q_flow; TC_139_794.Q_flow = TC_139_794.G * TC_139_794.dT; TC_139_794.dT = TC_139_794.port_a.T - TC_139_794.port_b.T; TC_139_794.port_a.Q_flow = TC_139_794.Q_flow; TC_139_794.port_b.Q_flow = -TC_139_794.Q_flow; TC_140_141.Q_flow = TC_140_141.G * TC_140_141.dT; TC_140_141.dT = TC_140_141.port_a.T - TC_140_141.port_b.T; TC_140_141.port_a.Q_flow = TC_140_141.Q_flow; TC_140_141.port_b.Q_flow = -TC_140_141.Q_flow; TC_140_153.Q_flow = TC_140_153.G * TC_140_153.dT; TC_140_153.dT = TC_140_153.port_a.T - TC_140_153.port_b.T; TC_140_153.port_a.Q_flow = TC_140_153.Q_flow; TC_140_153.port_b.Q_flow = -TC_140_153.Q_flow; TC_140_795.Q_flow = TC_140_795.G * TC_140_795.dT; TC_140_795.dT = TC_140_795.port_a.T - TC_140_795.port_b.T; TC_140_795.port_a.Q_flow = TC_140_795.Q_flow; TC_140_795.port_b.Q_flow = -TC_140_795.Q_flow; TC_141_142.Q_flow = TC_141_142.G * TC_141_142.dT; TC_141_142.dT = TC_141_142.port_a.T - TC_141_142.port_b.T; TC_141_142.port_a.Q_flow = TC_141_142.Q_flow; TC_141_142.port_b.Q_flow = -TC_141_142.Q_flow; TC_141_154.Q_flow = TC_141_154.G * TC_141_154.dT; TC_141_154.dT = TC_141_154.port_a.T - TC_141_154.port_b.T; TC_141_154.port_a.Q_flow = TC_141_154.Q_flow; TC_141_154.port_b.Q_flow = -TC_141_154.Q_flow; TC_141_796.Q_flow = TC_141_796.G * TC_141_796.dT; TC_141_796.dT = TC_141_796.port_a.T - TC_141_796.port_b.T; TC_141_796.port_a.Q_flow = TC_141_796.Q_flow; TC_141_796.port_b.Q_flow = -TC_141_796.Q_flow; TC_142_143.Q_flow = TC_142_143.G * TC_142_143.dT; TC_142_143.dT = TC_142_143.port_a.T - TC_142_143.port_b.T; TC_142_143.port_a.Q_flow = TC_142_143.Q_flow; TC_142_143.port_b.Q_flow = -TC_142_143.Q_flow; TC_142_155.Q_flow = TC_142_155.G * TC_142_155.dT; TC_142_155.dT = TC_142_155.port_a.T - TC_142_155.port_b.T; TC_142_155.port_a.Q_flow = TC_142_155.Q_flow; TC_142_155.port_b.Q_flow = -TC_142_155.Q_flow; TC_142_1432.Q_flow = TC_142_1432.G * TC_142_1432.dT; TC_142_1432.dT = TC_142_1432.port_a.T - TC_142_1432.port_b.T; TC_142_1432.port_a.Q_flow = TC_142_1432.Q_flow; TC_142_1432.port_b.Q_flow = -TC_142_1432.Q_flow; TC_143_156.Q_flow = TC_143_156.G * TC_143_156.dT; TC_143_156.dT = TC_143_156.port_a.T - TC_143_156.port_b.T; TC_143_156.port_a.Q_flow = TC_143_156.Q_flow; TC_143_156.port_b.Q_flow = -TC_143_156.Q_flow; TC_143_240.Q_flow = TC_143_240.G * TC_143_240.dT; TC_143_240.dT = TC_143_240.port_a.T - TC_143_240.port_b.T; TC_143_240.port_a.Q_flow = TC_143_240.Q_flow; TC_143_240.port_b.Q_flow = -TC_143_240.Q_flow; TC_144_145.Q_flow = TC_144_145.G * TC_144_145.dT; TC_144_145.dT = TC_144_145.port_a.T - TC_144_145.port_b.T; TC_144_145.port_a.Q_flow = TC_144_145.Q_flow; TC_144_145.port_b.Q_flow = -TC_144_145.Q_flow; TC_144_157.Q_flow = TC_144_157.G * TC_144_157.dT; TC_144_157.dT = TC_144_157.port_a.T - TC_144_157.port_b.T; TC_144_157.port_a.Q_flow = TC_144_157.Q_flow; TC_144_157.port_b.Q_flow = -TC_144_157.Q_flow; TC_144_241.Q_flow = TC_144_241.G * TC_144_241.dT; TC_144_241.dT = TC_144_241.port_a.T - TC_144_241.port_b.T; TC_144_241.port_a.Q_flow = TC_144_241.Q_flow; TC_144_241.port_b.Q_flow = -TC_144_241.Q_flow; TC_145_146.Q_flow = TC_145_146.G * TC_145_146.dT; TC_145_146.dT = TC_145_146.port_a.T - TC_145_146.port_b.T; TC_145_146.port_a.Q_flow = TC_145_146.Q_flow; TC_145_146.port_b.Q_flow = -TC_145_146.Q_flow; TC_145_158.Q_flow = TC_145_158.G * TC_145_158.dT; TC_145_158.dT = TC_145_158.port_a.T - TC_145_158.port_b.T; TC_145_158.port_a.Q_flow = TC_145_158.Q_flow; TC_145_158.port_b.Q_flow = -TC_145_158.Q_flow; TC_145_1433.Q_flow = TC_145_1433.G * TC_145_1433.dT; TC_145_1433.dT = TC_145_1433.port_a.T - TC_145_1433.port_b.T; TC_145_1433.port_a.Q_flow = TC_145_1433.Q_flow; TC_145_1433.port_b.Q_flow = -TC_145_1433.Q_flow; TC_146_147.Q_flow = TC_146_147.G * TC_146_147.dT; TC_146_147.dT = TC_146_147.port_a.T - TC_146_147.port_b.T; TC_146_147.port_a.Q_flow = TC_146_147.Q_flow; TC_146_147.port_b.Q_flow = -TC_146_147.Q_flow; TC_146_159.Q_flow = TC_146_159.G * TC_146_159.dT; TC_146_159.dT = TC_146_159.port_a.T - TC_146_159.port_b.T; TC_146_159.port_a.Q_flow = TC_146_159.Q_flow; TC_146_159.port_b.Q_flow = -TC_146_159.Q_flow; TC_146_1434.Q_flow = TC_146_1434.G * TC_146_1434.dT; TC_146_1434.dT = TC_146_1434.port_a.T - TC_146_1434.port_b.T; TC_146_1434.port_a.Q_flow = TC_146_1434.Q_flow; TC_146_1434.port_b.Q_flow = -TC_146_1434.Q_flow; TC_147_148.Q_flow = TC_147_148.G * TC_147_148.dT; TC_147_148.dT = TC_147_148.port_a.T - TC_147_148.port_b.T; TC_147_148.port_a.Q_flow = TC_147_148.Q_flow; TC_147_148.port_b.Q_flow = -TC_147_148.Q_flow; TC_147_160.Q_flow = TC_147_160.G * TC_147_160.dT; TC_147_160.dT = TC_147_160.port_a.T - TC_147_160.port_b.T; TC_147_160.port_a.Q_flow = TC_147_160.Q_flow; TC_147_160.port_b.Q_flow = -TC_147_160.Q_flow; TC_147_797.Q_flow = TC_147_797.G * TC_147_797.dT; TC_147_797.dT = TC_147_797.port_a.T - TC_147_797.port_b.T; TC_147_797.port_a.Q_flow = TC_147_797.Q_flow; TC_147_797.port_b.Q_flow = -TC_147_797.Q_flow; TC_148_149.Q_flow = TC_148_149.G * TC_148_149.dT; TC_148_149.dT = TC_148_149.port_a.T - TC_148_149.port_b.T; TC_148_149.port_a.Q_flow = TC_148_149.Q_flow; TC_148_149.port_b.Q_flow = -TC_148_149.Q_flow; TC_148_161.Q_flow = TC_148_161.G * TC_148_161.dT; TC_148_161.dT = TC_148_161.port_a.T - TC_148_161.port_b.T; TC_148_161.port_a.Q_flow = TC_148_161.Q_flow; TC_148_161.port_b.Q_flow = -TC_148_161.Q_flow; TC_148_798.Q_flow = TC_148_798.G * TC_148_798.dT; TC_148_798.dT = TC_148_798.port_a.T - TC_148_798.port_b.T; TC_148_798.port_a.Q_flow = TC_148_798.Q_flow; TC_148_798.port_b.Q_flow = -TC_148_798.Q_flow; TC_149_150.Q_flow = TC_149_150.G * TC_149_150.dT; TC_149_150.dT = TC_149_150.port_a.T - TC_149_150.port_b.T; TC_149_150.port_a.Q_flow = TC_149_150.Q_flow; TC_149_150.port_b.Q_flow = -TC_149_150.Q_flow; TC_149_162.Q_flow = TC_149_162.G * TC_149_162.dT; TC_149_162.dT = TC_149_162.port_a.T - TC_149_162.port_b.T; TC_149_162.port_a.Q_flow = TC_149_162.Q_flow; TC_149_162.port_b.Q_flow = -TC_149_162.Q_flow; TC_149_799.Q_flow = TC_149_799.G * TC_149_799.dT; TC_149_799.dT = TC_149_799.port_a.T - TC_149_799.port_b.T; TC_149_799.port_a.Q_flow = TC_149_799.Q_flow; TC_149_799.port_b.Q_flow = -TC_149_799.Q_flow; TC_150_151.Q_flow = TC_150_151.G * TC_150_151.dT; TC_150_151.dT = TC_150_151.port_a.T - TC_150_151.port_b.T; TC_150_151.port_a.Q_flow = TC_150_151.Q_flow; TC_150_151.port_b.Q_flow = -TC_150_151.Q_flow; TC_150_163.Q_flow = TC_150_163.G * TC_150_163.dT; TC_150_163.dT = TC_150_163.port_a.T - TC_150_163.port_b.T; TC_150_163.port_a.Q_flow = TC_150_163.Q_flow; TC_150_163.port_b.Q_flow = -TC_150_163.Q_flow; TC_150_800.Q_flow = TC_150_800.G * TC_150_800.dT; TC_150_800.dT = TC_150_800.port_a.T - TC_150_800.port_b.T; TC_150_800.port_a.Q_flow = TC_150_800.Q_flow; TC_150_800.port_b.Q_flow = -TC_150_800.Q_flow; TC_151_152.Q_flow = TC_151_152.G * TC_151_152.dT; TC_151_152.dT = TC_151_152.port_a.T - TC_151_152.port_b.T; TC_151_152.port_a.Q_flow = TC_151_152.Q_flow; TC_151_152.port_b.Q_flow = -TC_151_152.Q_flow; TC_151_164.Q_flow = TC_151_164.G * TC_151_164.dT; TC_151_164.dT = TC_151_164.port_a.T - TC_151_164.port_b.T; TC_151_164.port_a.Q_flow = TC_151_164.Q_flow; TC_151_164.port_b.Q_flow = -TC_151_164.Q_flow; TC_151_801.Q_flow = TC_151_801.G * TC_151_801.dT; TC_151_801.dT = TC_151_801.port_a.T - TC_151_801.port_b.T; TC_151_801.port_a.Q_flow = TC_151_801.Q_flow; TC_151_801.port_b.Q_flow = -TC_151_801.Q_flow; TC_152_153.Q_flow = TC_152_153.G * TC_152_153.dT; TC_152_153.dT = TC_152_153.port_a.T - TC_152_153.port_b.T; TC_152_153.port_a.Q_flow = TC_152_153.Q_flow; TC_152_153.port_b.Q_flow = -TC_152_153.Q_flow; TC_152_165.Q_flow = TC_152_165.G * TC_152_165.dT; TC_152_165.dT = TC_152_165.port_a.T - TC_152_165.port_b.T; TC_152_165.port_a.Q_flow = TC_152_165.Q_flow; TC_152_165.port_b.Q_flow = -TC_152_165.Q_flow; TC_152_802.Q_flow = TC_152_802.G * TC_152_802.dT; TC_152_802.dT = TC_152_802.port_a.T - TC_152_802.port_b.T; TC_152_802.port_a.Q_flow = TC_152_802.Q_flow; TC_152_802.port_b.Q_flow = -TC_152_802.Q_flow; TC_153_154.Q_flow = TC_153_154.G * TC_153_154.dT; TC_153_154.dT = TC_153_154.port_a.T - TC_153_154.port_b.T; TC_153_154.port_a.Q_flow = TC_153_154.Q_flow; TC_153_154.port_b.Q_flow = -TC_153_154.Q_flow; TC_153_166.Q_flow = TC_153_166.G * TC_153_166.dT; TC_153_166.dT = TC_153_166.port_a.T - TC_153_166.port_b.T; TC_153_166.port_a.Q_flow = TC_153_166.Q_flow; TC_153_166.port_b.Q_flow = -TC_153_166.Q_flow; TC_153_803.Q_flow = TC_153_803.G * TC_153_803.dT; TC_153_803.dT = TC_153_803.port_a.T - TC_153_803.port_b.T; TC_153_803.port_a.Q_flow = TC_153_803.Q_flow; TC_153_803.port_b.Q_flow = -TC_153_803.Q_flow; TC_154_155.Q_flow = TC_154_155.G * TC_154_155.dT; TC_154_155.dT = TC_154_155.port_a.T - TC_154_155.port_b.T; TC_154_155.port_a.Q_flow = TC_154_155.Q_flow; TC_154_155.port_b.Q_flow = -TC_154_155.Q_flow; TC_154_167.Q_flow = TC_154_167.G * TC_154_167.dT; TC_154_167.dT = TC_154_167.port_a.T - TC_154_167.port_b.T; TC_154_167.port_a.Q_flow = TC_154_167.Q_flow; TC_154_167.port_b.Q_flow = -TC_154_167.Q_flow; TC_154_804.Q_flow = TC_154_804.G * TC_154_804.dT; TC_154_804.dT = TC_154_804.port_a.T - TC_154_804.port_b.T; TC_154_804.port_a.Q_flow = TC_154_804.Q_flow; TC_154_804.port_b.Q_flow = -TC_154_804.Q_flow; TC_155_156.Q_flow = TC_155_156.G * TC_155_156.dT; TC_155_156.dT = TC_155_156.port_a.T - TC_155_156.port_b.T; TC_155_156.port_a.Q_flow = TC_155_156.Q_flow; TC_155_156.port_b.Q_flow = -TC_155_156.Q_flow; TC_155_168.Q_flow = TC_155_168.G * TC_155_168.dT; TC_155_168.dT = TC_155_168.port_a.T - TC_155_168.port_b.T; TC_155_168.port_a.Q_flow = TC_155_168.Q_flow; TC_155_168.port_b.Q_flow = -TC_155_168.Q_flow; TC_155_1435.Q_flow = TC_155_1435.G * TC_155_1435.dT; TC_155_1435.dT = TC_155_1435.port_a.T - TC_155_1435.port_b.T; TC_155_1435.port_a.Q_flow = TC_155_1435.Q_flow; TC_155_1435.port_b.Q_flow = -TC_155_1435.Q_flow; TC_156_169.Q_flow = TC_156_169.G * TC_156_169.dT; TC_156_169.dT = TC_156_169.port_a.T - TC_156_169.port_b.T; TC_156_169.port_a.Q_flow = TC_156_169.Q_flow; TC_156_169.port_b.Q_flow = -TC_156_169.Q_flow; TC_156_242.Q_flow = TC_156_242.G * TC_156_242.dT; TC_156_242.dT = TC_156_242.port_a.T - TC_156_242.port_b.T; TC_156_242.port_a.Q_flow = TC_156_242.Q_flow; TC_156_242.port_b.Q_flow = -TC_156_242.Q_flow; TC_157_158.Q_flow = TC_157_158.G * TC_157_158.dT; TC_157_158.dT = TC_157_158.port_a.T - TC_157_158.port_b.T; TC_157_158.port_a.Q_flow = TC_157_158.Q_flow; TC_157_158.port_b.Q_flow = -TC_157_158.Q_flow; TC_157_170.Q_flow = TC_157_170.G * TC_157_170.dT; TC_157_170.dT = TC_157_170.port_a.T - TC_157_170.port_b.T; TC_157_170.port_a.Q_flow = TC_157_170.Q_flow; TC_157_170.port_b.Q_flow = -TC_157_170.Q_flow; TC_157_243.Q_flow = TC_157_243.G * TC_157_243.dT; TC_157_243.dT = TC_157_243.port_a.T - TC_157_243.port_b.T; TC_157_243.port_a.Q_flow = TC_157_243.Q_flow; TC_157_243.port_b.Q_flow = -TC_157_243.Q_flow; TC_158_159.Q_flow = TC_158_159.G * TC_158_159.dT; TC_158_159.dT = TC_158_159.port_a.T - TC_158_159.port_b.T; TC_158_159.port_a.Q_flow = TC_158_159.Q_flow; TC_158_159.port_b.Q_flow = -TC_158_159.Q_flow; TC_158_171.Q_flow = TC_158_171.G * TC_158_171.dT; TC_158_171.dT = TC_158_171.port_a.T - TC_158_171.port_b.T; TC_158_171.port_a.Q_flow = TC_158_171.Q_flow; TC_158_171.port_b.Q_flow = -TC_158_171.Q_flow; TC_158_1436.Q_flow = TC_158_1436.G * TC_158_1436.dT; TC_158_1436.dT = TC_158_1436.port_a.T - TC_158_1436.port_b.T; TC_158_1436.port_a.Q_flow = TC_158_1436.Q_flow; TC_158_1436.port_b.Q_flow = -TC_158_1436.Q_flow; TC_159_160.Q_flow = TC_159_160.G * TC_159_160.dT; TC_159_160.dT = TC_159_160.port_a.T - TC_159_160.port_b.T; TC_159_160.port_a.Q_flow = TC_159_160.Q_flow; TC_159_160.port_b.Q_flow = -TC_159_160.Q_flow; TC_159_172.Q_flow = TC_159_172.G * TC_159_172.dT; TC_159_172.dT = TC_159_172.port_a.T - TC_159_172.port_b.T; TC_159_172.port_a.Q_flow = TC_159_172.Q_flow; TC_159_172.port_b.Q_flow = -TC_159_172.Q_flow; TC_159_1437.Q_flow = TC_159_1437.G * TC_159_1437.dT; TC_159_1437.dT = TC_159_1437.port_a.T - TC_159_1437.port_b.T; TC_159_1437.port_a.Q_flow = TC_159_1437.Q_flow; TC_159_1437.port_b.Q_flow = -TC_159_1437.Q_flow; TC_160_161.Q_flow = TC_160_161.G * TC_160_161.dT; TC_160_161.dT = TC_160_161.port_a.T - TC_160_161.port_b.T; TC_160_161.port_a.Q_flow = TC_160_161.Q_flow; TC_160_161.port_b.Q_flow = -TC_160_161.Q_flow; TC_160_173.Q_flow = TC_160_173.G * TC_160_173.dT; TC_160_173.dT = TC_160_173.port_a.T - TC_160_173.port_b.T; TC_160_173.port_a.Q_flow = TC_160_173.Q_flow; TC_160_173.port_b.Q_flow = -TC_160_173.Q_flow; TC_160_805.Q_flow = TC_160_805.G * TC_160_805.dT; TC_160_805.dT = TC_160_805.port_a.T - TC_160_805.port_b.T; TC_160_805.port_a.Q_flow = TC_160_805.Q_flow; TC_160_805.port_b.Q_flow = -TC_160_805.Q_flow; TC_161_162.Q_flow = TC_161_162.G * TC_161_162.dT; TC_161_162.dT = TC_161_162.port_a.T - TC_161_162.port_b.T; TC_161_162.port_a.Q_flow = TC_161_162.Q_flow; TC_161_162.port_b.Q_flow = -TC_161_162.Q_flow; TC_161_174.Q_flow = TC_161_174.G * TC_161_174.dT; TC_161_174.dT = TC_161_174.port_a.T - TC_161_174.port_b.T; TC_161_174.port_a.Q_flow = TC_161_174.Q_flow; TC_161_174.port_b.Q_flow = -TC_161_174.Q_flow; TC_161_806.Q_flow = TC_161_806.G * TC_161_806.dT; TC_161_806.dT = TC_161_806.port_a.T - TC_161_806.port_b.T; TC_161_806.port_a.Q_flow = TC_161_806.Q_flow; TC_161_806.port_b.Q_flow = -TC_161_806.Q_flow; TC_162_163.Q_flow = TC_162_163.G * TC_162_163.dT; TC_162_163.dT = TC_162_163.port_a.T - TC_162_163.port_b.T; TC_162_163.port_a.Q_flow = TC_162_163.Q_flow; TC_162_163.port_b.Q_flow = -TC_162_163.Q_flow; TC_162_175.Q_flow = TC_162_175.G * TC_162_175.dT; TC_162_175.dT = TC_162_175.port_a.T - TC_162_175.port_b.T; TC_162_175.port_a.Q_flow = TC_162_175.Q_flow; TC_162_175.port_b.Q_flow = -TC_162_175.Q_flow; TC_162_807.Q_flow = TC_162_807.G * TC_162_807.dT; TC_162_807.dT = TC_162_807.port_a.T - TC_162_807.port_b.T; TC_162_807.port_a.Q_flow = TC_162_807.Q_flow; TC_162_807.port_b.Q_flow = -TC_162_807.Q_flow; TC_163_164.Q_flow = TC_163_164.G * TC_163_164.dT; TC_163_164.dT = TC_163_164.port_a.T - TC_163_164.port_b.T; TC_163_164.port_a.Q_flow = TC_163_164.Q_flow; TC_163_164.port_b.Q_flow = -TC_163_164.Q_flow; TC_163_176.Q_flow = TC_163_176.G * TC_163_176.dT; TC_163_176.dT = TC_163_176.port_a.T - TC_163_176.port_b.T; TC_163_176.port_a.Q_flow = TC_163_176.Q_flow; TC_163_176.port_b.Q_flow = -TC_163_176.Q_flow; TC_163_808.Q_flow = TC_163_808.G * TC_163_808.dT; TC_163_808.dT = TC_163_808.port_a.T - TC_163_808.port_b.T; TC_163_808.port_a.Q_flow = TC_163_808.Q_flow; TC_163_808.port_b.Q_flow = -TC_163_808.Q_flow; TC_164_165.Q_flow = TC_164_165.G * TC_164_165.dT; TC_164_165.dT = TC_164_165.port_a.T - TC_164_165.port_b.T; TC_164_165.port_a.Q_flow = TC_164_165.Q_flow; TC_164_165.port_b.Q_flow = -TC_164_165.Q_flow; TC_164_177.Q_flow = TC_164_177.G * TC_164_177.dT; TC_164_177.dT = TC_164_177.port_a.T - TC_164_177.port_b.T; TC_164_177.port_a.Q_flow = TC_164_177.Q_flow; TC_164_177.port_b.Q_flow = -TC_164_177.Q_flow; TC_164_809.Q_flow = TC_164_809.G * TC_164_809.dT; TC_164_809.dT = TC_164_809.port_a.T - TC_164_809.port_b.T; TC_164_809.port_a.Q_flow = TC_164_809.Q_flow; TC_164_809.port_b.Q_flow = -TC_164_809.Q_flow; TC_165_166.Q_flow = TC_165_166.G * TC_165_166.dT; TC_165_166.dT = TC_165_166.port_a.T - TC_165_166.port_b.T; TC_165_166.port_a.Q_flow = TC_165_166.Q_flow; TC_165_166.port_b.Q_flow = -TC_165_166.Q_flow; TC_165_178.Q_flow = TC_165_178.G * TC_165_178.dT; TC_165_178.dT = TC_165_178.port_a.T - TC_165_178.port_b.T; TC_165_178.port_a.Q_flow = TC_165_178.Q_flow; TC_165_178.port_b.Q_flow = -TC_165_178.Q_flow; TC_165_810.Q_flow = TC_165_810.G * TC_165_810.dT; TC_165_810.dT = TC_165_810.port_a.T - TC_165_810.port_b.T; TC_165_810.port_a.Q_flow = TC_165_810.Q_flow; TC_165_810.port_b.Q_flow = -TC_165_810.Q_flow; TC_166_167.Q_flow = TC_166_167.G * TC_166_167.dT; TC_166_167.dT = TC_166_167.port_a.T - TC_166_167.port_b.T; TC_166_167.port_a.Q_flow = TC_166_167.Q_flow; TC_166_167.port_b.Q_flow = -TC_166_167.Q_flow; TC_166_179.Q_flow = TC_166_179.G * TC_166_179.dT; TC_166_179.dT = TC_166_179.port_a.T - TC_166_179.port_b.T; TC_166_179.port_a.Q_flow = TC_166_179.Q_flow; TC_166_179.port_b.Q_flow = -TC_166_179.Q_flow; TC_166_811.Q_flow = TC_166_811.G * TC_166_811.dT; TC_166_811.dT = TC_166_811.port_a.T - TC_166_811.port_b.T; TC_166_811.port_a.Q_flow = TC_166_811.Q_flow; TC_166_811.port_b.Q_flow = -TC_166_811.Q_flow; TC_167_168.Q_flow = TC_167_168.G * TC_167_168.dT; TC_167_168.dT = TC_167_168.port_a.T - TC_167_168.port_b.T; TC_167_168.port_a.Q_flow = TC_167_168.Q_flow; TC_167_168.port_b.Q_flow = -TC_167_168.Q_flow; TC_167_180.Q_flow = TC_167_180.G * TC_167_180.dT; TC_167_180.dT = TC_167_180.port_a.T - TC_167_180.port_b.T; TC_167_180.port_a.Q_flow = TC_167_180.Q_flow; TC_167_180.port_b.Q_flow = -TC_167_180.Q_flow; TC_167_812.Q_flow = TC_167_812.G * TC_167_812.dT; TC_167_812.dT = TC_167_812.port_a.T - TC_167_812.port_b.T; TC_167_812.port_a.Q_flow = TC_167_812.Q_flow; TC_167_812.port_b.Q_flow = -TC_167_812.Q_flow; TC_168_169.Q_flow = TC_168_169.G * TC_168_169.dT; TC_168_169.dT = TC_168_169.port_a.T - TC_168_169.port_b.T; TC_168_169.port_a.Q_flow = TC_168_169.Q_flow; TC_168_169.port_b.Q_flow = -TC_168_169.Q_flow; TC_168_181.Q_flow = TC_168_181.G * TC_168_181.dT; TC_168_181.dT = TC_168_181.port_a.T - TC_168_181.port_b.T; TC_168_181.port_a.Q_flow = TC_168_181.Q_flow; TC_168_181.port_b.Q_flow = -TC_168_181.Q_flow; TC_168_1438.Q_flow = TC_168_1438.G * TC_168_1438.dT; TC_168_1438.dT = TC_168_1438.port_a.T - TC_168_1438.port_b.T; TC_168_1438.port_a.Q_flow = TC_168_1438.Q_flow; TC_168_1438.port_b.Q_flow = -TC_168_1438.Q_flow; TC_169_182.Q_flow = TC_169_182.G * TC_169_182.dT; TC_169_182.dT = TC_169_182.port_a.T - TC_169_182.port_b.T; TC_169_182.port_a.Q_flow = TC_169_182.Q_flow; TC_169_182.port_b.Q_flow = -TC_169_182.Q_flow; TC_169_244.Q_flow = TC_169_244.G * TC_169_244.dT; TC_169_244.dT = TC_169_244.port_a.T - TC_169_244.port_b.T; TC_169_244.port_a.Q_flow = TC_169_244.Q_flow; TC_169_244.port_b.Q_flow = -TC_169_244.Q_flow; TC_170_171.Q_flow = TC_170_171.G * TC_170_171.dT; TC_170_171.dT = TC_170_171.port_a.T - TC_170_171.port_b.T; TC_170_171.port_a.Q_flow = TC_170_171.Q_flow; TC_170_171.port_b.Q_flow = -TC_170_171.Q_flow; TC_170_183.Q_flow = TC_170_183.G * TC_170_183.dT; TC_170_183.dT = TC_170_183.port_a.T - TC_170_183.port_b.T; TC_170_183.port_a.Q_flow = TC_170_183.Q_flow; TC_170_183.port_b.Q_flow = -TC_170_183.Q_flow; TC_170_245.Q_flow = TC_170_245.G * TC_170_245.dT; TC_170_245.dT = TC_170_245.port_a.T - TC_170_245.port_b.T; TC_170_245.port_a.Q_flow = TC_170_245.Q_flow; TC_170_245.port_b.Q_flow = -TC_170_245.Q_flow; TC_171_172.Q_flow = TC_171_172.G * TC_171_172.dT; TC_171_172.dT = TC_171_172.port_a.T - TC_171_172.port_b.T; TC_171_172.port_a.Q_flow = TC_171_172.Q_flow; TC_171_172.port_b.Q_flow = -TC_171_172.Q_flow; TC_171_184.Q_flow = TC_171_184.G * TC_171_184.dT; TC_171_184.dT = TC_171_184.port_a.T - TC_171_184.port_b.T; TC_171_184.port_a.Q_flow = TC_171_184.Q_flow; TC_171_184.port_b.Q_flow = -TC_171_184.Q_flow; TC_171_1439.Q_flow = TC_171_1439.G * TC_171_1439.dT; TC_171_1439.dT = TC_171_1439.port_a.T - TC_171_1439.port_b.T; TC_171_1439.port_a.Q_flow = TC_171_1439.Q_flow; TC_171_1439.port_b.Q_flow = -TC_171_1439.Q_flow; TC_172_173.Q_flow = TC_172_173.G * TC_172_173.dT; TC_172_173.dT = TC_172_173.port_a.T - TC_172_173.port_b.T; TC_172_173.port_a.Q_flow = TC_172_173.Q_flow; TC_172_173.port_b.Q_flow = -TC_172_173.Q_flow; TC_172_185.Q_flow = TC_172_185.G * TC_172_185.dT; TC_172_185.dT = TC_172_185.port_a.T - TC_172_185.port_b.T; TC_172_185.port_a.Q_flow = TC_172_185.Q_flow; TC_172_185.port_b.Q_flow = -TC_172_185.Q_flow; TC_172_1440.Q_flow = TC_172_1440.G * TC_172_1440.dT; TC_172_1440.dT = TC_172_1440.port_a.T - TC_172_1440.port_b.T; TC_172_1440.port_a.Q_flow = TC_172_1440.Q_flow; TC_172_1440.port_b.Q_flow = -TC_172_1440.Q_flow; TC_173_174.Q_flow = TC_173_174.G * TC_173_174.dT; TC_173_174.dT = TC_173_174.port_a.T - TC_173_174.port_b.T; TC_173_174.port_a.Q_flow = TC_173_174.Q_flow; TC_173_174.port_b.Q_flow = -TC_173_174.Q_flow; TC_173_186.Q_flow = TC_173_186.G * TC_173_186.dT; TC_173_186.dT = TC_173_186.port_a.T - TC_173_186.port_b.T; TC_173_186.port_a.Q_flow = TC_173_186.Q_flow; TC_173_186.port_b.Q_flow = -TC_173_186.Q_flow; TC_173_1441.Q_flow = TC_173_1441.G * TC_173_1441.dT; TC_173_1441.dT = TC_173_1441.port_a.T - TC_173_1441.port_b.T; TC_173_1441.port_a.Q_flow = TC_173_1441.Q_flow; TC_173_1441.port_b.Q_flow = -TC_173_1441.Q_flow; TC_174_175.Q_flow = TC_174_175.G * TC_174_175.dT; TC_174_175.dT = TC_174_175.port_a.T - TC_174_175.port_b.T; TC_174_175.port_a.Q_flow = TC_174_175.Q_flow; TC_174_175.port_b.Q_flow = -TC_174_175.Q_flow; TC_174_187.Q_flow = TC_174_187.G * TC_174_187.dT; TC_174_187.dT = TC_174_187.port_a.T - TC_174_187.port_b.T; TC_174_187.port_a.Q_flow = TC_174_187.Q_flow; TC_174_187.port_b.Q_flow = -TC_174_187.Q_flow; TC_174_1442.Q_flow = TC_174_1442.G * TC_174_1442.dT; TC_174_1442.dT = TC_174_1442.port_a.T - TC_174_1442.port_b.T; TC_174_1442.port_a.Q_flow = TC_174_1442.Q_flow; TC_174_1442.port_b.Q_flow = -TC_174_1442.Q_flow; TC_175_176.Q_flow = TC_175_176.G * TC_175_176.dT; TC_175_176.dT = TC_175_176.port_a.T - TC_175_176.port_b.T; TC_175_176.port_a.Q_flow = TC_175_176.Q_flow; TC_175_176.port_b.Q_flow = -TC_175_176.Q_flow; TC_175_188.Q_flow = TC_175_188.G * TC_175_188.dT; TC_175_188.dT = TC_175_188.port_a.T - TC_175_188.port_b.T; TC_175_188.port_a.Q_flow = TC_175_188.Q_flow; TC_175_188.port_b.Q_flow = -TC_175_188.Q_flow; TC_175_1443.Q_flow = TC_175_1443.G * TC_175_1443.dT; TC_175_1443.dT = TC_175_1443.port_a.T - TC_175_1443.port_b.T; TC_175_1443.port_a.Q_flow = TC_175_1443.Q_flow; TC_175_1443.port_b.Q_flow = -TC_175_1443.Q_flow; TC_176_177.Q_flow = TC_176_177.G * TC_176_177.dT; TC_176_177.dT = TC_176_177.port_a.T - TC_176_177.port_b.T; TC_176_177.port_a.Q_flow = TC_176_177.Q_flow; TC_176_177.port_b.Q_flow = -TC_176_177.Q_flow; TC_176_189.Q_flow = TC_176_189.G * TC_176_189.dT; TC_176_189.dT = TC_176_189.port_a.T - TC_176_189.port_b.T; TC_176_189.port_a.Q_flow = TC_176_189.Q_flow; TC_176_189.port_b.Q_flow = -TC_176_189.Q_flow; TC_176_1444.Q_flow = TC_176_1444.G * TC_176_1444.dT; TC_176_1444.dT = TC_176_1444.port_a.T - TC_176_1444.port_b.T; TC_176_1444.port_a.Q_flow = TC_176_1444.Q_flow; TC_176_1444.port_b.Q_flow = -TC_176_1444.Q_flow; TC_177_178.Q_flow = TC_177_178.G * TC_177_178.dT; TC_177_178.dT = TC_177_178.port_a.T - TC_177_178.port_b.T; TC_177_178.port_a.Q_flow = TC_177_178.Q_flow; TC_177_178.port_b.Q_flow = -TC_177_178.Q_flow; TC_177_190.Q_flow = TC_177_190.G * TC_177_190.dT; TC_177_190.dT = TC_177_190.port_a.T - TC_177_190.port_b.T; TC_177_190.port_a.Q_flow = TC_177_190.Q_flow; TC_177_190.port_b.Q_flow = -TC_177_190.Q_flow; TC_177_1445.Q_flow = TC_177_1445.G * TC_177_1445.dT; TC_177_1445.dT = TC_177_1445.port_a.T - TC_177_1445.port_b.T; TC_177_1445.port_a.Q_flow = TC_177_1445.Q_flow; TC_177_1445.port_b.Q_flow = -TC_177_1445.Q_flow; TC_178_179.Q_flow = TC_178_179.G * TC_178_179.dT; TC_178_179.dT = TC_178_179.port_a.T - TC_178_179.port_b.T; TC_178_179.port_a.Q_flow = TC_178_179.Q_flow; TC_178_179.port_b.Q_flow = -TC_178_179.Q_flow; TC_178_191.Q_flow = TC_178_191.G * TC_178_191.dT; TC_178_191.dT = TC_178_191.port_a.T - TC_178_191.port_b.T; TC_178_191.port_a.Q_flow = TC_178_191.Q_flow; TC_178_191.port_b.Q_flow = -TC_178_191.Q_flow; TC_178_1446.Q_flow = TC_178_1446.G * TC_178_1446.dT; TC_178_1446.dT = TC_178_1446.port_a.T - TC_178_1446.port_b.T; TC_178_1446.port_a.Q_flow = TC_178_1446.Q_flow; TC_178_1446.port_b.Q_flow = -TC_178_1446.Q_flow; TC_179_180.Q_flow = TC_179_180.G * TC_179_180.dT; TC_179_180.dT = TC_179_180.port_a.T - TC_179_180.port_b.T; TC_179_180.port_a.Q_flow = TC_179_180.Q_flow; TC_179_180.port_b.Q_flow = -TC_179_180.Q_flow; TC_179_192.Q_flow = TC_179_192.G * TC_179_192.dT; TC_179_192.dT = TC_179_192.port_a.T - TC_179_192.port_b.T; TC_179_192.port_a.Q_flow = TC_179_192.Q_flow; TC_179_192.port_b.Q_flow = -TC_179_192.Q_flow; TC_179_1447.Q_flow = TC_179_1447.G * TC_179_1447.dT; TC_179_1447.dT = TC_179_1447.port_a.T - TC_179_1447.port_b.T; TC_179_1447.port_a.Q_flow = TC_179_1447.Q_flow; TC_179_1447.port_b.Q_flow = -TC_179_1447.Q_flow; TC_180_181.Q_flow = TC_180_181.G * TC_180_181.dT; TC_180_181.dT = TC_180_181.port_a.T - TC_180_181.port_b.T; TC_180_181.port_a.Q_flow = TC_180_181.Q_flow; TC_180_181.port_b.Q_flow = -TC_180_181.Q_flow; TC_180_193.Q_flow = TC_180_193.G * TC_180_193.dT; TC_180_193.dT = TC_180_193.port_a.T - TC_180_193.port_b.T; TC_180_193.port_a.Q_flow = TC_180_193.Q_flow; TC_180_193.port_b.Q_flow = -TC_180_193.Q_flow; TC_180_1448.Q_flow = TC_180_1448.G * TC_180_1448.dT; TC_180_1448.dT = TC_180_1448.port_a.T - TC_180_1448.port_b.T; TC_180_1448.port_a.Q_flow = TC_180_1448.Q_flow; TC_180_1448.port_b.Q_flow = -TC_180_1448.Q_flow; TC_181_182.Q_flow = TC_181_182.G * TC_181_182.dT; TC_181_182.dT = TC_181_182.port_a.T - TC_181_182.port_b.T; TC_181_182.port_a.Q_flow = TC_181_182.Q_flow; TC_181_182.port_b.Q_flow = -TC_181_182.Q_flow; TC_181_194.Q_flow = TC_181_194.G * TC_181_194.dT; TC_181_194.dT = TC_181_194.port_a.T - TC_181_194.port_b.T; TC_181_194.port_a.Q_flow = TC_181_194.Q_flow; TC_181_194.port_b.Q_flow = -TC_181_194.Q_flow; TC_181_1449.Q_flow = TC_181_1449.G * TC_181_1449.dT; TC_181_1449.dT = TC_181_1449.port_a.T - TC_181_1449.port_b.T; TC_181_1449.port_a.Q_flow = TC_181_1449.Q_flow; TC_181_1449.port_b.Q_flow = -TC_181_1449.Q_flow; TC_182_195.Q_flow = TC_182_195.G * TC_182_195.dT; TC_182_195.dT = TC_182_195.port_a.T - TC_182_195.port_b.T; TC_182_195.port_a.Q_flow = TC_182_195.Q_flow; TC_182_195.port_b.Q_flow = -TC_182_195.Q_flow; TC_182_246.Q_flow = TC_182_246.G * TC_182_246.dT; TC_182_246.dT = TC_182_246.port_a.T - TC_182_246.port_b.T; TC_182_246.port_a.Q_flow = TC_182_246.Q_flow; TC_182_246.port_b.Q_flow = -TC_182_246.Q_flow; TC_183_184.Q_flow = TC_183_184.G * TC_183_184.dT; TC_183_184.dT = TC_183_184.port_a.T - TC_183_184.port_b.T; TC_183_184.port_a.Q_flow = TC_183_184.Q_flow; TC_183_184.port_b.Q_flow = -TC_183_184.Q_flow; TC_183_196.Q_flow = TC_183_196.G * TC_183_196.dT; TC_183_196.dT = TC_183_196.port_a.T - TC_183_196.port_b.T; TC_183_196.port_a.Q_flow = TC_183_196.Q_flow; TC_183_196.port_b.Q_flow = -TC_183_196.Q_flow; TC_183_247.Q_flow = TC_183_247.G * TC_183_247.dT; TC_183_247.dT = TC_183_247.port_a.T - TC_183_247.port_b.T; TC_183_247.port_a.Q_flow = TC_183_247.Q_flow; TC_183_247.port_b.Q_flow = -TC_183_247.Q_flow; TC_184_185.Q_flow = TC_184_185.G * TC_184_185.dT; TC_184_185.dT = TC_184_185.port_a.T - TC_184_185.port_b.T; TC_184_185.port_a.Q_flow = TC_184_185.Q_flow; TC_184_185.port_b.Q_flow = -TC_184_185.Q_flow; TC_184_197.Q_flow = TC_184_197.G * TC_184_197.dT; TC_184_197.dT = TC_184_197.port_a.T - TC_184_197.port_b.T; TC_184_197.port_a.Q_flow = TC_184_197.Q_flow; TC_184_197.port_b.Q_flow = -TC_184_197.Q_flow; TC_184_1450.Q_flow = TC_184_1450.G * TC_184_1450.dT; TC_184_1450.dT = TC_184_1450.port_a.T - TC_184_1450.port_b.T; TC_184_1450.port_a.Q_flow = TC_184_1450.Q_flow; TC_184_1450.port_b.Q_flow = -TC_184_1450.Q_flow; TC_185_186.Q_flow = TC_185_186.G * TC_185_186.dT; TC_185_186.dT = TC_185_186.port_a.T - TC_185_186.port_b.T; TC_185_186.port_a.Q_flow = TC_185_186.Q_flow; TC_185_186.port_b.Q_flow = -TC_185_186.Q_flow; TC_185_198.Q_flow = TC_185_198.G * TC_185_198.dT; TC_185_198.dT = TC_185_198.port_a.T - TC_185_198.port_b.T; TC_185_198.port_a.Q_flow = TC_185_198.Q_flow; TC_185_198.port_b.Q_flow = -TC_185_198.Q_flow; TC_185_1451.Q_flow = TC_185_1451.G * TC_185_1451.dT; TC_185_1451.dT = TC_185_1451.port_a.T - TC_185_1451.port_b.T; TC_185_1451.port_a.Q_flow = TC_185_1451.Q_flow; TC_185_1451.port_b.Q_flow = -TC_185_1451.Q_flow; TC_186_187.Q_flow = TC_186_187.G * TC_186_187.dT; TC_186_187.dT = TC_186_187.port_a.T - TC_186_187.port_b.T; TC_186_187.port_a.Q_flow = TC_186_187.Q_flow; TC_186_187.port_b.Q_flow = -TC_186_187.Q_flow; TC_186_199.Q_flow = TC_186_199.G * TC_186_199.dT; TC_186_199.dT = TC_186_199.port_a.T - TC_186_199.port_b.T; TC_186_199.port_a.Q_flow = TC_186_199.Q_flow; TC_186_199.port_b.Q_flow = -TC_186_199.Q_flow; TC_186_1452.Q_flow = TC_186_1452.G * TC_186_1452.dT; TC_186_1452.dT = TC_186_1452.port_a.T - TC_186_1452.port_b.T; TC_186_1452.port_a.Q_flow = TC_186_1452.Q_flow; TC_186_1452.port_b.Q_flow = -TC_186_1452.Q_flow; TC_187_188.Q_flow = TC_187_188.G * TC_187_188.dT; TC_187_188.dT = TC_187_188.port_a.T - TC_187_188.port_b.T; TC_187_188.port_a.Q_flow = TC_187_188.Q_flow; TC_187_188.port_b.Q_flow = -TC_187_188.Q_flow; TC_187_200.Q_flow = TC_187_200.G * TC_187_200.dT; TC_187_200.dT = TC_187_200.port_a.T - TC_187_200.port_b.T; TC_187_200.port_a.Q_flow = TC_187_200.Q_flow; TC_187_200.port_b.Q_flow = -TC_187_200.Q_flow; TC_187_1453.Q_flow = TC_187_1453.G * TC_187_1453.dT; TC_187_1453.dT = TC_187_1453.port_a.T - TC_187_1453.port_b.T; TC_187_1453.port_a.Q_flow = TC_187_1453.Q_flow; TC_187_1453.port_b.Q_flow = -TC_187_1453.Q_flow; TC_188_189.Q_flow = TC_188_189.G * TC_188_189.dT; TC_188_189.dT = TC_188_189.port_a.T - TC_188_189.port_b.T; TC_188_189.port_a.Q_flow = TC_188_189.Q_flow; TC_188_189.port_b.Q_flow = -TC_188_189.Q_flow; TC_188_201.Q_flow = TC_188_201.G * TC_188_201.dT; TC_188_201.dT = TC_188_201.port_a.T - TC_188_201.port_b.T; TC_188_201.port_a.Q_flow = TC_188_201.Q_flow; TC_188_201.port_b.Q_flow = -TC_188_201.Q_flow; TC_188_1454.Q_flow = TC_188_1454.G * TC_188_1454.dT; TC_188_1454.dT = TC_188_1454.port_a.T - TC_188_1454.port_b.T; TC_188_1454.port_a.Q_flow = TC_188_1454.Q_flow; TC_188_1454.port_b.Q_flow = -TC_188_1454.Q_flow; TC_189_190.Q_flow = TC_189_190.G * TC_189_190.dT; TC_189_190.dT = TC_189_190.port_a.T - TC_189_190.port_b.T; TC_189_190.port_a.Q_flow = TC_189_190.Q_flow; TC_189_190.port_b.Q_flow = -TC_189_190.Q_flow; TC_189_202.Q_flow = TC_189_202.G * TC_189_202.dT; TC_189_202.dT = TC_189_202.port_a.T - TC_189_202.port_b.T; TC_189_202.port_a.Q_flow = TC_189_202.Q_flow; TC_189_202.port_b.Q_flow = -TC_189_202.Q_flow; TC_189_1455.Q_flow = TC_189_1455.G * TC_189_1455.dT; TC_189_1455.dT = TC_189_1455.port_a.T - TC_189_1455.port_b.T; TC_189_1455.port_a.Q_flow = TC_189_1455.Q_flow; TC_189_1455.port_b.Q_flow = -TC_189_1455.Q_flow; TC_190_191.Q_flow = TC_190_191.G * TC_190_191.dT; TC_190_191.dT = TC_190_191.port_a.T - TC_190_191.port_b.T; TC_190_191.port_a.Q_flow = TC_190_191.Q_flow; TC_190_191.port_b.Q_flow = -TC_190_191.Q_flow; TC_190_203.Q_flow = TC_190_203.G * TC_190_203.dT; TC_190_203.dT = TC_190_203.port_a.T - TC_190_203.port_b.T; TC_190_203.port_a.Q_flow = TC_190_203.Q_flow; TC_190_203.port_b.Q_flow = -TC_190_203.Q_flow; TC_190_1456.Q_flow = TC_190_1456.G * TC_190_1456.dT; TC_190_1456.dT = TC_190_1456.port_a.T - TC_190_1456.port_b.T; TC_190_1456.port_a.Q_flow = TC_190_1456.Q_flow; TC_190_1456.port_b.Q_flow = -TC_190_1456.Q_flow; TC_191_192.Q_flow = TC_191_192.G * TC_191_192.dT; TC_191_192.dT = TC_191_192.port_a.T - TC_191_192.port_b.T; TC_191_192.port_a.Q_flow = TC_191_192.Q_flow; TC_191_192.port_b.Q_flow = -TC_191_192.Q_flow; TC_191_204.Q_flow = TC_191_204.G * TC_191_204.dT; TC_191_204.dT = TC_191_204.port_a.T - TC_191_204.port_b.T; TC_191_204.port_a.Q_flow = TC_191_204.Q_flow; TC_191_204.port_b.Q_flow = -TC_191_204.Q_flow; TC_191_1457.Q_flow = TC_191_1457.G * TC_191_1457.dT; TC_191_1457.dT = TC_191_1457.port_a.T - TC_191_1457.port_b.T; TC_191_1457.port_a.Q_flow = TC_191_1457.Q_flow; TC_191_1457.port_b.Q_flow = -TC_191_1457.Q_flow; TC_192_193.Q_flow = TC_192_193.G * TC_192_193.dT; TC_192_193.dT = TC_192_193.port_a.T - TC_192_193.port_b.T; TC_192_193.port_a.Q_flow = TC_192_193.Q_flow; TC_192_193.port_b.Q_flow = -TC_192_193.Q_flow; TC_192_205.Q_flow = TC_192_205.G * TC_192_205.dT; TC_192_205.dT = TC_192_205.port_a.T - TC_192_205.port_b.T; TC_192_205.port_a.Q_flow = TC_192_205.Q_flow; TC_192_205.port_b.Q_flow = -TC_192_205.Q_flow; TC_192_1458.Q_flow = TC_192_1458.G * TC_192_1458.dT; TC_192_1458.dT = TC_192_1458.port_a.T - TC_192_1458.port_b.T; TC_192_1458.port_a.Q_flow = TC_192_1458.Q_flow; TC_192_1458.port_b.Q_flow = -TC_192_1458.Q_flow; TC_193_194.Q_flow = TC_193_194.G * TC_193_194.dT; TC_193_194.dT = TC_193_194.port_a.T - TC_193_194.port_b.T; TC_193_194.port_a.Q_flow = TC_193_194.Q_flow; TC_193_194.port_b.Q_flow = -TC_193_194.Q_flow; TC_193_206.Q_flow = TC_193_206.G * TC_193_206.dT; TC_193_206.dT = TC_193_206.port_a.T - TC_193_206.port_b.T; TC_193_206.port_a.Q_flow = TC_193_206.Q_flow; TC_193_206.port_b.Q_flow = -TC_193_206.Q_flow; TC_193_1459.Q_flow = TC_193_1459.G * TC_193_1459.dT; TC_193_1459.dT = TC_193_1459.port_a.T - TC_193_1459.port_b.T; TC_193_1459.port_a.Q_flow = TC_193_1459.Q_flow; TC_193_1459.port_b.Q_flow = -TC_193_1459.Q_flow; TC_194_195.Q_flow = TC_194_195.G * TC_194_195.dT; TC_194_195.dT = TC_194_195.port_a.T - TC_194_195.port_b.T; TC_194_195.port_a.Q_flow = TC_194_195.Q_flow; TC_194_195.port_b.Q_flow = -TC_194_195.Q_flow; TC_194_207.Q_flow = TC_194_207.G * TC_194_207.dT; TC_194_207.dT = TC_194_207.port_a.T - TC_194_207.port_b.T; TC_194_207.port_a.Q_flow = TC_194_207.Q_flow; TC_194_207.port_b.Q_flow = -TC_194_207.Q_flow; TC_194_1460.Q_flow = TC_194_1460.G * TC_194_1460.dT; TC_194_1460.dT = TC_194_1460.port_a.T - TC_194_1460.port_b.T; TC_194_1460.port_a.Q_flow = TC_194_1460.Q_flow; TC_194_1460.port_b.Q_flow = -TC_194_1460.Q_flow; TC_195_208.Q_flow = TC_195_208.G * TC_195_208.dT; TC_195_208.dT = TC_195_208.port_a.T - TC_195_208.port_b.T; TC_195_208.port_a.Q_flow = TC_195_208.Q_flow; TC_195_208.port_b.Q_flow = -TC_195_208.Q_flow; TC_195_248.Q_flow = TC_195_248.G * TC_195_248.dT; TC_195_248.dT = TC_195_248.port_a.T - TC_195_248.port_b.T; TC_195_248.port_a.Q_flow = TC_195_248.Q_flow; TC_195_248.port_b.Q_flow = -TC_195_248.Q_flow; TC_196_197.Q_flow = TC_196_197.G * TC_196_197.dT; TC_196_197.dT = TC_196_197.port_a.T - TC_196_197.port_b.T; TC_196_197.port_a.Q_flow = TC_196_197.Q_flow; TC_196_197.port_b.Q_flow = -TC_196_197.Q_flow; TC_196_249.Q_flow = TC_196_249.G * TC_196_249.dT; TC_196_249.dT = TC_196_249.port_a.T - TC_196_249.port_b.T; TC_196_249.port_a.Q_flow = TC_196_249.Q_flow; TC_196_249.port_b.Q_flow = -TC_196_249.Q_flow; TC_197_198.Q_flow = TC_197_198.G * TC_197_198.dT; TC_197_198.dT = TC_197_198.port_a.T - TC_197_198.port_b.T; TC_197_198.port_a.Q_flow = TC_197_198.Q_flow; TC_197_198.port_b.Q_flow = -TC_197_198.Q_flow; TC_197_250.Q_flow = TC_197_250.G * TC_197_250.dT; TC_197_250.dT = TC_197_250.port_a.T - TC_197_250.port_b.T; TC_197_250.port_a.Q_flow = TC_197_250.Q_flow; TC_197_250.port_b.Q_flow = -TC_197_250.Q_flow; TC_198_199.Q_flow = TC_198_199.G * TC_198_199.dT; TC_198_199.dT = TC_198_199.port_a.T - TC_198_199.port_b.T; TC_198_199.port_a.Q_flow = TC_198_199.Q_flow; TC_198_199.port_b.Q_flow = -TC_198_199.Q_flow; TC_198_251.Q_flow = TC_198_251.G * TC_198_251.dT; TC_198_251.dT = TC_198_251.port_a.T - TC_198_251.port_b.T; TC_198_251.port_a.Q_flow = TC_198_251.Q_flow; TC_198_251.port_b.Q_flow = -TC_198_251.Q_flow; TC_199_200.Q_flow = TC_199_200.G * TC_199_200.dT; TC_199_200.dT = TC_199_200.port_a.T - TC_199_200.port_b.T; TC_199_200.port_a.Q_flow = TC_199_200.Q_flow; TC_199_200.port_b.Q_flow = -TC_199_200.Q_flow; TC_199_252.Q_flow = TC_199_252.G * TC_199_252.dT; TC_199_252.dT = TC_199_252.port_a.T - TC_199_252.port_b.T; TC_199_252.port_a.Q_flow = TC_199_252.Q_flow; TC_199_252.port_b.Q_flow = -TC_199_252.Q_flow; TC_200_201.Q_flow = TC_200_201.G * TC_200_201.dT; TC_200_201.dT = TC_200_201.port_a.T - TC_200_201.port_b.T; TC_200_201.port_a.Q_flow = TC_200_201.Q_flow; TC_200_201.port_b.Q_flow = -TC_200_201.Q_flow; TC_200_253.Q_flow = TC_200_253.G * TC_200_253.dT; TC_200_253.dT = TC_200_253.port_a.T - TC_200_253.port_b.T; TC_200_253.port_a.Q_flow = TC_200_253.Q_flow; TC_200_253.port_b.Q_flow = -TC_200_253.Q_flow; TC_201_202.Q_flow = TC_201_202.G * TC_201_202.dT; TC_201_202.dT = TC_201_202.port_a.T - TC_201_202.port_b.T; TC_201_202.port_a.Q_flow = TC_201_202.Q_flow; TC_201_202.port_b.Q_flow = -TC_201_202.Q_flow; TC_201_254.Q_flow = TC_201_254.G * TC_201_254.dT; TC_201_254.dT = TC_201_254.port_a.T - TC_201_254.port_b.T; TC_201_254.port_a.Q_flow = TC_201_254.Q_flow; TC_201_254.port_b.Q_flow = -TC_201_254.Q_flow; TC_202_203.Q_flow = TC_202_203.G * TC_202_203.dT; TC_202_203.dT = TC_202_203.port_a.T - TC_202_203.port_b.T; TC_202_203.port_a.Q_flow = TC_202_203.Q_flow; TC_202_203.port_b.Q_flow = -TC_202_203.Q_flow; TC_202_255.Q_flow = TC_202_255.G * TC_202_255.dT; TC_202_255.dT = TC_202_255.port_a.T - TC_202_255.port_b.T; TC_202_255.port_a.Q_flow = TC_202_255.Q_flow; TC_202_255.port_b.Q_flow = -TC_202_255.Q_flow; TC_203_204.Q_flow = TC_203_204.G * TC_203_204.dT; TC_203_204.dT = TC_203_204.port_a.T - TC_203_204.port_b.T; TC_203_204.port_a.Q_flow = TC_203_204.Q_flow; TC_203_204.port_b.Q_flow = -TC_203_204.Q_flow; TC_203_256.Q_flow = TC_203_256.G * TC_203_256.dT; TC_203_256.dT = TC_203_256.port_a.T - TC_203_256.port_b.T; TC_203_256.port_a.Q_flow = TC_203_256.Q_flow; TC_203_256.port_b.Q_flow = -TC_203_256.Q_flow; TC_204_205.Q_flow = TC_204_205.G * TC_204_205.dT; TC_204_205.dT = TC_204_205.port_a.T - TC_204_205.port_b.T; TC_204_205.port_a.Q_flow = TC_204_205.Q_flow; TC_204_205.port_b.Q_flow = -TC_204_205.Q_flow; TC_204_257.Q_flow = TC_204_257.G * TC_204_257.dT; TC_204_257.dT = TC_204_257.port_a.T - TC_204_257.port_b.T; TC_204_257.port_a.Q_flow = TC_204_257.Q_flow; TC_204_257.port_b.Q_flow = -TC_204_257.Q_flow; TC_205_206.Q_flow = TC_205_206.G * TC_205_206.dT; TC_205_206.dT = TC_205_206.port_a.T - TC_205_206.port_b.T; TC_205_206.port_a.Q_flow = TC_205_206.Q_flow; TC_205_206.port_b.Q_flow = -TC_205_206.Q_flow; TC_205_258.Q_flow = TC_205_258.G * TC_205_258.dT; TC_205_258.dT = TC_205_258.port_a.T - TC_205_258.port_b.T; TC_205_258.port_a.Q_flow = TC_205_258.Q_flow; TC_205_258.port_b.Q_flow = -TC_205_258.Q_flow; TC_206_207.Q_flow = TC_206_207.G * TC_206_207.dT; TC_206_207.dT = TC_206_207.port_a.T - TC_206_207.port_b.T; TC_206_207.port_a.Q_flow = TC_206_207.Q_flow; TC_206_207.port_b.Q_flow = -TC_206_207.Q_flow; TC_206_259.Q_flow = TC_206_259.G * TC_206_259.dT; TC_206_259.dT = TC_206_259.port_a.T - TC_206_259.port_b.T; TC_206_259.port_a.Q_flow = TC_206_259.Q_flow; TC_206_259.port_b.Q_flow = -TC_206_259.Q_flow; TC_207_208.Q_flow = TC_207_208.G * TC_207_208.dT; TC_207_208.dT = TC_207_208.port_a.T - TC_207_208.port_b.T; TC_207_208.port_a.Q_flow = TC_207_208.Q_flow; TC_207_208.port_b.Q_flow = -TC_207_208.Q_flow; TC_207_260.Q_flow = TC_207_260.G * TC_207_260.dT; TC_207_260.dT = TC_207_260.port_a.T - TC_207_260.port_b.T; TC_207_260.port_a.Q_flow = TC_207_260.Q_flow; TC_207_260.port_b.Q_flow = -TC_207_260.Q_flow; TC_208_261.Q_flow = TC_208_261.G * TC_208_261.dT; TC_208_261.dT = TC_208_261.port_a.T - TC_208_261.port_b.T; TC_208_261.port_a.Q_flow = TC_208_261.Q_flow; TC_208_261.port_b.Q_flow = -TC_208_261.Q_flow; TC_209_210.Q_flow = TC_209_210.G * TC_209_210.dT; TC_209_210.dT = TC_209_210.port_a.T - TC_209_210.port_b.T; TC_209_210.port_a.Q_flow = TC_209_210.Q_flow; TC_209_210.port_b.Q_flow = -TC_209_210.Q_flow; TC_209_371.Q_flow = TC_209_371.G * TC_209_371.dT; TC_209_371.dT = TC_209_371.port_a.T - TC_209_371.port_b.T; TC_209_371.port_a.Q_flow = TC_209_371.Q_flow; TC_209_371.port_b.Q_flow = -TC_209_371.Q_flow; TC_209_424.Q_flow = TC_209_424.G * TC_209_424.dT; TC_209_424.dT = TC_209_424.port_a.T - TC_209_424.port_b.T; TC_209_424.port_a.Q_flow = TC_209_424.Q_flow; TC_209_424.port_b.Q_flow = -TC_209_424.Q_flow; TC_209_1477.Q_flow = TC_209_1477.G * TC_209_1477.dT; TC_209_1477.dT = TC_209_1477.port_a.T - TC_209_1477.port_b.T; TC_209_1477.port_a.Q_flow = TC_209_1477.Q_flow; TC_209_1477.port_b.Q_flow = -TC_209_1477.Q_flow; TC_210_211.Q_flow = TC_210_211.G * TC_210_211.dT; TC_210_211.dT = TC_210_211.port_a.T - TC_210_211.port_b.T; TC_210_211.port_a.Q_flow = TC_210_211.Q_flow; TC_210_211.port_b.Q_flow = -TC_210_211.Q_flow; TC_210_372.Q_flow = TC_210_372.G * TC_210_372.dT; TC_210_372.dT = TC_210_372.port_a.T - TC_210_372.port_b.T; TC_210_372.port_a.Q_flow = TC_210_372.Q_flow; TC_210_372.port_b.Q_flow = -TC_210_372.Q_flow; TC_210_1478.Q_flow = TC_210_1478.G * TC_210_1478.dT; TC_210_1478.dT = TC_210_1478.port_a.T - TC_210_1478.port_b.T; TC_210_1478.port_a.Q_flow = TC_210_1478.Q_flow; TC_210_1478.port_b.Q_flow = -TC_210_1478.Q_flow; TC_211_212.Q_flow = TC_211_212.G * TC_211_212.dT; TC_211_212.dT = TC_211_212.port_a.T - TC_211_212.port_b.T; TC_211_212.port_a.Q_flow = TC_211_212.Q_flow; TC_211_212.port_b.Q_flow = -TC_211_212.Q_flow; TC_211_373.Q_flow = TC_211_373.G * TC_211_373.dT; TC_211_373.dT = TC_211_373.port_a.T - TC_211_373.port_b.T; TC_211_373.port_a.Q_flow = TC_211_373.Q_flow; TC_211_373.port_b.Q_flow = -TC_211_373.Q_flow; TC_211_1479.Q_flow = TC_211_1479.G * TC_211_1479.dT; TC_211_1479.dT = TC_211_1479.port_a.T - TC_211_1479.port_b.T; TC_211_1479.port_a.Q_flow = TC_211_1479.Q_flow; TC_211_1479.port_b.Q_flow = -TC_211_1479.Q_flow; TC_212_213.Q_flow = TC_212_213.G * TC_212_213.dT; TC_212_213.dT = TC_212_213.port_a.T - TC_212_213.port_b.T; TC_212_213.port_a.Q_flow = TC_212_213.Q_flow; TC_212_213.port_b.Q_flow = -TC_212_213.Q_flow; TC_212_374.Q_flow = TC_212_374.G * TC_212_374.dT; TC_212_374.dT = TC_212_374.port_a.T - TC_212_374.port_b.T; TC_212_374.port_a.Q_flow = TC_212_374.Q_flow; TC_212_374.port_b.Q_flow = -TC_212_374.Q_flow; TC_212_1480.Q_flow = TC_212_1480.G * TC_212_1480.dT; TC_212_1480.dT = TC_212_1480.port_a.T - TC_212_1480.port_b.T; TC_212_1480.port_a.Q_flow = TC_212_1480.Q_flow; TC_212_1480.port_b.Q_flow = -TC_212_1480.Q_flow; TC_213_214.Q_flow = TC_213_214.G * TC_213_214.dT; TC_213_214.dT = TC_213_214.port_a.T - TC_213_214.port_b.T; TC_213_214.port_a.Q_flow = TC_213_214.Q_flow; TC_213_214.port_b.Q_flow = -TC_213_214.Q_flow; TC_213_375.Q_flow = TC_213_375.G * TC_213_375.dT; TC_213_375.dT = TC_213_375.port_a.T - TC_213_375.port_b.T; TC_213_375.port_a.Q_flow = TC_213_375.Q_flow; TC_213_375.port_b.Q_flow = -TC_213_375.Q_flow; TC_213_1481.Q_flow = TC_213_1481.G * TC_213_1481.dT; TC_213_1481.dT = TC_213_1481.port_a.T - TC_213_1481.port_b.T; TC_213_1481.port_a.Q_flow = TC_213_1481.Q_flow; TC_213_1481.port_b.Q_flow = -TC_213_1481.Q_flow; TC_214_215.Q_flow = TC_214_215.G * TC_214_215.dT; TC_214_215.dT = TC_214_215.port_a.T - TC_214_215.port_b.T; TC_214_215.port_a.Q_flow = TC_214_215.Q_flow; TC_214_215.port_b.Q_flow = -TC_214_215.Q_flow; TC_214_376.Q_flow = TC_214_376.G * TC_214_376.dT; TC_214_376.dT = TC_214_376.port_a.T - TC_214_376.port_b.T; TC_214_376.port_a.Q_flow = TC_214_376.Q_flow; TC_214_376.port_b.Q_flow = -TC_214_376.Q_flow; TC_214_1482.Q_flow = TC_214_1482.G * TC_214_1482.dT; TC_214_1482.dT = TC_214_1482.port_a.T - TC_214_1482.port_b.T; TC_214_1482.port_a.Q_flow = TC_214_1482.Q_flow; TC_214_1482.port_b.Q_flow = -TC_214_1482.Q_flow; TC_215_216.Q_flow = TC_215_216.G * TC_215_216.dT; TC_215_216.dT = TC_215_216.port_a.T - TC_215_216.port_b.T; TC_215_216.port_a.Q_flow = TC_215_216.Q_flow; TC_215_216.port_b.Q_flow = -TC_215_216.Q_flow; TC_215_377.Q_flow = TC_215_377.G * TC_215_377.dT; TC_215_377.dT = TC_215_377.port_a.T - TC_215_377.port_b.T; TC_215_377.port_a.Q_flow = TC_215_377.Q_flow; TC_215_377.port_b.Q_flow = -TC_215_377.Q_flow; TC_215_1483.Q_flow = TC_215_1483.G * TC_215_1483.dT; TC_215_1483.dT = TC_215_1483.port_a.T - TC_215_1483.port_b.T; TC_215_1483.port_a.Q_flow = TC_215_1483.Q_flow; TC_215_1483.port_b.Q_flow = -TC_215_1483.Q_flow; TC_216_217.Q_flow = TC_216_217.G * TC_216_217.dT; TC_216_217.dT = TC_216_217.port_a.T - TC_216_217.port_b.T; TC_216_217.port_a.Q_flow = TC_216_217.Q_flow; TC_216_217.port_b.Q_flow = -TC_216_217.Q_flow; TC_216_378.Q_flow = TC_216_378.G * TC_216_378.dT; TC_216_378.dT = TC_216_378.port_a.T - TC_216_378.port_b.T; TC_216_378.port_a.Q_flow = TC_216_378.Q_flow; TC_216_378.port_b.Q_flow = -TC_216_378.Q_flow; TC_216_1484.Q_flow = TC_216_1484.G * TC_216_1484.dT; TC_216_1484.dT = TC_216_1484.port_a.T - TC_216_1484.port_b.T; TC_216_1484.port_a.Q_flow = TC_216_1484.Q_flow; TC_216_1484.port_b.Q_flow = -TC_216_1484.Q_flow; TC_217_218.Q_flow = TC_217_218.G * TC_217_218.dT; TC_217_218.dT = TC_217_218.port_a.T - TC_217_218.port_b.T; TC_217_218.port_a.Q_flow = TC_217_218.Q_flow; TC_217_218.port_b.Q_flow = -TC_217_218.Q_flow; TC_217_379.Q_flow = TC_217_379.G * TC_217_379.dT; TC_217_379.dT = TC_217_379.port_a.T - TC_217_379.port_b.T; TC_217_379.port_a.Q_flow = TC_217_379.Q_flow; TC_217_379.port_b.Q_flow = -TC_217_379.Q_flow; TC_217_1485.Q_flow = TC_217_1485.G * TC_217_1485.dT; TC_217_1485.dT = TC_217_1485.port_a.T - TC_217_1485.port_b.T; TC_217_1485.port_a.Q_flow = TC_217_1485.Q_flow; TC_217_1485.port_b.Q_flow = -TC_217_1485.Q_flow; TC_218_219.Q_flow = TC_218_219.G * TC_218_219.dT; TC_218_219.dT = TC_218_219.port_a.T - TC_218_219.port_b.T; TC_218_219.port_a.Q_flow = TC_218_219.Q_flow; TC_218_219.port_b.Q_flow = -TC_218_219.Q_flow; TC_218_380.Q_flow = TC_218_380.G * TC_218_380.dT; TC_218_380.dT = TC_218_380.port_a.T - TC_218_380.port_b.T; TC_218_380.port_a.Q_flow = TC_218_380.Q_flow; TC_218_380.port_b.Q_flow = -TC_218_380.Q_flow; TC_218_1486.Q_flow = TC_218_1486.G * TC_218_1486.dT; TC_218_1486.dT = TC_218_1486.port_a.T - TC_218_1486.port_b.T; TC_218_1486.port_a.Q_flow = TC_218_1486.Q_flow; TC_218_1486.port_b.Q_flow = -TC_218_1486.Q_flow; TC_219_220.Q_flow = TC_219_220.G * TC_219_220.dT; TC_219_220.dT = TC_219_220.port_a.T - TC_219_220.port_b.T; TC_219_220.port_a.Q_flow = TC_219_220.Q_flow; TC_219_220.port_b.Q_flow = -TC_219_220.Q_flow; TC_219_381.Q_flow = TC_219_381.G * TC_219_381.dT; TC_219_381.dT = TC_219_381.port_a.T - TC_219_381.port_b.T; TC_219_381.port_a.Q_flow = TC_219_381.Q_flow; TC_219_381.port_b.Q_flow = -TC_219_381.Q_flow; TC_219_1487.Q_flow = TC_219_1487.G * TC_219_1487.dT; TC_219_1487.dT = TC_219_1487.port_a.T - TC_219_1487.port_b.T; TC_219_1487.port_a.Q_flow = TC_219_1487.Q_flow; TC_219_1487.port_b.Q_flow = -TC_219_1487.Q_flow; TC_220_222.Q_flow = TC_220_222.G * TC_220_222.dT; TC_220_222.dT = TC_220_222.port_a.T - TC_220_222.port_b.T; TC_220_222.port_a.Q_flow = TC_220_222.Q_flow; TC_220_222.port_b.Q_flow = -TC_220_222.Q_flow; TC_220_382.Q_flow = TC_220_382.G * TC_220_382.dT; TC_220_382.dT = TC_220_382.port_a.T - TC_220_382.port_b.T; TC_220_382.port_a.Q_flow = TC_220_382.Q_flow; TC_220_382.port_b.Q_flow = -TC_220_382.Q_flow; TC_221_223.Q_flow = TC_221_223.G * TC_221_223.dT; TC_221_223.dT = TC_221_223.port_a.T - TC_221_223.port_b.T; TC_221_223.port_a.Q_flow = TC_221_223.Q_flow; TC_221_223.port_b.Q_flow = -TC_221_223.Q_flow; TC_221_383.Q_flow = TC_221_383.G * TC_221_383.dT; TC_221_383.dT = TC_221_383.port_a.T - TC_221_383.port_b.T; TC_221_383.port_a.Q_flow = TC_221_383.Q_flow; TC_221_383.port_b.Q_flow = -TC_221_383.Q_flow; TC_221_424.Q_flow = TC_221_424.G * TC_221_424.dT; TC_221_424.dT = TC_221_424.port_a.T - TC_221_424.port_b.T; TC_221_424.port_a.Q_flow = TC_221_424.Q_flow; TC_221_424.port_b.Q_flow = -TC_221_424.Q_flow; TC_221_1477.Q_flow = TC_221_1477.G * TC_221_1477.dT; TC_221_1477.dT = TC_221_1477.port_a.T - TC_221_1477.port_b.T; TC_221_1477.port_a.Q_flow = TC_221_1477.Q_flow; TC_221_1477.port_b.Q_flow = -TC_221_1477.Q_flow; TC_222_224.Q_flow = TC_222_224.G * TC_222_224.dT; TC_222_224.dT = TC_222_224.port_a.T - TC_222_224.port_b.T; TC_222_224.port_a.Q_flow = TC_222_224.Q_flow; TC_222_224.port_b.Q_flow = -TC_222_224.Q_flow; TC_222_384.Q_flow = TC_222_384.G * TC_222_384.dT; TC_222_384.dT = TC_222_384.port_a.T - TC_222_384.port_b.T; TC_222_384.port_a.Q_flow = TC_222_384.Q_flow; TC_222_384.port_b.Q_flow = -TC_222_384.Q_flow; TC_222_1487.Q_flow = TC_222_1487.G * TC_222_1487.dT; TC_222_1487.dT = TC_222_1487.port_a.T - TC_222_1487.port_b.T; TC_222_1487.port_a.Q_flow = TC_222_1487.Q_flow; TC_222_1487.port_b.Q_flow = -TC_222_1487.Q_flow; TC_223_225.Q_flow = TC_223_225.G * TC_223_225.dT; TC_223_225.dT = TC_223_225.port_a.T - TC_223_225.port_b.T; TC_223_225.port_a.Q_flow = TC_223_225.Q_flow; TC_223_225.port_b.Q_flow = -TC_223_225.Q_flow; TC_223_385.Q_flow = TC_223_385.G * TC_223_385.dT; TC_223_385.dT = TC_223_385.port_a.T - TC_223_385.port_b.T; TC_223_385.port_a.Q_flow = TC_223_385.Q_flow; TC_223_385.port_b.Q_flow = -TC_223_385.Q_flow; TC_223_1466.Q_flow = TC_223_1466.G * TC_223_1466.dT; TC_223_1466.dT = TC_223_1466.port_a.T - TC_223_1466.port_b.T; TC_223_1466.port_a.Q_flow = TC_223_1466.Q_flow; TC_223_1466.port_b.Q_flow = -TC_223_1466.Q_flow; TC_224_226.Q_flow = TC_224_226.G * TC_224_226.dT; TC_224_226.dT = TC_224_226.port_a.T - TC_224_226.port_b.T; TC_224_226.port_a.Q_flow = TC_224_226.Q_flow; TC_224_226.port_b.Q_flow = -TC_224_226.Q_flow; TC_224_386.Q_flow = TC_224_386.G * TC_224_386.dT; TC_224_386.dT = TC_224_386.port_a.T - TC_224_386.port_b.T; TC_224_386.port_a.Q_flow = TC_224_386.Q_flow; TC_224_386.port_b.Q_flow = -TC_224_386.Q_flow; TC_224_1476.Q_flow = TC_224_1476.G * TC_224_1476.dT; TC_224_1476.dT = TC_224_1476.port_a.T - TC_224_1476.port_b.T; TC_224_1476.port_a.Q_flow = TC_224_1476.Q_flow; TC_224_1476.port_b.Q_flow = -TC_224_1476.Q_flow; TC_225_227.Q_flow = TC_225_227.G * TC_225_227.dT; TC_225_227.dT = TC_225_227.port_a.T - TC_225_227.port_b.T; TC_225_227.port_a.Q_flow = TC_225_227.Q_flow; TC_225_227.port_b.Q_flow = -TC_225_227.Q_flow; TC_225_387.Q_flow = TC_225_387.G * TC_225_387.dT; TC_225_387.dT = TC_225_387.port_a.T - TC_225_387.port_b.T; TC_225_387.port_a.Q_flow = TC_225_387.Q_flow; TC_225_387.port_b.Q_flow = -TC_225_387.Q_flow; TC_225_1461.Q_flow = TC_225_1461.G * TC_225_1461.dT; TC_225_1461.dT = TC_225_1461.port_a.T - TC_225_1461.port_b.T; TC_225_1461.port_a.Q_flow = TC_225_1461.Q_flow; TC_225_1461.port_b.Q_flow = -TC_225_1461.Q_flow; TC_226_228.Q_flow = TC_226_228.G * TC_226_228.dT; TC_226_228.dT = TC_226_228.port_a.T - TC_226_228.port_b.T; TC_226_228.port_a.Q_flow = TC_226_228.Q_flow; TC_226_228.port_b.Q_flow = -TC_226_228.Q_flow; TC_226_388.Q_flow = TC_226_388.G * TC_226_388.dT; TC_226_388.dT = TC_226_388.port_a.T - TC_226_388.port_b.T; TC_226_388.port_a.Q_flow = TC_226_388.Q_flow; TC_226_388.port_b.Q_flow = -TC_226_388.Q_flow; TC_226_1463.Q_flow = TC_226_1463.G * TC_226_1463.dT; TC_226_1463.dT = TC_226_1463.port_a.T - TC_226_1463.port_b.T; TC_226_1463.port_a.Q_flow = TC_226_1463.Q_flow; TC_226_1463.port_b.Q_flow = -TC_226_1463.Q_flow; TC_227_229.Q_flow = TC_227_229.G * TC_227_229.dT; TC_227_229.dT = TC_227_229.port_a.T - TC_227_229.port_b.T; TC_227_229.port_a.Q_flow = TC_227_229.Q_flow; TC_227_229.port_b.Q_flow = -TC_227_229.Q_flow; TC_227_389.Q_flow = TC_227_389.G * TC_227_389.dT; TC_227_389.dT = TC_227_389.port_a.T - TC_227_389.port_b.T; TC_227_389.port_a.Q_flow = TC_227_389.Q_flow; TC_227_389.port_b.Q_flow = -TC_227_389.Q_flow; TC_227_1464.Q_flow = TC_227_1464.G * TC_227_1464.dT; TC_227_1464.dT = TC_227_1464.port_a.T - TC_227_1464.port_b.T; TC_227_1464.port_a.Q_flow = TC_227_1464.Q_flow; TC_227_1464.port_b.Q_flow = -TC_227_1464.Q_flow; TC_228_230.Q_flow = TC_228_230.G * TC_228_230.dT; TC_228_230.dT = TC_228_230.port_a.T - TC_228_230.port_b.T; TC_228_230.port_a.Q_flow = TC_228_230.Q_flow; TC_228_230.port_b.Q_flow = -TC_228_230.Q_flow; TC_228_390.Q_flow = TC_228_390.G * TC_228_390.dT; TC_228_390.dT = TC_228_390.port_a.T - TC_228_390.port_b.T; TC_228_390.port_a.Q_flow = TC_228_390.Q_flow; TC_228_390.port_b.Q_flow = -TC_228_390.Q_flow; TC_228_1414.Q_flow = TC_228_1414.G * TC_228_1414.dT; TC_228_1414.dT = TC_228_1414.port_a.T - TC_228_1414.port_b.T; TC_228_1414.port_a.Q_flow = TC_228_1414.Q_flow; TC_228_1414.port_b.Q_flow = -TC_228_1414.Q_flow; TC_229_231.Q_flow = TC_229_231.G * TC_229_231.dT; TC_229_231.dT = TC_229_231.port_a.T - TC_229_231.port_b.T; TC_229_231.port_a.Q_flow = TC_229_231.Q_flow; TC_229_231.port_b.Q_flow = -TC_229_231.Q_flow; TC_229_391.Q_flow = TC_229_391.G * TC_229_391.dT; TC_229_391.dT = TC_229_391.port_a.T - TC_229_391.port_b.T; TC_229_391.port_a.Q_flow = TC_229_391.Q_flow; TC_229_391.port_b.Q_flow = -TC_229_391.Q_flow; TC_229_1415.Q_flow = TC_229_1415.G * TC_229_1415.dT; TC_229_1415.dT = TC_229_1415.port_a.T - TC_229_1415.port_b.T; TC_229_1415.port_a.Q_flow = TC_229_1415.Q_flow; TC_229_1415.port_b.Q_flow = -TC_229_1415.Q_flow; TC_230_232.Q_flow = TC_230_232.G * TC_230_232.dT; TC_230_232.dT = TC_230_232.port_a.T - TC_230_232.port_b.T; TC_230_232.port_a.Q_flow = TC_230_232.Q_flow; TC_230_232.port_b.Q_flow = -TC_230_232.Q_flow; TC_230_392.Q_flow = TC_230_392.G * TC_230_392.dT; TC_230_392.dT = TC_230_392.port_a.T - TC_230_392.port_b.T; TC_230_392.port_a.Q_flow = TC_230_392.Q_flow; TC_230_392.port_b.Q_flow = -TC_230_392.Q_flow; TC_230_1417.Q_flow = TC_230_1417.G * TC_230_1417.dT; TC_230_1417.dT = TC_230_1417.port_a.T - TC_230_1417.port_b.T; TC_230_1417.port_a.Q_flow = TC_230_1417.Q_flow; TC_230_1417.port_b.Q_flow = -TC_230_1417.Q_flow; TC_231_233.Q_flow = TC_231_233.G * TC_231_233.dT; TC_231_233.dT = TC_231_233.port_a.T - TC_231_233.port_b.T; TC_231_233.port_a.Q_flow = TC_231_233.Q_flow; TC_231_233.port_b.Q_flow = -TC_231_233.Q_flow; TC_231_393.Q_flow = TC_231_393.G * TC_231_393.dT; TC_231_393.dT = TC_231_393.port_a.T - TC_231_393.port_b.T; TC_231_393.port_a.Q_flow = TC_231_393.Q_flow; TC_231_393.port_b.Q_flow = -TC_231_393.Q_flow; TC_231_1418.Q_flow = TC_231_1418.G * TC_231_1418.dT; TC_231_1418.dT = TC_231_1418.port_a.T - TC_231_1418.port_b.T; TC_231_1418.port_a.Q_flow = TC_231_1418.Q_flow; TC_231_1418.port_b.Q_flow = -TC_231_1418.Q_flow; TC_232_234.Q_flow = TC_232_234.G * TC_232_234.dT; TC_232_234.dT = TC_232_234.port_a.T - TC_232_234.port_b.T; TC_232_234.port_a.Q_flow = TC_232_234.Q_flow; TC_232_234.port_b.Q_flow = -TC_232_234.Q_flow; TC_232_394.Q_flow = TC_232_394.G * TC_232_394.dT; TC_232_394.dT = TC_232_394.port_a.T - TC_232_394.port_b.T; TC_232_394.port_a.Q_flow = TC_232_394.Q_flow; TC_232_394.port_b.Q_flow = -TC_232_394.Q_flow; TC_232_1420.Q_flow = TC_232_1420.G * TC_232_1420.dT; TC_232_1420.dT = TC_232_1420.port_a.T - TC_232_1420.port_b.T; TC_232_1420.port_a.Q_flow = TC_232_1420.Q_flow; TC_232_1420.port_b.Q_flow = -TC_232_1420.Q_flow; TC_233_235.Q_flow = TC_233_235.G * TC_233_235.dT; TC_233_235.dT = TC_233_235.port_a.T - TC_233_235.port_b.T; TC_233_235.port_a.Q_flow = TC_233_235.Q_flow; TC_233_235.port_b.Q_flow = -TC_233_235.Q_flow; TC_233_395.Q_flow = TC_233_395.G * TC_233_395.dT; TC_233_395.dT = TC_233_395.port_a.T - TC_233_395.port_b.T; TC_233_395.port_a.Q_flow = TC_233_395.Q_flow; TC_233_395.port_b.Q_flow = -TC_233_395.Q_flow; TC_233_1421.Q_flow = TC_233_1421.G * TC_233_1421.dT; TC_233_1421.dT = TC_233_1421.port_a.T - TC_233_1421.port_b.T; TC_233_1421.port_a.Q_flow = TC_233_1421.Q_flow; TC_233_1421.port_b.Q_flow = -TC_233_1421.Q_flow; TC_234_236.Q_flow = TC_234_236.G * TC_234_236.dT; TC_234_236.dT = TC_234_236.port_a.T - TC_234_236.port_b.T; TC_234_236.port_a.Q_flow = TC_234_236.Q_flow; TC_234_236.port_b.Q_flow = -TC_234_236.Q_flow; TC_234_396.Q_flow = TC_234_396.G * TC_234_396.dT; TC_234_396.dT = TC_234_396.port_a.T - TC_234_396.port_b.T; TC_234_396.port_a.Q_flow = TC_234_396.Q_flow; TC_234_396.port_b.Q_flow = -TC_234_396.Q_flow; TC_234_1423.Q_flow = TC_234_1423.G * TC_234_1423.dT; TC_234_1423.dT = TC_234_1423.port_a.T - TC_234_1423.port_b.T; TC_234_1423.port_a.Q_flow = TC_234_1423.Q_flow; TC_234_1423.port_b.Q_flow = -TC_234_1423.Q_flow; TC_235_237.Q_flow = TC_235_237.G * TC_235_237.dT; TC_235_237.dT = TC_235_237.port_a.T - TC_235_237.port_b.T; TC_235_237.port_a.Q_flow = TC_235_237.Q_flow; TC_235_237.port_b.Q_flow = -TC_235_237.Q_flow; TC_235_397.Q_flow = TC_235_397.G * TC_235_397.dT; TC_235_397.dT = TC_235_397.port_a.T - TC_235_397.port_b.T; TC_235_397.port_a.Q_flow = TC_235_397.Q_flow; TC_235_397.port_b.Q_flow = -TC_235_397.Q_flow; TC_235_1424.Q_flow = TC_235_1424.G * TC_235_1424.dT; TC_235_1424.dT = TC_235_1424.port_a.T - TC_235_1424.port_b.T; TC_235_1424.port_a.Q_flow = TC_235_1424.Q_flow; TC_235_1424.port_b.Q_flow = -TC_235_1424.Q_flow; TC_236_238.Q_flow = TC_236_238.G * TC_236_238.dT; TC_236_238.dT = TC_236_238.port_a.T - TC_236_238.port_b.T; TC_236_238.port_a.Q_flow = TC_236_238.Q_flow; TC_236_238.port_b.Q_flow = -TC_236_238.Q_flow; TC_236_398.Q_flow = TC_236_398.G * TC_236_398.dT; TC_236_398.dT = TC_236_398.port_a.T - TC_236_398.port_b.T; TC_236_398.port_a.Q_flow = TC_236_398.Q_flow; TC_236_398.port_b.Q_flow = -TC_236_398.Q_flow; TC_236_1426.Q_flow = TC_236_1426.G * TC_236_1426.dT; TC_236_1426.dT = TC_236_1426.port_a.T - TC_236_1426.port_b.T; TC_236_1426.port_a.Q_flow = TC_236_1426.Q_flow; TC_236_1426.port_b.Q_flow = -TC_236_1426.Q_flow; TC_237_239.Q_flow = TC_237_239.G * TC_237_239.dT; TC_237_239.dT = TC_237_239.port_a.T - TC_237_239.port_b.T; TC_237_239.port_a.Q_flow = TC_237_239.Q_flow; TC_237_239.port_b.Q_flow = -TC_237_239.Q_flow; TC_237_399.Q_flow = TC_237_399.G * TC_237_399.dT; TC_237_399.dT = TC_237_399.port_a.T - TC_237_399.port_b.T; TC_237_399.port_a.Q_flow = TC_237_399.Q_flow; TC_237_399.port_b.Q_flow = -TC_237_399.Q_flow; TC_237_1427.Q_flow = TC_237_1427.G * TC_237_1427.dT; TC_237_1427.dT = TC_237_1427.port_a.T - TC_237_1427.port_b.T; TC_237_1427.port_a.Q_flow = TC_237_1427.Q_flow; TC_237_1427.port_b.Q_flow = -TC_237_1427.Q_flow; TC_238_240.Q_flow = TC_238_240.G * TC_238_240.dT; TC_238_240.dT = TC_238_240.port_a.T - TC_238_240.port_b.T; TC_238_240.port_a.Q_flow = TC_238_240.Q_flow; TC_238_240.port_b.Q_flow = -TC_238_240.Q_flow; TC_238_400.Q_flow = TC_238_400.G * TC_238_400.dT; TC_238_400.dT = TC_238_400.port_a.T - TC_238_400.port_b.T; TC_238_400.port_a.Q_flow = TC_238_400.Q_flow; TC_238_400.port_b.Q_flow = -TC_238_400.Q_flow; TC_238_1429.Q_flow = TC_238_1429.G * TC_238_1429.dT; TC_238_1429.dT = TC_238_1429.port_a.T - TC_238_1429.port_b.T; TC_238_1429.port_a.Q_flow = TC_238_1429.Q_flow; TC_238_1429.port_b.Q_flow = -TC_238_1429.Q_flow; TC_239_241.Q_flow = TC_239_241.G * TC_239_241.dT; TC_239_241.dT = TC_239_241.port_a.T - TC_239_241.port_b.T; TC_239_241.port_a.Q_flow = TC_239_241.Q_flow; TC_239_241.port_b.Q_flow = -TC_239_241.Q_flow; TC_239_401.Q_flow = TC_239_401.G * TC_239_401.dT; TC_239_401.dT = TC_239_401.port_a.T - TC_239_401.port_b.T; TC_239_401.port_a.Q_flow = TC_239_401.Q_flow; TC_239_401.port_b.Q_flow = -TC_239_401.Q_flow; TC_239_1430.Q_flow = TC_239_1430.G * TC_239_1430.dT; TC_239_1430.dT = TC_239_1430.port_a.T - TC_239_1430.port_b.T; TC_239_1430.port_a.Q_flow = TC_239_1430.Q_flow; TC_239_1430.port_b.Q_flow = -TC_239_1430.Q_flow; TC_240_242.Q_flow = TC_240_242.G * TC_240_242.dT; TC_240_242.dT = TC_240_242.port_a.T - TC_240_242.port_b.T; TC_240_242.port_a.Q_flow = TC_240_242.Q_flow; TC_240_242.port_b.Q_flow = -TC_240_242.Q_flow; TC_240_402.Q_flow = TC_240_402.G * TC_240_402.dT; TC_240_402.dT = TC_240_402.port_a.T - TC_240_402.port_b.T; TC_240_402.port_a.Q_flow = TC_240_402.Q_flow; TC_240_402.port_b.Q_flow = -TC_240_402.Q_flow; TC_240_1432.Q_flow = TC_240_1432.G * TC_240_1432.dT; TC_240_1432.dT = TC_240_1432.port_a.T - TC_240_1432.port_b.T; TC_240_1432.port_a.Q_flow = TC_240_1432.Q_flow; TC_240_1432.port_b.Q_flow = -TC_240_1432.Q_flow; TC_241_243.Q_flow = TC_241_243.G * TC_241_243.dT; TC_241_243.dT = TC_241_243.port_a.T - TC_241_243.port_b.T; TC_241_243.port_a.Q_flow = TC_241_243.Q_flow; TC_241_243.port_b.Q_flow = -TC_241_243.Q_flow; TC_241_403.Q_flow = TC_241_403.G * TC_241_403.dT; TC_241_403.dT = TC_241_403.port_a.T - TC_241_403.port_b.T; TC_241_403.port_a.Q_flow = TC_241_403.Q_flow; TC_241_403.port_b.Q_flow = -TC_241_403.Q_flow; TC_241_1433.Q_flow = TC_241_1433.G * TC_241_1433.dT; TC_241_1433.dT = TC_241_1433.port_a.T - TC_241_1433.port_b.T; TC_241_1433.port_a.Q_flow = TC_241_1433.Q_flow; TC_241_1433.port_b.Q_flow = -TC_241_1433.Q_flow; TC_242_244.Q_flow = TC_242_244.G * TC_242_244.dT; TC_242_244.dT = TC_242_244.port_a.T - TC_242_244.port_b.T; TC_242_244.port_a.Q_flow = TC_242_244.Q_flow; TC_242_244.port_b.Q_flow = -TC_242_244.Q_flow; TC_242_404.Q_flow = TC_242_404.G * TC_242_404.dT; TC_242_404.dT = TC_242_404.port_a.T - TC_242_404.port_b.T; TC_242_404.port_a.Q_flow = TC_242_404.Q_flow; TC_242_404.port_b.Q_flow = -TC_242_404.Q_flow; TC_242_1435.Q_flow = TC_242_1435.G * TC_242_1435.dT; TC_242_1435.dT = TC_242_1435.port_a.T - TC_242_1435.port_b.T; TC_242_1435.port_a.Q_flow = TC_242_1435.Q_flow; TC_242_1435.port_b.Q_flow = -TC_242_1435.Q_flow; TC_243_245.Q_flow = TC_243_245.G * TC_243_245.dT; TC_243_245.dT = TC_243_245.port_a.T - TC_243_245.port_b.T; TC_243_245.port_a.Q_flow = TC_243_245.Q_flow; TC_243_245.port_b.Q_flow = -TC_243_245.Q_flow; TC_243_405.Q_flow = TC_243_405.G * TC_243_405.dT; TC_243_405.dT = TC_243_405.port_a.T - TC_243_405.port_b.T; TC_243_405.port_a.Q_flow = TC_243_405.Q_flow; TC_243_405.port_b.Q_flow = -TC_243_405.Q_flow; TC_243_1436.Q_flow = TC_243_1436.G * TC_243_1436.dT; TC_243_1436.dT = TC_243_1436.port_a.T - TC_243_1436.port_b.T; TC_243_1436.port_a.Q_flow = TC_243_1436.Q_flow; TC_243_1436.port_b.Q_flow = -TC_243_1436.Q_flow; TC_244_246.Q_flow = TC_244_246.G * TC_244_246.dT; TC_244_246.dT = TC_244_246.port_a.T - TC_244_246.port_b.T; TC_244_246.port_a.Q_flow = TC_244_246.Q_flow; TC_244_246.port_b.Q_flow = -TC_244_246.Q_flow; TC_244_406.Q_flow = TC_244_406.G * TC_244_406.dT; TC_244_406.dT = TC_244_406.port_a.T - TC_244_406.port_b.T; TC_244_406.port_a.Q_flow = TC_244_406.Q_flow; TC_244_406.port_b.Q_flow = -TC_244_406.Q_flow; TC_244_1438.Q_flow = TC_244_1438.G * TC_244_1438.dT; TC_244_1438.dT = TC_244_1438.port_a.T - TC_244_1438.port_b.T; TC_244_1438.port_a.Q_flow = TC_244_1438.Q_flow; TC_244_1438.port_b.Q_flow = -TC_244_1438.Q_flow; TC_245_247.Q_flow = TC_245_247.G * TC_245_247.dT; TC_245_247.dT = TC_245_247.port_a.T - TC_245_247.port_b.T; TC_245_247.port_a.Q_flow = TC_245_247.Q_flow; TC_245_247.port_b.Q_flow = -TC_245_247.Q_flow; TC_245_407.Q_flow = TC_245_407.G * TC_245_407.dT; TC_245_407.dT = TC_245_407.port_a.T - TC_245_407.port_b.T; TC_245_407.port_a.Q_flow = TC_245_407.Q_flow; TC_245_407.port_b.Q_flow = -TC_245_407.Q_flow; TC_245_1439.Q_flow = TC_245_1439.G * TC_245_1439.dT; TC_245_1439.dT = TC_245_1439.port_a.T - TC_245_1439.port_b.T; TC_245_1439.port_a.Q_flow = TC_245_1439.Q_flow; TC_245_1439.port_b.Q_flow = -TC_245_1439.Q_flow; TC_246_248.Q_flow = TC_246_248.G * TC_246_248.dT; TC_246_248.dT = TC_246_248.port_a.T - TC_246_248.port_b.T; TC_246_248.port_a.Q_flow = TC_246_248.Q_flow; TC_246_248.port_b.Q_flow = -TC_246_248.Q_flow; TC_246_408.Q_flow = TC_246_408.G * TC_246_408.dT; TC_246_408.dT = TC_246_408.port_a.T - TC_246_408.port_b.T; TC_246_408.port_a.Q_flow = TC_246_408.Q_flow; TC_246_408.port_b.Q_flow = -TC_246_408.Q_flow; TC_246_1449.Q_flow = TC_246_1449.G * TC_246_1449.dT; TC_246_1449.dT = TC_246_1449.port_a.T - TC_246_1449.port_b.T; TC_246_1449.port_a.Q_flow = TC_246_1449.Q_flow; TC_246_1449.port_b.Q_flow = -TC_246_1449.Q_flow; TC_247_249.Q_flow = TC_247_249.G * TC_247_249.dT; TC_247_249.dT = TC_247_249.port_a.T - TC_247_249.port_b.T; TC_247_249.port_a.Q_flow = TC_247_249.Q_flow; TC_247_249.port_b.Q_flow = -TC_247_249.Q_flow; TC_247_409.Q_flow = TC_247_409.G * TC_247_409.dT; TC_247_409.dT = TC_247_409.port_a.T - TC_247_409.port_b.T; TC_247_409.port_a.Q_flow = TC_247_409.Q_flow; TC_247_409.port_b.Q_flow = -TC_247_409.Q_flow; TC_247_1450.Q_flow = TC_247_1450.G * TC_247_1450.dT; TC_247_1450.dT = TC_247_1450.port_a.T - TC_247_1450.port_b.T; TC_247_1450.port_a.Q_flow = TC_247_1450.Q_flow; TC_247_1450.port_b.Q_flow = -TC_247_1450.Q_flow; TC_248_261.Q_flow = TC_248_261.G * TC_248_261.dT; TC_248_261.dT = TC_248_261.port_a.T - TC_248_261.port_b.T; TC_248_261.port_a.Q_flow = TC_248_261.Q_flow; TC_248_261.port_b.Q_flow = -TC_248_261.Q_flow; TC_248_410.Q_flow = TC_248_410.G * TC_248_410.dT; TC_248_410.dT = TC_248_410.port_a.T - TC_248_410.port_b.T; TC_248_410.port_a.Q_flow = TC_248_410.Q_flow; TC_248_410.port_b.Q_flow = -TC_248_410.Q_flow; TC_248_1460.Q_flow = TC_248_1460.G * TC_248_1460.dT; TC_248_1460.dT = TC_248_1460.port_a.T - TC_248_1460.port_b.T; TC_248_1460.port_a.Q_flow = TC_248_1460.Q_flow; TC_248_1460.port_b.Q_flow = -TC_248_1460.Q_flow; TC_249_250.Q_flow = TC_249_250.G * TC_249_250.dT; TC_249_250.dT = TC_249_250.port_a.T - TC_249_250.port_b.T; TC_249_250.port_a.Q_flow = TC_249_250.Q_flow; TC_249_250.port_b.Q_flow = -TC_249_250.Q_flow; TC_249_411.Q_flow = TC_249_411.G * TC_249_411.dT; TC_249_411.dT = TC_249_411.port_a.T - TC_249_411.port_b.T; TC_249_411.port_a.Q_flow = TC_249_411.Q_flow; TC_249_411.port_b.Q_flow = -TC_249_411.Q_flow; TC_250_251.Q_flow = TC_250_251.G * TC_250_251.dT; TC_250_251.dT = TC_250_251.port_a.T - TC_250_251.port_b.T; TC_250_251.port_a.Q_flow = TC_250_251.Q_flow; TC_250_251.port_b.Q_flow = -TC_250_251.Q_flow; TC_250_412.Q_flow = TC_250_412.G * TC_250_412.dT; TC_250_412.dT = TC_250_412.port_a.T - TC_250_412.port_b.T; TC_250_412.port_a.Q_flow = TC_250_412.Q_flow; TC_250_412.port_b.Q_flow = -TC_250_412.Q_flow; TC_250_1450.Q_flow = TC_250_1450.G * TC_250_1450.dT; TC_250_1450.dT = TC_250_1450.port_a.T - TC_250_1450.port_b.T; TC_250_1450.port_a.Q_flow = TC_250_1450.Q_flow; TC_250_1450.port_b.Q_flow = -TC_250_1450.Q_flow; TC_251_252.Q_flow = TC_251_252.G * TC_251_252.dT; TC_251_252.dT = TC_251_252.port_a.T - TC_251_252.port_b.T; TC_251_252.port_a.Q_flow = TC_251_252.Q_flow; TC_251_252.port_b.Q_flow = -TC_251_252.Q_flow; TC_251_413.Q_flow = TC_251_413.G * TC_251_413.dT; TC_251_413.dT = TC_251_413.port_a.T - TC_251_413.port_b.T; TC_251_413.port_a.Q_flow = TC_251_413.Q_flow; TC_251_413.port_b.Q_flow = -TC_251_413.Q_flow; TC_251_1451.Q_flow = TC_251_1451.G * TC_251_1451.dT; TC_251_1451.dT = TC_251_1451.port_a.T - TC_251_1451.port_b.T; TC_251_1451.port_a.Q_flow = TC_251_1451.Q_flow; TC_251_1451.port_b.Q_flow = -TC_251_1451.Q_flow; TC_252_253.Q_flow = TC_252_253.G * TC_252_253.dT; TC_252_253.dT = TC_252_253.port_a.T - TC_252_253.port_b.T; TC_252_253.port_a.Q_flow = TC_252_253.Q_flow; TC_252_253.port_b.Q_flow = -TC_252_253.Q_flow; TC_252_414.Q_flow = TC_252_414.G * TC_252_414.dT; TC_252_414.dT = TC_252_414.port_a.T - TC_252_414.port_b.T; TC_252_414.port_a.Q_flow = TC_252_414.Q_flow; TC_252_414.port_b.Q_flow = -TC_252_414.Q_flow; TC_252_1452.Q_flow = TC_252_1452.G * TC_252_1452.dT; TC_252_1452.dT = TC_252_1452.port_a.T - TC_252_1452.port_b.T; TC_252_1452.port_a.Q_flow = TC_252_1452.Q_flow; TC_252_1452.port_b.Q_flow = -TC_252_1452.Q_flow; TC_253_254.Q_flow = TC_253_254.G * TC_253_254.dT; TC_253_254.dT = TC_253_254.port_a.T - TC_253_254.port_b.T; TC_253_254.port_a.Q_flow = TC_253_254.Q_flow; TC_253_254.port_b.Q_flow = -TC_253_254.Q_flow; TC_253_415.Q_flow = TC_253_415.G * TC_253_415.dT; TC_253_415.dT = TC_253_415.port_a.T - TC_253_415.port_b.T; TC_253_415.port_a.Q_flow = TC_253_415.Q_flow; TC_253_415.port_b.Q_flow = -TC_253_415.Q_flow; TC_253_1453.Q_flow = TC_253_1453.G * TC_253_1453.dT; TC_253_1453.dT = TC_253_1453.port_a.T - TC_253_1453.port_b.T; TC_253_1453.port_a.Q_flow = TC_253_1453.Q_flow; TC_253_1453.port_b.Q_flow = -TC_253_1453.Q_flow; TC_254_255.Q_flow = TC_254_255.G * TC_254_255.dT; TC_254_255.dT = TC_254_255.port_a.T - TC_254_255.port_b.T; TC_254_255.port_a.Q_flow = TC_254_255.Q_flow; TC_254_255.port_b.Q_flow = -TC_254_255.Q_flow; TC_254_416.Q_flow = TC_254_416.G * TC_254_416.dT; TC_254_416.dT = TC_254_416.port_a.T - TC_254_416.port_b.T; TC_254_416.port_a.Q_flow = TC_254_416.Q_flow; TC_254_416.port_b.Q_flow = -TC_254_416.Q_flow; TC_254_1454.Q_flow = TC_254_1454.G * TC_254_1454.dT; TC_254_1454.dT = TC_254_1454.port_a.T - TC_254_1454.port_b.T; TC_254_1454.port_a.Q_flow = TC_254_1454.Q_flow; TC_254_1454.port_b.Q_flow = -TC_254_1454.Q_flow; TC_255_256.Q_flow = TC_255_256.G * TC_255_256.dT; TC_255_256.dT = TC_255_256.port_a.T - TC_255_256.port_b.T; TC_255_256.port_a.Q_flow = TC_255_256.Q_flow; TC_255_256.port_b.Q_flow = -TC_255_256.Q_flow; TC_255_417.Q_flow = TC_255_417.G * TC_255_417.dT; TC_255_417.dT = TC_255_417.port_a.T - TC_255_417.port_b.T; TC_255_417.port_a.Q_flow = TC_255_417.Q_flow; TC_255_417.port_b.Q_flow = -TC_255_417.Q_flow; TC_255_1455.Q_flow = TC_255_1455.G * TC_255_1455.dT; TC_255_1455.dT = TC_255_1455.port_a.T - TC_255_1455.port_b.T; TC_255_1455.port_a.Q_flow = TC_255_1455.Q_flow; TC_255_1455.port_b.Q_flow = -TC_255_1455.Q_flow; TC_256_257.Q_flow = TC_256_257.G * TC_256_257.dT; TC_256_257.dT = TC_256_257.port_a.T - TC_256_257.port_b.T; TC_256_257.port_a.Q_flow = TC_256_257.Q_flow; TC_256_257.port_b.Q_flow = -TC_256_257.Q_flow; TC_256_418.Q_flow = TC_256_418.G * TC_256_418.dT; TC_256_418.dT = TC_256_418.port_a.T - TC_256_418.port_b.T; TC_256_418.port_a.Q_flow = TC_256_418.Q_flow; TC_256_418.port_b.Q_flow = -TC_256_418.Q_flow; TC_256_1456.Q_flow = TC_256_1456.G * TC_256_1456.dT; TC_256_1456.dT = TC_256_1456.port_a.T - TC_256_1456.port_b.T; TC_256_1456.port_a.Q_flow = TC_256_1456.Q_flow; TC_256_1456.port_b.Q_flow = -TC_256_1456.Q_flow; TC_257_258.Q_flow = TC_257_258.G * TC_257_258.dT; TC_257_258.dT = TC_257_258.port_a.T - TC_257_258.port_b.T; TC_257_258.port_a.Q_flow = TC_257_258.Q_flow; TC_257_258.port_b.Q_flow = -TC_257_258.Q_flow; TC_257_419.Q_flow = TC_257_419.G * TC_257_419.dT; TC_257_419.dT = TC_257_419.port_a.T - TC_257_419.port_b.T; TC_257_419.port_a.Q_flow = TC_257_419.Q_flow; TC_257_419.port_b.Q_flow = -TC_257_419.Q_flow; TC_257_1457.Q_flow = TC_257_1457.G * TC_257_1457.dT; TC_257_1457.dT = TC_257_1457.port_a.T - TC_257_1457.port_b.T; TC_257_1457.port_a.Q_flow = TC_257_1457.Q_flow; TC_257_1457.port_b.Q_flow = -TC_257_1457.Q_flow; TC_258_259.Q_flow = TC_258_259.G * TC_258_259.dT; TC_258_259.dT = TC_258_259.port_a.T - TC_258_259.port_b.T; TC_258_259.port_a.Q_flow = TC_258_259.Q_flow; TC_258_259.port_b.Q_flow = -TC_258_259.Q_flow; TC_258_420.Q_flow = TC_258_420.G * TC_258_420.dT; TC_258_420.dT = TC_258_420.port_a.T - TC_258_420.port_b.T; TC_258_420.port_a.Q_flow = TC_258_420.Q_flow; TC_258_420.port_b.Q_flow = -TC_258_420.Q_flow; TC_258_1458.Q_flow = TC_258_1458.G * TC_258_1458.dT; TC_258_1458.dT = TC_258_1458.port_a.T - TC_258_1458.port_b.T; TC_258_1458.port_a.Q_flow = TC_258_1458.Q_flow; TC_258_1458.port_b.Q_flow = -TC_258_1458.Q_flow; TC_259_260.Q_flow = TC_259_260.G * TC_259_260.dT; TC_259_260.dT = TC_259_260.port_a.T - TC_259_260.port_b.T; TC_259_260.port_a.Q_flow = TC_259_260.Q_flow; TC_259_260.port_b.Q_flow = -TC_259_260.Q_flow; TC_259_421.Q_flow = TC_259_421.G * TC_259_421.dT; TC_259_421.dT = TC_259_421.port_a.T - TC_259_421.port_b.T; TC_259_421.port_a.Q_flow = TC_259_421.Q_flow; TC_259_421.port_b.Q_flow = -TC_259_421.Q_flow; TC_259_1459.Q_flow = TC_259_1459.G * TC_259_1459.dT; TC_259_1459.dT = TC_259_1459.port_a.T - TC_259_1459.port_b.T; TC_259_1459.port_a.Q_flow = TC_259_1459.Q_flow; TC_259_1459.port_b.Q_flow = -TC_259_1459.Q_flow; TC_260_261.Q_flow = TC_260_261.G * TC_260_261.dT; TC_260_261.dT = TC_260_261.port_a.T - TC_260_261.port_b.T; TC_260_261.port_a.Q_flow = TC_260_261.Q_flow; TC_260_261.port_b.Q_flow = -TC_260_261.Q_flow; TC_260_422.Q_flow = TC_260_422.G * TC_260_422.dT; TC_260_422.dT = TC_260_422.port_a.T - TC_260_422.port_b.T; TC_260_422.port_a.Q_flow = TC_260_422.Q_flow; TC_260_422.port_b.Q_flow = -TC_260_422.Q_flow; TC_260_1460.Q_flow = TC_260_1460.G * TC_260_1460.dT; TC_260_1460.dT = TC_260_1460.port_a.T - TC_260_1460.port_b.T; TC_260_1460.port_a.Q_flow = TC_260_1460.Q_flow; TC_260_1460.port_b.Q_flow = -TC_260_1460.Q_flow; TC_261_423.Q_flow = TC_261_423.G * TC_261_423.dT; TC_261_423.dT = TC_261_423.port_a.T - TC_261_423.port_b.T; TC_261_423.port_a.Q_flow = TC_261_423.Q_flow; TC_261_423.port_b.Q_flow = -TC_261_423.Q_flow; TC_262_263.Q_flow = TC_262_263.G * TC_262_263.dT; TC_262_263.dT = TC_262_263.port_a.T - TC_262_263.port_b.T; TC_262_263.port_a.Q_flow = TC_262_263.Q_flow; TC_262_263.port_b.Q_flow = -TC_262_263.Q_flow; TC_262_275.Q_flow = TC_262_275.G * TC_262_275.dT; TC_262_275.dT = TC_262_275.port_a.T - TC_262_275.port_b.T; TC_262_275.port_a.Q_flow = TC_262_275.Q_flow; TC_262_275.port_b.Q_flow = -TC_262_275.Q_flow; TC_262_316.Q_flow = TC_262_316.G * TC_262_316.dT; TC_262_316.dT = TC_262_316.port_a.T - TC_262_316.port_b.T; TC_262_316.port_a.Q_flow = TC_262_316.Q_flow; TC_262_316.port_b.Q_flow = -TC_262_316.Q_flow; TC_262_425.Q_flow = TC_262_425.G * TC_262_425.dT; TC_262_425.dT = TC_262_425.port_a.T - TC_262_425.port_b.T; TC_262_425.port_a.Q_flow = TC_262_425.Q_flow; TC_262_425.port_b.Q_flow = -TC_262_425.Q_flow; TC_263_264.Q_flow = TC_263_264.G * TC_263_264.dT; TC_263_264.dT = TC_263_264.port_a.T - TC_263_264.port_b.T; TC_263_264.port_a.Q_flow = TC_263_264.Q_flow; TC_263_264.port_b.Q_flow = -TC_263_264.Q_flow; TC_263_317.Q_flow = TC_263_317.G * TC_263_317.dT; TC_263_317.dT = TC_263_317.port_a.T - TC_263_317.port_b.T; TC_263_317.port_a.Q_flow = TC_263_317.Q_flow; TC_263_317.port_b.Q_flow = -TC_263_317.Q_flow; TC_263_426.Q_flow = TC_263_426.G * TC_263_426.dT; TC_263_426.dT = TC_263_426.port_a.T - TC_263_426.port_b.T; TC_263_426.port_a.Q_flow = TC_263_426.Q_flow; TC_263_426.port_b.Q_flow = -TC_263_426.Q_flow; TC_263_1099.Q_flow = TC_263_1099.G * TC_263_1099.dT; TC_263_1099.dT = TC_263_1099.port_a.T - TC_263_1099.port_b.T; TC_263_1099.port_a.Q_flow = TC_263_1099.Q_flow; TC_263_1099.port_b.Q_flow = -TC_263_1099.Q_flow; TC_264_265.Q_flow = TC_264_265.G * TC_264_265.dT; TC_264_265.dT = TC_264_265.port_a.T - TC_264_265.port_b.T; TC_264_265.port_a.Q_flow = TC_264_265.Q_flow; TC_264_265.port_b.Q_flow = -TC_264_265.Q_flow; TC_264_318.Q_flow = TC_264_318.G * TC_264_318.dT; TC_264_318.dT = TC_264_318.port_a.T - TC_264_318.port_b.T; TC_264_318.port_a.Q_flow = TC_264_318.Q_flow; TC_264_318.port_b.Q_flow = -TC_264_318.Q_flow; TC_264_427.Q_flow = TC_264_427.G * TC_264_427.dT; TC_264_427.dT = TC_264_427.port_a.T - TC_264_427.port_b.T; TC_264_427.port_a.Q_flow = TC_264_427.Q_flow; TC_264_427.port_b.Q_flow = -TC_264_427.Q_flow; TC_264_1100.Q_flow = TC_264_1100.G * TC_264_1100.dT; TC_264_1100.dT = TC_264_1100.port_a.T - TC_264_1100.port_b.T; TC_264_1100.port_a.Q_flow = TC_264_1100.Q_flow; TC_264_1100.port_b.Q_flow = -TC_264_1100.Q_flow; TC_265_266.Q_flow = TC_265_266.G * TC_265_266.dT; TC_265_266.dT = TC_265_266.port_a.T - TC_265_266.port_b.T; TC_265_266.port_a.Q_flow = TC_265_266.Q_flow; TC_265_266.port_b.Q_flow = -TC_265_266.Q_flow; TC_265_319.Q_flow = TC_265_319.G * TC_265_319.dT; TC_265_319.dT = TC_265_319.port_a.T - TC_265_319.port_b.T; TC_265_319.port_a.Q_flow = TC_265_319.Q_flow; TC_265_319.port_b.Q_flow = -TC_265_319.Q_flow; TC_265_428.Q_flow = TC_265_428.G * TC_265_428.dT; TC_265_428.dT = TC_265_428.port_a.T - TC_265_428.port_b.T; TC_265_428.port_a.Q_flow = TC_265_428.Q_flow; TC_265_428.port_b.Q_flow = -TC_265_428.Q_flow; TC_265_1101.Q_flow = TC_265_1101.G * TC_265_1101.dT; TC_265_1101.dT = TC_265_1101.port_a.T - TC_265_1101.port_b.T; TC_265_1101.port_a.Q_flow = TC_265_1101.Q_flow; TC_265_1101.port_b.Q_flow = -TC_265_1101.Q_flow; TC_266_267.Q_flow = TC_266_267.G * TC_266_267.dT; TC_266_267.dT = TC_266_267.port_a.T - TC_266_267.port_b.T; TC_266_267.port_a.Q_flow = TC_266_267.Q_flow; TC_266_267.port_b.Q_flow = -TC_266_267.Q_flow; TC_266_320.Q_flow = TC_266_320.G * TC_266_320.dT; TC_266_320.dT = TC_266_320.port_a.T - TC_266_320.port_b.T; TC_266_320.port_a.Q_flow = TC_266_320.Q_flow; TC_266_320.port_b.Q_flow = -TC_266_320.Q_flow; TC_266_429.Q_flow = TC_266_429.G * TC_266_429.dT; TC_266_429.dT = TC_266_429.port_a.T - TC_266_429.port_b.T; TC_266_429.port_a.Q_flow = TC_266_429.Q_flow; TC_266_429.port_b.Q_flow = -TC_266_429.Q_flow; TC_266_1102.Q_flow = TC_266_1102.G * TC_266_1102.dT; TC_266_1102.dT = TC_266_1102.port_a.T - TC_266_1102.port_b.T; TC_266_1102.port_a.Q_flow = TC_266_1102.Q_flow; TC_266_1102.port_b.Q_flow = -TC_266_1102.Q_flow; TC_267_268.Q_flow = TC_267_268.G * TC_267_268.dT; TC_267_268.dT = TC_267_268.port_a.T - TC_267_268.port_b.T; TC_267_268.port_a.Q_flow = TC_267_268.Q_flow; TC_267_268.port_b.Q_flow = -TC_267_268.Q_flow; TC_267_321.Q_flow = TC_267_321.G * TC_267_321.dT; TC_267_321.dT = TC_267_321.port_a.T - TC_267_321.port_b.T; TC_267_321.port_a.Q_flow = TC_267_321.Q_flow; TC_267_321.port_b.Q_flow = -TC_267_321.Q_flow; TC_267_430.Q_flow = TC_267_430.G * TC_267_430.dT; TC_267_430.dT = TC_267_430.port_a.T - TC_267_430.port_b.T; TC_267_430.port_a.Q_flow = TC_267_430.Q_flow; TC_267_430.port_b.Q_flow = -TC_267_430.Q_flow; TC_267_1103.Q_flow = TC_267_1103.G * TC_267_1103.dT; TC_267_1103.dT = TC_267_1103.port_a.T - TC_267_1103.port_b.T; TC_267_1103.port_a.Q_flow = TC_267_1103.Q_flow; TC_267_1103.port_b.Q_flow = -TC_267_1103.Q_flow; TC_268_269.Q_flow = TC_268_269.G * TC_268_269.dT; TC_268_269.dT = TC_268_269.port_a.T - TC_268_269.port_b.T; TC_268_269.port_a.Q_flow = TC_268_269.Q_flow; TC_268_269.port_b.Q_flow = -TC_268_269.Q_flow; TC_268_322.Q_flow = TC_268_322.G * TC_268_322.dT; TC_268_322.dT = TC_268_322.port_a.T - TC_268_322.port_b.T; TC_268_322.port_a.Q_flow = TC_268_322.Q_flow; TC_268_322.port_b.Q_flow = -TC_268_322.Q_flow; TC_268_431.Q_flow = TC_268_431.G * TC_268_431.dT; TC_268_431.dT = TC_268_431.port_a.T - TC_268_431.port_b.T; TC_268_431.port_a.Q_flow = TC_268_431.Q_flow; TC_268_431.port_b.Q_flow = -TC_268_431.Q_flow; TC_268_1104.Q_flow = TC_268_1104.G * TC_268_1104.dT; TC_268_1104.dT = TC_268_1104.port_a.T - TC_268_1104.port_b.T; TC_268_1104.port_a.Q_flow = TC_268_1104.Q_flow; TC_268_1104.port_b.Q_flow = -TC_268_1104.Q_flow; TC_269_270.Q_flow = TC_269_270.G * TC_269_270.dT; TC_269_270.dT = TC_269_270.port_a.T - TC_269_270.port_b.T; TC_269_270.port_a.Q_flow = TC_269_270.Q_flow; TC_269_270.port_b.Q_flow = -TC_269_270.Q_flow; TC_269_323.Q_flow = TC_269_323.G * TC_269_323.dT; TC_269_323.dT = TC_269_323.port_a.T - TC_269_323.port_b.T; TC_269_323.port_a.Q_flow = TC_269_323.Q_flow; TC_269_323.port_b.Q_flow = -TC_269_323.Q_flow; TC_269_432.Q_flow = TC_269_432.G * TC_269_432.dT; TC_269_432.dT = TC_269_432.port_a.T - TC_269_432.port_b.T; TC_269_432.port_a.Q_flow = TC_269_432.Q_flow; TC_269_432.port_b.Q_flow = -TC_269_432.Q_flow; TC_269_1105.Q_flow = TC_269_1105.G * TC_269_1105.dT; TC_269_1105.dT = TC_269_1105.port_a.T - TC_269_1105.port_b.T; TC_269_1105.port_a.Q_flow = TC_269_1105.Q_flow; TC_269_1105.port_b.Q_flow = -TC_269_1105.Q_flow; TC_270_271.Q_flow = TC_270_271.G * TC_270_271.dT; TC_270_271.dT = TC_270_271.port_a.T - TC_270_271.port_b.T; TC_270_271.port_a.Q_flow = TC_270_271.Q_flow; TC_270_271.port_b.Q_flow = -TC_270_271.Q_flow; TC_270_324.Q_flow = TC_270_324.G * TC_270_324.dT; TC_270_324.dT = TC_270_324.port_a.T - TC_270_324.port_b.T; TC_270_324.port_a.Q_flow = TC_270_324.Q_flow; TC_270_324.port_b.Q_flow = -TC_270_324.Q_flow; TC_270_433.Q_flow = TC_270_433.G * TC_270_433.dT; TC_270_433.dT = TC_270_433.port_a.T - TC_270_433.port_b.T; TC_270_433.port_a.Q_flow = TC_270_433.Q_flow; TC_270_433.port_b.Q_flow = -TC_270_433.Q_flow; TC_270_1106.Q_flow = TC_270_1106.G * TC_270_1106.dT; TC_270_1106.dT = TC_270_1106.port_a.T - TC_270_1106.port_b.T; TC_270_1106.port_a.Q_flow = TC_270_1106.Q_flow; TC_270_1106.port_b.Q_flow = -TC_270_1106.Q_flow; TC_271_272.Q_flow = TC_271_272.G * TC_271_272.dT; TC_271_272.dT = TC_271_272.port_a.T - TC_271_272.port_b.T; TC_271_272.port_a.Q_flow = TC_271_272.Q_flow; TC_271_272.port_b.Q_flow = -TC_271_272.Q_flow; TC_271_325.Q_flow = TC_271_325.G * TC_271_325.dT; TC_271_325.dT = TC_271_325.port_a.T - TC_271_325.port_b.T; TC_271_325.port_a.Q_flow = TC_271_325.Q_flow; TC_271_325.port_b.Q_flow = -TC_271_325.Q_flow; TC_271_434.Q_flow = TC_271_434.G * TC_271_434.dT; TC_271_434.dT = TC_271_434.port_a.T - TC_271_434.port_b.T; TC_271_434.port_a.Q_flow = TC_271_434.Q_flow; TC_271_434.port_b.Q_flow = -TC_271_434.Q_flow; TC_271_1107.Q_flow = TC_271_1107.G * TC_271_1107.dT; TC_271_1107.dT = TC_271_1107.port_a.T - TC_271_1107.port_b.T; TC_271_1107.port_a.Q_flow = TC_271_1107.Q_flow; TC_271_1107.port_b.Q_flow = -TC_271_1107.Q_flow; TC_272_273.Q_flow = TC_272_273.G * TC_272_273.dT; TC_272_273.dT = TC_272_273.port_a.T - TC_272_273.port_b.T; TC_272_273.port_a.Q_flow = TC_272_273.Q_flow; TC_272_273.port_b.Q_flow = -TC_272_273.Q_flow; TC_272_326.Q_flow = TC_272_326.G * TC_272_326.dT; TC_272_326.dT = TC_272_326.port_a.T - TC_272_326.port_b.T; TC_272_326.port_a.Q_flow = TC_272_326.Q_flow; TC_272_326.port_b.Q_flow = -TC_272_326.Q_flow; TC_272_435.Q_flow = TC_272_435.G * TC_272_435.dT; TC_272_435.dT = TC_272_435.port_a.T - TC_272_435.port_b.T; TC_272_435.port_a.Q_flow = TC_272_435.Q_flow; TC_272_435.port_b.Q_flow = -TC_272_435.Q_flow; TC_272_1108.Q_flow = TC_272_1108.G * TC_272_1108.dT; TC_272_1108.dT = TC_272_1108.port_a.T - TC_272_1108.port_b.T; TC_272_1108.port_a.Q_flow = TC_272_1108.Q_flow; TC_272_1108.port_b.Q_flow = -TC_272_1108.Q_flow; TC_273_274.Q_flow = TC_273_274.G * TC_273_274.dT; TC_273_274.dT = TC_273_274.port_a.T - TC_273_274.port_b.T; TC_273_274.port_a.Q_flow = TC_273_274.Q_flow; TC_273_274.port_b.Q_flow = -TC_273_274.Q_flow; TC_273_327.Q_flow = TC_273_327.G * TC_273_327.dT; TC_273_327.dT = TC_273_327.port_a.T - TC_273_327.port_b.T; TC_273_327.port_a.Q_flow = TC_273_327.Q_flow; TC_273_327.port_b.Q_flow = -TC_273_327.Q_flow; TC_273_436.Q_flow = TC_273_436.G * TC_273_436.dT; TC_273_436.dT = TC_273_436.port_a.T - TC_273_436.port_b.T; TC_273_436.port_a.Q_flow = TC_273_436.Q_flow; TC_273_436.port_b.Q_flow = -TC_273_436.Q_flow; TC_273_1109.Q_flow = TC_273_1109.G * TC_273_1109.dT; TC_273_1109.dT = TC_273_1109.port_a.T - TC_273_1109.port_b.T; TC_273_1109.port_a.Q_flow = TC_273_1109.Q_flow; TC_273_1109.port_b.Q_flow = -TC_273_1109.Q_flow; TC_274_276.Q_flow = TC_274_276.G * TC_274_276.dT; TC_274_276.dT = TC_274_276.port_a.T - TC_274_276.port_b.T; TC_274_276.port_a.Q_flow = TC_274_276.Q_flow; TC_274_276.port_b.Q_flow = -TC_274_276.Q_flow; TC_274_328.Q_flow = TC_274_328.G * TC_274_328.dT; TC_274_328.dT = TC_274_328.port_a.T - TC_274_328.port_b.T; TC_274_328.port_a.Q_flow = TC_274_328.Q_flow; TC_274_328.port_b.Q_flow = -TC_274_328.Q_flow; TC_274_437.Q_flow = TC_274_437.G * TC_274_437.dT; TC_274_437.dT = TC_274_437.port_a.T - TC_274_437.port_b.T; TC_274_437.port_a.Q_flow = TC_274_437.Q_flow; TC_274_437.port_b.Q_flow = -TC_274_437.Q_flow; TC_275_277.Q_flow = TC_275_277.G * TC_275_277.dT; TC_275_277.dT = TC_275_277.port_a.T - TC_275_277.port_b.T; TC_275_277.port_a.Q_flow = TC_275_277.Q_flow; TC_275_277.port_b.Q_flow = -TC_275_277.Q_flow; TC_275_329.Q_flow = TC_275_329.G * TC_275_329.dT; TC_275_329.dT = TC_275_329.port_a.T - TC_275_329.port_b.T; TC_275_329.port_a.Q_flow = TC_275_329.Q_flow; TC_275_329.port_b.Q_flow = -TC_275_329.Q_flow; TC_275_438.Q_flow = TC_275_438.G * TC_275_438.dT; TC_275_438.dT = TC_275_438.port_a.T - TC_275_438.port_b.T; TC_275_438.port_a.Q_flow = TC_275_438.Q_flow; TC_275_438.port_b.Q_flow = -TC_275_438.Q_flow; TC_275_1099.Q_flow = TC_275_1099.G * TC_275_1099.dT; TC_275_1099.dT = TC_275_1099.port_a.T - TC_275_1099.port_b.T; TC_275_1099.port_a.Q_flow = TC_275_1099.Q_flow; TC_275_1099.port_b.Q_flow = -TC_275_1099.Q_flow; TC_276_278.Q_flow = TC_276_278.G * TC_276_278.dT; TC_276_278.dT = TC_276_278.port_a.T - TC_276_278.port_b.T; TC_276_278.port_a.Q_flow = TC_276_278.Q_flow; TC_276_278.port_b.Q_flow = -TC_276_278.Q_flow; TC_276_330.Q_flow = TC_276_330.G * TC_276_330.dT; TC_276_330.dT = TC_276_330.port_a.T - TC_276_330.port_b.T; TC_276_330.port_a.Q_flow = TC_276_330.Q_flow; TC_276_330.port_b.Q_flow = -TC_276_330.Q_flow; TC_276_439.Q_flow = TC_276_439.G * TC_276_439.dT; TC_276_439.dT = TC_276_439.port_a.T - TC_276_439.port_b.T; TC_276_439.port_a.Q_flow = TC_276_439.Q_flow; TC_276_439.port_b.Q_flow = -TC_276_439.Q_flow; TC_276_1109.Q_flow = TC_276_1109.G * TC_276_1109.dT; TC_276_1109.dT = TC_276_1109.port_a.T - TC_276_1109.port_b.T; TC_276_1109.port_a.Q_flow = TC_276_1109.Q_flow; TC_276_1109.port_b.Q_flow = -TC_276_1109.Q_flow; TC_277_279.Q_flow = TC_277_279.G * TC_277_279.dT; TC_277_279.dT = TC_277_279.port_a.T - TC_277_279.port_b.T; TC_277_279.port_a.Q_flow = TC_277_279.Q_flow; TC_277_279.port_b.Q_flow = -TC_277_279.Q_flow; TC_277_331.Q_flow = TC_277_331.G * TC_277_331.dT; TC_277_331.dT = TC_277_331.port_a.T - TC_277_331.port_b.T; TC_277_331.port_a.Q_flow = TC_277_331.Q_flow; TC_277_331.port_b.Q_flow = -TC_277_331.Q_flow; TC_277_440.Q_flow = TC_277_440.G * TC_277_440.dT; TC_277_440.dT = TC_277_440.port_a.T - TC_277_440.port_b.T; TC_277_440.port_a.Q_flow = TC_277_440.Q_flow; TC_277_440.port_b.Q_flow = -TC_277_440.Q_flow; TC_277_1110.Q_flow = TC_277_1110.G * TC_277_1110.dT; TC_277_1110.dT = TC_277_1110.port_a.T - TC_277_1110.port_b.T; TC_277_1110.port_a.Q_flow = TC_277_1110.Q_flow; TC_277_1110.port_b.Q_flow = -TC_277_1110.Q_flow; TC_278_280.Q_flow = TC_278_280.G * TC_278_280.dT; TC_278_280.dT = TC_278_280.port_a.T - TC_278_280.port_b.T; TC_278_280.port_a.Q_flow = TC_278_280.Q_flow; TC_278_280.port_b.Q_flow = -TC_278_280.Q_flow; TC_278_332.Q_flow = TC_278_332.G * TC_278_332.dT; TC_278_332.dT = TC_278_332.port_a.T - TC_278_332.port_b.T; TC_278_332.port_a.Q_flow = TC_278_332.Q_flow; TC_278_332.port_b.Q_flow = -TC_278_332.Q_flow; TC_278_441.Q_flow = TC_278_441.G * TC_278_441.dT; TC_278_441.dT = TC_278_441.port_a.T - TC_278_441.port_b.T; TC_278_441.port_a.Q_flow = TC_278_441.Q_flow; TC_278_441.port_b.Q_flow = -TC_278_441.Q_flow; TC_278_1111.Q_flow = TC_278_1111.G * TC_278_1111.dT; TC_278_1111.dT = TC_278_1111.port_a.T - TC_278_1111.port_b.T; TC_278_1111.port_a.Q_flow = TC_278_1111.Q_flow; TC_278_1111.port_b.Q_flow = -TC_278_1111.Q_flow; TC_279_281.Q_flow = TC_279_281.G * TC_279_281.dT; TC_279_281.dT = TC_279_281.port_a.T - TC_279_281.port_b.T; TC_279_281.port_a.Q_flow = TC_279_281.Q_flow; TC_279_281.port_b.Q_flow = -TC_279_281.Q_flow; TC_279_333.Q_flow = TC_279_333.G * TC_279_333.dT; TC_279_333.dT = TC_279_333.port_a.T - TC_279_333.port_b.T; TC_279_333.port_a.Q_flow = TC_279_333.Q_flow; TC_279_333.port_b.Q_flow = -TC_279_333.Q_flow; TC_279_442.Q_flow = TC_279_442.G * TC_279_442.dT; TC_279_442.dT = TC_279_442.port_a.T - TC_279_442.port_b.T; TC_279_442.port_a.Q_flow = TC_279_442.Q_flow; TC_279_442.port_b.Q_flow = -TC_279_442.Q_flow; TC_279_1112.Q_flow = TC_279_1112.G * TC_279_1112.dT; TC_279_1112.dT = TC_279_1112.port_a.T - TC_279_1112.port_b.T; TC_279_1112.port_a.Q_flow = TC_279_1112.Q_flow; TC_279_1112.port_b.Q_flow = -TC_279_1112.Q_flow; TC_280_282.Q_flow = TC_280_282.G * TC_280_282.dT; TC_280_282.dT = TC_280_282.port_a.T - TC_280_282.port_b.T; TC_280_282.port_a.Q_flow = TC_280_282.Q_flow; TC_280_282.port_b.Q_flow = -TC_280_282.Q_flow; TC_280_334.Q_flow = TC_280_334.G * TC_280_334.dT; TC_280_334.dT = TC_280_334.port_a.T - TC_280_334.port_b.T; TC_280_334.port_a.Q_flow = TC_280_334.Q_flow; TC_280_334.port_b.Q_flow = -TC_280_334.Q_flow; TC_280_443.Q_flow = TC_280_443.G * TC_280_443.dT; TC_280_443.dT = TC_280_443.port_a.T - TC_280_443.port_b.T; TC_280_443.port_a.Q_flow = TC_280_443.Q_flow; TC_280_443.port_b.Q_flow = -TC_280_443.Q_flow; TC_280_1113.Q_flow = TC_280_1113.G * TC_280_1113.dT; TC_280_1113.dT = TC_280_1113.port_a.T - TC_280_1113.port_b.T; TC_280_1113.port_a.Q_flow = TC_280_1113.Q_flow; TC_280_1113.port_b.Q_flow = -TC_280_1113.Q_flow; TC_281_283.Q_flow = TC_281_283.G * TC_281_283.dT; TC_281_283.dT = TC_281_283.port_a.T - TC_281_283.port_b.T; TC_281_283.port_a.Q_flow = TC_281_283.Q_flow; TC_281_283.port_b.Q_flow = -TC_281_283.Q_flow; TC_281_335.Q_flow = TC_281_335.G * TC_281_335.dT; TC_281_335.dT = TC_281_335.port_a.T - TC_281_335.port_b.T; TC_281_335.port_a.Q_flow = TC_281_335.Q_flow; TC_281_335.port_b.Q_flow = -TC_281_335.Q_flow; TC_281_444.Q_flow = TC_281_444.G * TC_281_444.dT; TC_281_444.dT = TC_281_444.port_a.T - TC_281_444.port_b.T; TC_281_444.port_a.Q_flow = TC_281_444.Q_flow; TC_281_444.port_b.Q_flow = -TC_281_444.Q_flow; TC_281_1114.Q_flow = TC_281_1114.G * TC_281_1114.dT; TC_281_1114.dT = TC_281_1114.port_a.T - TC_281_1114.port_b.T; TC_281_1114.port_a.Q_flow = TC_281_1114.Q_flow; TC_281_1114.port_b.Q_flow = -TC_281_1114.Q_flow; TC_282_284.Q_flow = TC_282_284.G * TC_282_284.dT; TC_282_284.dT = TC_282_284.port_a.T - TC_282_284.port_b.T; TC_282_284.port_a.Q_flow = TC_282_284.Q_flow; TC_282_284.port_b.Q_flow = -TC_282_284.Q_flow; TC_282_336.Q_flow = TC_282_336.G * TC_282_336.dT; TC_282_336.dT = TC_282_336.port_a.T - TC_282_336.port_b.T; TC_282_336.port_a.Q_flow = TC_282_336.Q_flow; TC_282_336.port_b.Q_flow = -TC_282_336.Q_flow; TC_282_445.Q_flow = TC_282_445.G * TC_282_445.dT; TC_282_445.dT = TC_282_445.port_a.T - TC_282_445.port_b.T; TC_282_445.port_a.Q_flow = TC_282_445.Q_flow; TC_282_445.port_b.Q_flow = -TC_282_445.Q_flow; TC_282_1115.Q_flow = TC_282_1115.G * TC_282_1115.dT; TC_282_1115.dT = TC_282_1115.port_a.T - TC_282_1115.port_b.T; TC_282_1115.port_a.Q_flow = TC_282_1115.Q_flow; TC_282_1115.port_b.Q_flow = -TC_282_1115.Q_flow; TC_283_285.Q_flow = TC_283_285.G * TC_283_285.dT; TC_283_285.dT = TC_283_285.port_a.T - TC_283_285.port_b.T; TC_283_285.port_a.Q_flow = TC_283_285.Q_flow; TC_283_285.port_b.Q_flow = -TC_283_285.Q_flow; TC_283_337.Q_flow = TC_283_337.G * TC_283_337.dT; TC_283_337.dT = TC_283_337.port_a.T - TC_283_337.port_b.T; TC_283_337.port_a.Q_flow = TC_283_337.Q_flow; TC_283_337.port_b.Q_flow = -TC_283_337.Q_flow; TC_283_446.Q_flow = TC_283_446.G * TC_283_446.dT; TC_283_446.dT = TC_283_446.port_a.T - TC_283_446.port_b.T; TC_283_446.port_a.Q_flow = TC_283_446.Q_flow; TC_283_446.port_b.Q_flow = -TC_283_446.Q_flow; TC_283_1116.Q_flow = TC_283_1116.G * TC_283_1116.dT; TC_283_1116.dT = TC_283_1116.port_a.T - TC_283_1116.port_b.T; TC_283_1116.port_a.Q_flow = TC_283_1116.Q_flow; TC_283_1116.port_b.Q_flow = -TC_283_1116.Q_flow; TC_284_286.Q_flow = TC_284_286.G * TC_284_286.dT; TC_284_286.dT = TC_284_286.port_a.T - TC_284_286.port_b.T; TC_284_286.port_a.Q_flow = TC_284_286.Q_flow; TC_284_286.port_b.Q_flow = -TC_284_286.Q_flow; TC_284_338.Q_flow = TC_284_338.G * TC_284_338.dT; TC_284_338.dT = TC_284_338.port_a.T - TC_284_338.port_b.T; TC_284_338.port_a.Q_flow = TC_284_338.Q_flow; TC_284_338.port_b.Q_flow = -TC_284_338.Q_flow; TC_284_447.Q_flow = TC_284_447.G * TC_284_447.dT; TC_284_447.dT = TC_284_447.port_a.T - TC_284_447.port_b.T; TC_284_447.port_a.Q_flow = TC_284_447.Q_flow; TC_284_447.port_b.Q_flow = -TC_284_447.Q_flow; TC_284_1117.Q_flow = TC_284_1117.G * TC_284_1117.dT; TC_284_1117.dT = TC_284_1117.port_a.T - TC_284_1117.port_b.T; TC_284_1117.port_a.Q_flow = TC_284_1117.Q_flow; TC_284_1117.port_b.Q_flow = -TC_284_1117.Q_flow; TC_285_287.Q_flow = TC_285_287.G * TC_285_287.dT; TC_285_287.dT = TC_285_287.port_a.T - TC_285_287.port_b.T; TC_285_287.port_a.Q_flow = TC_285_287.Q_flow; TC_285_287.port_b.Q_flow = -TC_285_287.Q_flow; TC_285_339.Q_flow = TC_285_339.G * TC_285_339.dT; TC_285_339.dT = TC_285_339.port_a.T - TC_285_339.port_b.T; TC_285_339.port_a.Q_flow = TC_285_339.Q_flow; TC_285_339.port_b.Q_flow = -TC_285_339.Q_flow; TC_285_448.Q_flow = TC_285_448.G * TC_285_448.dT; TC_285_448.dT = TC_285_448.port_a.T - TC_285_448.port_b.T; TC_285_448.port_a.Q_flow = TC_285_448.Q_flow; TC_285_448.port_b.Q_flow = -TC_285_448.Q_flow; TC_285_1118.Q_flow = TC_285_1118.G * TC_285_1118.dT; TC_285_1118.dT = TC_285_1118.port_a.T - TC_285_1118.port_b.T; TC_285_1118.port_a.Q_flow = TC_285_1118.Q_flow; TC_285_1118.port_b.Q_flow = -TC_285_1118.Q_flow; TC_286_288.Q_flow = TC_286_288.G * TC_286_288.dT; TC_286_288.dT = TC_286_288.port_a.T - TC_286_288.port_b.T; TC_286_288.port_a.Q_flow = TC_286_288.Q_flow; TC_286_288.port_b.Q_flow = -TC_286_288.Q_flow; TC_286_340.Q_flow = TC_286_340.G * TC_286_340.dT; TC_286_340.dT = TC_286_340.port_a.T - TC_286_340.port_b.T; TC_286_340.port_a.Q_flow = TC_286_340.Q_flow; TC_286_340.port_b.Q_flow = -TC_286_340.Q_flow; TC_286_449.Q_flow = TC_286_449.G * TC_286_449.dT; TC_286_449.dT = TC_286_449.port_a.T - TC_286_449.port_b.T; TC_286_449.port_a.Q_flow = TC_286_449.Q_flow; TC_286_449.port_b.Q_flow = -TC_286_449.Q_flow; TC_286_1119.Q_flow = TC_286_1119.G * TC_286_1119.dT; TC_286_1119.dT = TC_286_1119.port_a.T - TC_286_1119.port_b.T; TC_286_1119.port_a.Q_flow = TC_286_1119.Q_flow; TC_286_1119.port_b.Q_flow = -TC_286_1119.Q_flow; TC_287_289.Q_flow = TC_287_289.G * TC_287_289.dT; TC_287_289.dT = TC_287_289.port_a.T - TC_287_289.port_b.T; TC_287_289.port_a.Q_flow = TC_287_289.Q_flow; TC_287_289.port_b.Q_flow = -TC_287_289.Q_flow; TC_287_341.Q_flow = TC_287_341.G * TC_287_341.dT; TC_287_341.dT = TC_287_341.port_a.T - TC_287_341.port_b.T; TC_287_341.port_a.Q_flow = TC_287_341.Q_flow; TC_287_341.port_b.Q_flow = -TC_287_341.Q_flow; TC_287_450.Q_flow = TC_287_450.G * TC_287_450.dT; TC_287_450.dT = TC_287_450.port_a.T - TC_287_450.port_b.T; TC_287_450.port_a.Q_flow = TC_287_450.Q_flow; TC_287_450.port_b.Q_flow = -TC_287_450.Q_flow; TC_287_1120.Q_flow = TC_287_1120.G * TC_287_1120.dT; TC_287_1120.dT = TC_287_1120.port_a.T - TC_287_1120.port_b.T; TC_287_1120.port_a.Q_flow = TC_287_1120.Q_flow; TC_287_1120.port_b.Q_flow = -TC_287_1120.Q_flow; TC_288_290.Q_flow = TC_288_290.G * TC_288_290.dT; TC_288_290.dT = TC_288_290.port_a.T - TC_288_290.port_b.T; TC_288_290.port_a.Q_flow = TC_288_290.Q_flow; TC_288_290.port_b.Q_flow = -TC_288_290.Q_flow; TC_288_342.Q_flow = TC_288_342.G * TC_288_342.dT; TC_288_342.dT = TC_288_342.port_a.T - TC_288_342.port_b.T; TC_288_342.port_a.Q_flow = TC_288_342.Q_flow; TC_288_342.port_b.Q_flow = -TC_288_342.Q_flow; TC_288_451.Q_flow = TC_288_451.G * TC_288_451.dT; TC_288_451.dT = TC_288_451.port_a.T - TC_288_451.port_b.T; TC_288_451.port_a.Q_flow = TC_288_451.Q_flow; TC_288_451.port_b.Q_flow = -TC_288_451.Q_flow; TC_288_1121.Q_flow = TC_288_1121.G * TC_288_1121.dT; TC_288_1121.dT = TC_288_1121.port_a.T - TC_288_1121.port_b.T; TC_288_1121.port_a.Q_flow = TC_288_1121.Q_flow; TC_288_1121.port_b.Q_flow = -TC_288_1121.Q_flow; TC_289_291.Q_flow = TC_289_291.G * TC_289_291.dT; TC_289_291.dT = TC_289_291.port_a.T - TC_289_291.port_b.T; TC_289_291.port_a.Q_flow = TC_289_291.Q_flow; TC_289_291.port_b.Q_flow = -TC_289_291.Q_flow; TC_289_343.Q_flow = TC_289_343.G * TC_289_343.dT; TC_289_343.dT = TC_289_343.port_a.T - TC_289_343.port_b.T; TC_289_343.port_a.Q_flow = TC_289_343.Q_flow; TC_289_343.port_b.Q_flow = -TC_289_343.Q_flow; TC_289_452.Q_flow = TC_289_452.G * TC_289_452.dT; TC_289_452.dT = TC_289_452.port_a.T - TC_289_452.port_b.T; TC_289_452.port_a.Q_flow = TC_289_452.Q_flow; TC_289_452.port_b.Q_flow = -TC_289_452.Q_flow; TC_289_1122.Q_flow = TC_289_1122.G * TC_289_1122.dT; TC_289_1122.dT = TC_289_1122.port_a.T - TC_289_1122.port_b.T; TC_289_1122.port_a.Q_flow = TC_289_1122.Q_flow; TC_289_1122.port_b.Q_flow = -TC_289_1122.Q_flow; TC_290_292.Q_flow = TC_290_292.G * TC_290_292.dT; TC_290_292.dT = TC_290_292.port_a.T - TC_290_292.port_b.T; TC_290_292.port_a.Q_flow = TC_290_292.Q_flow; TC_290_292.port_b.Q_flow = -TC_290_292.Q_flow; TC_290_344.Q_flow = TC_290_344.G * TC_290_344.dT; TC_290_344.dT = TC_290_344.port_a.T - TC_290_344.port_b.T; TC_290_344.port_a.Q_flow = TC_290_344.Q_flow; TC_290_344.port_b.Q_flow = -TC_290_344.Q_flow; TC_290_453.Q_flow = TC_290_453.G * TC_290_453.dT; TC_290_453.dT = TC_290_453.port_a.T - TC_290_453.port_b.T; TC_290_453.port_a.Q_flow = TC_290_453.Q_flow; TC_290_453.port_b.Q_flow = -TC_290_453.Q_flow; TC_290_1123.Q_flow = TC_290_1123.G * TC_290_1123.dT; TC_290_1123.dT = TC_290_1123.port_a.T - TC_290_1123.port_b.T; TC_290_1123.port_a.Q_flow = TC_290_1123.Q_flow; TC_290_1123.port_b.Q_flow = -TC_290_1123.Q_flow; TC_291_293.Q_flow = TC_291_293.G * TC_291_293.dT; TC_291_293.dT = TC_291_293.port_a.T - TC_291_293.port_b.T; TC_291_293.port_a.Q_flow = TC_291_293.Q_flow; TC_291_293.port_b.Q_flow = -TC_291_293.Q_flow; TC_291_345.Q_flow = TC_291_345.G * TC_291_345.dT; TC_291_345.dT = TC_291_345.port_a.T - TC_291_345.port_b.T; TC_291_345.port_a.Q_flow = TC_291_345.Q_flow; TC_291_345.port_b.Q_flow = -TC_291_345.Q_flow; TC_291_454.Q_flow = TC_291_454.G * TC_291_454.dT; TC_291_454.dT = TC_291_454.port_a.T - TC_291_454.port_b.T; TC_291_454.port_a.Q_flow = TC_291_454.Q_flow; TC_291_454.port_b.Q_flow = -TC_291_454.Q_flow; TC_291_1124.Q_flow = TC_291_1124.G * TC_291_1124.dT; TC_291_1124.dT = TC_291_1124.port_a.T - TC_291_1124.port_b.T; TC_291_1124.port_a.Q_flow = TC_291_1124.Q_flow; TC_291_1124.port_b.Q_flow = -TC_291_1124.Q_flow; TC_292_294.Q_flow = TC_292_294.G * TC_292_294.dT; TC_292_294.dT = TC_292_294.port_a.T - TC_292_294.port_b.T; TC_292_294.port_a.Q_flow = TC_292_294.Q_flow; TC_292_294.port_b.Q_flow = -TC_292_294.Q_flow; TC_292_346.Q_flow = TC_292_346.G * TC_292_346.dT; TC_292_346.dT = TC_292_346.port_a.T - TC_292_346.port_b.T; TC_292_346.port_a.Q_flow = TC_292_346.Q_flow; TC_292_346.port_b.Q_flow = -TC_292_346.Q_flow; TC_292_455.Q_flow = TC_292_455.G * TC_292_455.dT; TC_292_455.dT = TC_292_455.port_a.T - TC_292_455.port_b.T; TC_292_455.port_a.Q_flow = TC_292_455.Q_flow; TC_292_455.port_b.Q_flow = -TC_292_455.Q_flow; TC_292_1125.Q_flow = TC_292_1125.G * TC_292_1125.dT; TC_292_1125.dT = TC_292_1125.port_a.T - TC_292_1125.port_b.T; TC_292_1125.port_a.Q_flow = TC_292_1125.Q_flow; TC_292_1125.port_b.Q_flow = -TC_292_1125.Q_flow; TC_293_295.Q_flow = TC_293_295.G * TC_293_295.dT; TC_293_295.dT = TC_293_295.port_a.T - TC_293_295.port_b.T; TC_293_295.port_a.Q_flow = TC_293_295.Q_flow; TC_293_295.port_b.Q_flow = -TC_293_295.Q_flow; TC_293_347.Q_flow = TC_293_347.G * TC_293_347.dT; TC_293_347.dT = TC_293_347.port_a.T - TC_293_347.port_b.T; TC_293_347.port_a.Q_flow = TC_293_347.Q_flow; TC_293_347.port_b.Q_flow = -TC_293_347.Q_flow; TC_293_456.Q_flow = TC_293_456.G * TC_293_456.dT; TC_293_456.dT = TC_293_456.port_a.T - TC_293_456.port_b.T; TC_293_456.port_a.Q_flow = TC_293_456.Q_flow; TC_293_456.port_b.Q_flow = -TC_293_456.Q_flow; TC_293_1126.Q_flow = TC_293_1126.G * TC_293_1126.dT; TC_293_1126.dT = TC_293_1126.port_a.T - TC_293_1126.port_b.T; TC_293_1126.port_a.Q_flow = TC_293_1126.Q_flow; TC_293_1126.port_b.Q_flow = -TC_293_1126.Q_flow; TC_294_296.Q_flow = TC_294_296.G * TC_294_296.dT; TC_294_296.dT = TC_294_296.port_a.T - TC_294_296.port_b.T; TC_294_296.port_a.Q_flow = TC_294_296.Q_flow; TC_294_296.port_b.Q_flow = -TC_294_296.Q_flow; TC_294_348.Q_flow = TC_294_348.G * TC_294_348.dT; TC_294_348.dT = TC_294_348.port_a.T - TC_294_348.port_b.T; TC_294_348.port_a.Q_flow = TC_294_348.Q_flow; TC_294_348.port_b.Q_flow = -TC_294_348.Q_flow; TC_294_457.Q_flow = TC_294_457.G * TC_294_457.dT; TC_294_457.dT = TC_294_457.port_a.T - TC_294_457.port_b.T; TC_294_457.port_a.Q_flow = TC_294_457.Q_flow; TC_294_457.port_b.Q_flow = -TC_294_457.Q_flow; TC_294_1127.Q_flow = TC_294_1127.G * TC_294_1127.dT; TC_294_1127.dT = TC_294_1127.port_a.T - TC_294_1127.port_b.T; TC_294_1127.port_a.Q_flow = TC_294_1127.Q_flow; TC_294_1127.port_b.Q_flow = -TC_294_1127.Q_flow; TC_295_297.Q_flow = TC_295_297.G * TC_295_297.dT; TC_295_297.dT = TC_295_297.port_a.T - TC_295_297.port_b.T; TC_295_297.port_a.Q_flow = TC_295_297.Q_flow; TC_295_297.port_b.Q_flow = -TC_295_297.Q_flow; TC_295_349.Q_flow = TC_295_349.G * TC_295_349.dT; TC_295_349.dT = TC_295_349.port_a.T - TC_295_349.port_b.T; TC_295_349.port_a.Q_flow = TC_295_349.Q_flow; TC_295_349.port_b.Q_flow = -TC_295_349.Q_flow; TC_295_458.Q_flow = TC_295_458.G * TC_295_458.dT; TC_295_458.dT = TC_295_458.port_a.T - TC_295_458.port_b.T; TC_295_458.port_a.Q_flow = TC_295_458.Q_flow; TC_295_458.port_b.Q_flow = -TC_295_458.Q_flow; TC_295_1128.Q_flow = TC_295_1128.G * TC_295_1128.dT; TC_295_1128.dT = TC_295_1128.port_a.T - TC_295_1128.port_b.T; TC_295_1128.port_a.Q_flow = TC_295_1128.Q_flow; TC_295_1128.port_b.Q_flow = -TC_295_1128.Q_flow; TC_296_298.Q_flow = TC_296_298.G * TC_296_298.dT; TC_296_298.dT = TC_296_298.port_a.T - TC_296_298.port_b.T; TC_296_298.port_a.Q_flow = TC_296_298.Q_flow; TC_296_298.port_b.Q_flow = -TC_296_298.Q_flow; TC_296_350.Q_flow = TC_296_350.G * TC_296_350.dT; TC_296_350.dT = TC_296_350.port_a.T - TC_296_350.port_b.T; TC_296_350.port_a.Q_flow = TC_296_350.Q_flow; TC_296_350.port_b.Q_flow = -TC_296_350.Q_flow; TC_296_459.Q_flow = TC_296_459.G * TC_296_459.dT; TC_296_459.dT = TC_296_459.port_a.T - TC_296_459.port_b.T; TC_296_459.port_a.Q_flow = TC_296_459.Q_flow; TC_296_459.port_b.Q_flow = -TC_296_459.Q_flow; TC_296_1129.Q_flow = TC_296_1129.G * TC_296_1129.dT; TC_296_1129.dT = TC_296_1129.port_a.T - TC_296_1129.port_b.T; TC_296_1129.port_a.Q_flow = TC_296_1129.Q_flow; TC_296_1129.port_b.Q_flow = -TC_296_1129.Q_flow; TC_297_299.Q_flow = TC_297_299.G * TC_297_299.dT; TC_297_299.dT = TC_297_299.port_a.T - TC_297_299.port_b.T; TC_297_299.port_a.Q_flow = TC_297_299.Q_flow; TC_297_299.port_b.Q_flow = -TC_297_299.Q_flow; TC_297_351.Q_flow = TC_297_351.G * TC_297_351.dT; TC_297_351.dT = TC_297_351.port_a.T - TC_297_351.port_b.T; TC_297_351.port_a.Q_flow = TC_297_351.Q_flow; TC_297_351.port_b.Q_flow = -TC_297_351.Q_flow; TC_297_460.Q_flow = TC_297_460.G * TC_297_460.dT; TC_297_460.dT = TC_297_460.port_a.T - TC_297_460.port_b.T; TC_297_460.port_a.Q_flow = TC_297_460.Q_flow; TC_297_460.port_b.Q_flow = -TC_297_460.Q_flow; TC_297_1130.Q_flow = TC_297_1130.G * TC_297_1130.dT; TC_297_1130.dT = TC_297_1130.port_a.T - TC_297_1130.port_b.T; TC_297_1130.port_a.Q_flow = TC_297_1130.Q_flow; TC_297_1130.port_b.Q_flow = -TC_297_1130.Q_flow; TC_298_300.Q_flow = TC_298_300.G * TC_298_300.dT; TC_298_300.dT = TC_298_300.port_a.T - TC_298_300.port_b.T; TC_298_300.port_a.Q_flow = TC_298_300.Q_flow; TC_298_300.port_b.Q_flow = -TC_298_300.Q_flow; TC_298_352.Q_flow = TC_298_352.G * TC_298_352.dT; TC_298_352.dT = TC_298_352.port_a.T - TC_298_352.port_b.T; TC_298_352.port_a.Q_flow = TC_298_352.Q_flow; TC_298_352.port_b.Q_flow = -TC_298_352.Q_flow; TC_298_461.Q_flow = TC_298_461.G * TC_298_461.dT; TC_298_461.dT = TC_298_461.port_a.T - TC_298_461.port_b.T; TC_298_461.port_a.Q_flow = TC_298_461.Q_flow; TC_298_461.port_b.Q_flow = -TC_298_461.Q_flow; TC_298_1131.Q_flow = TC_298_1131.G * TC_298_1131.dT; TC_298_1131.dT = TC_298_1131.port_a.T - TC_298_1131.port_b.T; TC_298_1131.port_a.Q_flow = TC_298_1131.Q_flow; TC_298_1131.port_b.Q_flow = -TC_298_1131.Q_flow; TC_299_301.Q_flow = TC_299_301.G * TC_299_301.dT; TC_299_301.dT = TC_299_301.port_a.T - TC_299_301.port_b.T; TC_299_301.port_a.Q_flow = TC_299_301.Q_flow; TC_299_301.port_b.Q_flow = -TC_299_301.Q_flow; TC_299_353.Q_flow = TC_299_353.G * TC_299_353.dT; TC_299_353.dT = TC_299_353.port_a.T - TC_299_353.port_b.T; TC_299_353.port_a.Q_flow = TC_299_353.Q_flow; TC_299_353.port_b.Q_flow = -TC_299_353.Q_flow; TC_299_462.Q_flow = TC_299_462.G * TC_299_462.dT; TC_299_462.dT = TC_299_462.port_a.T - TC_299_462.port_b.T; TC_299_462.port_a.Q_flow = TC_299_462.Q_flow; TC_299_462.port_b.Q_flow = -TC_299_462.Q_flow; TC_299_1132.Q_flow = TC_299_1132.G * TC_299_1132.dT; TC_299_1132.dT = TC_299_1132.port_a.T - TC_299_1132.port_b.T; TC_299_1132.port_a.Q_flow = TC_299_1132.Q_flow; TC_299_1132.port_b.Q_flow = -TC_299_1132.Q_flow; TC_300_302.Q_flow = TC_300_302.G * TC_300_302.dT; TC_300_302.dT = TC_300_302.port_a.T - TC_300_302.port_b.T; TC_300_302.port_a.Q_flow = TC_300_302.Q_flow; TC_300_302.port_b.Q_flow = -TC_300_302.Q_flow; TC_300_354.Q_flow = TC_300_354.G * TC_300_354.dT; TC_300_354.dT = TC_300_354.port_a.T - TC_300_354.port_b.T; TC_300_354.port_a.Q_flow = TC_300_354.Q_flow; TC_300_354.port_b.Q_flow = -TC_300_354.Q_flow; TC_300_463.Q_flow = TC_300_463.G * TC_300_463.dT; TC_300_463.dT = TC_300_463.port_a.T - TC_300_463.port_b.T; TC_300_463.port_a.Q_flow = TC_300_463.Q_flow; TC_300_463.port_b.Q_flow = -TC_300_463.Q_flow; TC_300_1133.Q_flow = TC_300_1133.G * TC_300_1133.dT; TC_300_1133.dT = TC_300_1133.port_a.T - TC_300_1133.port_b.T; TC_300_1133.port_a.Q_flow = TC_300_1133.Q_flow; TC_300_1133.port_b.Q_flow = -TC_300_1133.Q_flow; TC_301_303.Q_flow = TC_301_303.G * TC_301_303.dT; TC_301_303.dT = TC_301_303.port_a.T - TC_301_303.port_b.T; TC_301_303.port_a.Q_flow = TC_301_303.Q_flow; TC_301_303.port_b.Q_flow = -TC_301_303.Q_flow; TC_301_355.Q_flow = TC_301_355.G * TC_301_355.dT; TC_301_355.dT = TC_301_355.port_a.T - TC_301_355.port_b.T; TC_301_355.port_a.Q_flow = TC_301_355.Q_flow; TC_301_355.port_b.Q_flow = -TC_301_355.Q_flow; TC_301_464.Q_flow = TC_301_464.G * TC_301_464.dT; TC_301_464.dT = TC_301_464.port_a.T - TC_301_464.port_b.T; TC_301_464.port_a.Q_flow = TC_301_464.Q_flow; TC_301_464.port_b.Q_flow = -TC_301_464.Q_flow; TC_301_1134.Q_flow = TC_301_1134.G * TC_301_1134.dT; TC_301_1134.dT = TC_301_1134.port_a.T - TC_301_1134.port_b.T; TC_301_1134.port_a.Q_flow = TC_301_1134.Q_flow; TC_301_1134.port_b.Q_flow = -TC_301_1134.Q_flow; TC_302_315.Q_flow = TC_302_315.G * TC_302_315.dT; TC_302_315.dT = TC_302_315.port_a.T - TC_302_315.port_b.T; TC_302_315.port_a.Q_flow = TC_302_315.Q_flow; TC_302_315.port_b.Q_flow = -TC_302_315.Q_flow; TC_302_356.Q_flow = TC_302_356.G * TC_302_356.dT; TC_302_356.dT = TC_302_356.port_a.T - TC_302_356.port_b.T; TC_302_356.port_a.Q_flow = TC_302_356.Q_flow; TC_302_356.port_b.Q_flow = -TC_302_356.Q_flow; TC_302_465.Q_flow = TC_302_465.G * TC_302_465.dT; TC_302_465.dT = TC_302_465.port_a.T - TC_302_465.port_b.T; TC_302_465.port_a.Q_flow = TC_302_465.Q_flow; TC_302_465.port_b.Q_flow = -TC_302_465.Q_flow; TC_302_1144.Q_flow = TC_302_1144.G * TC_302_1144.dT; TC_302_1144.dT = TC_302_1144.port_a.T - TC_302_1144.port_b.T; TC_302_1144.port_a.Q_flow = TC_302_1144.Q_flow; TC_302_1144.port_b.Q_flow = -TC_302_1144.Q_flow; TC_303_304.Q_flow = TC_303_304.G * TC_303_304.dT; TC_303_304.dT = TC_303_304.port_a.T - TC_303_304.port_b.T; TC_303_304.port_a.Q_flow = TC_303_304.Q_flow; TC_303_304.port_b.Q_flow = -TC_303_304.Q_flow; TC_303_357.Q_flow = TC_303_357.G * TC_303_357.dT; TC_303_357.dT = TC_303_357.port_a.T - TC_303_357.port_b.T; TC_303_357.port_a.Q_flow = TC_303_357.Q_flow; TC_303_357.port_b.Q_flow = -TC_303_357.Q_flow; TC_303_466.Q_flow = TC_303_466.G * TC_303_466.dT; TC_303_466.dT = TC_303_466.port_a.T - TC_303_466.port_b.T; TC_303_466.port_a.Q_flow = TC_303_466.Q_flow; TC_303_466.port_b.Q_flow = -TC_303_466.Q_flow; TC_304_305.Q_flow = TC_304_305.G * TC_304_305.dT; TC_304_305.dT = TC_304_305.port_a.T - TC_304_305.port_b.T; TC_304_305.port_a.Q_flow = TC_304_305.Q_flow; TC_304_305.port_b.Q_flow = -TC_304_305.Q_flow; TC_304_358.Q_flow = TC_304_358.G * TC_304_358.dT; TC_304_358.dT = TC_304_358.port_a.T - TC_304_358.port_b.T; TC_304_358.port_a.Q_flow = TC_304_358.Q_flow; TC_304_358.port_b.Q_flow = -TC_304_358.Q_flow; TC_304_467.Q_flow = TC_304_467.G * TC_304_467.dT; TC_304_467.dT = TC_304_467.port_a.T - TC_304_467.port_b.T; TC_304_467.port_a.Q_flow = TC_304_467.Q_flow; TC_304_467.port_b.Q_flow = -TC_304_467.Q_flow; TC_304_1134.Q_flow = TC_304_1134.G * TC_304_1134.dT; TC_304_1134.dT = TC_304_1134.port_a.T - TC_304_1134.port_b.T; TC_304_1134.port_a.Q_flow = TC_304_1134.Q_flow; TC_304_1134.port_b.Q_flow = -TC_304_1134.Q_flow; TC_305_306.Q_flow = TC_305_306.G * TC_305_306.dT; TC_305_306.dT = TC_305_306.port_a.T - TC_305_306.port_b.T; TC_305_306.port_a.Q_flow = TC_305_306.Q_flow; TC_305_306.port_b.Q_flow = -TC_305_306.Q_flow; TC_305_359.Q_flow = TC_305_359.G * TC_305_359.dT; TC_305_359.dT = TC_305_359.port_a.T - TC_305_359.port_b.T; TC_305_359.port_a.Q_flow = TC_305_359.Q_flow; TC_305_359.port_b.Q_flow = -TC_305_359.Q_flow; TC_305_468.Q_flow = TC_305_468.G * TC_305_468.dT; TC_305_468.dT = TC_305_468.port_a.T - TC_305_468.port_b.T; TC_305_468.port_a.Q_flow = TC_305_468.Q_flow; TC_305_468.port_b.Q_flow = -TC_305_468.Q_flow; TC_305_1135.Q_flow = TC_305_1135.G * TC_305_1135.dT; TC_305_1135.dT = TC_305_1135.port_a.T - TC_305_1135.port_b.T; TC_305_1135.port_a.Q_flow = TC_305_1135.Q_flow; TC_305_1135.port_b.Q_flow = -TC_305_1135.Q_flow; TC_306_307.Q_flow = TC_306_307.G * TC_306_307.dT; TC_306_307.dT = TC_306_307.port_a.T - TC_306_307.port_b.T; TC_306_307.port_a.Q_flow = TC_306_307.Q_flow; TC_306_307.port_b.Q_flow = -TC_306_307.Q_flow; TC_306_360.Q_flow = TC_306_360.G * TC_306_360.dT; TC_306_360.dT = TC_306_360.port_a.T - TC_306_360.port_b.T; TC_306_360.port_a.Q_flow = TC_306_360.Q_flow; TC_306_360.port_b.Q_flow = -TC_306_360.Q_flow; TC_306_469.Q_flow = TC_306_469.G * TC_306_469.dT; TC_306_469.dT = TC_306_469.port_a.T - TC_306_469.port_b.T; TC_306_469.port_a.Q_flow = TC_306_469.Q_flow; TC_306_469.port_b.Q_flow = -TC_306_469.Q_flow; TC_306_1136.Q_flow = TC_306_1136.G * TC_306_1136.dT; TC_306_1136.dT = TC_306_1136.port_a.T - TC_306_1136.port_b.T; TC_306_1136.port_a.Q_flow = TC_306_1136.Q_flow; TC_306_1136.port_b.Q_flow = -TC_306_1136.Q_flow; TC_307_308.Q_flow = TC_307_308.G * TC_307_308.dT; TC_307_308.dT = TC_307_308.port_a.T - TC_307_308.port_b.T; TC_307_308.port_a.Q_flow = TC_307_308.Q_flow; TC_307_308.port_b.Q_flow = -TC_307_308.Q_flow; TC_307_361.Q_flow = TC_307_361.G * TC_307_361.dT; TC_307_361.dT = TC_307_361.port_a.T - TC_307_361.port_b.T; TC_307_361.port_a.Q_flow = TC_307_361.Q_flow; TC_307_361.port_b.Q_flow = -TC_307_361.Q_flow; TC_307_470.Q_flow = TC_307_470.G * TC_307_470.dT; TC_307_470.dT = TC_307_470.port_a.T - TC_307_470.port_b.T; TC_307_470.port_a.Q_flow = TC_307_470.Q_flow; TC_307_470.port_b.Q_flow = -TC_307_470.Q_flow; TC_307_1137.Q_flow = TC_307_1137.G * TC_307_1137.dT; TC_307_1137.dT = TC_307_1137.port_a.T - TC_307_1137.port_b.T; TC_307_1137.port_a.Q_flow = TC_307_1137.Q_flow; TC_307_1137.port_b.Q_flow = -TC_307_1137.Q_flow; TC_308_309.Q_flow = TC_308_309.G * TC_308_309.dT; TC_308_309.dT = TC_308_309.port_a.T - TC_308_309.port_b.T; TC_308_309.port_a.Q_flow = TC_308_309.Q_flow; TC_308_309.port_b.Q_flow = -TC_308_309.Q_flow; TC_308_362.Q_flow = TC_308_362.G * TC_308_362.dT; TC_308_362.dT = TC_308_362.port_a.T - TC_308_362.port_b.T; TC_308_362.port_a.Q_flow = TC_308_362.Q_flow; TC_308_362.port_b.Q_flow = -TC_308_362.Q_flow; TC_308_471.Q_flow = TC_308_471.G * TC_308_471.dT; TC_308_471.dT = TC_308_471.port_a.T - TC_308_471.port_b.T; TC_308_471.port_a.Q_flow = TC_308_471.Q_flow; TC_308_471.port_b.Q_flow = -TC_308_471.Q_flow; TC_308_1138.Q_flow = TC_308_1138.G * TC_308_1138.dT; TC_308_1138.dT = TC_308_1138.port_a.T - TC_308_1138.port_b.T; TC_308_1138.port_a.Q_flow = TC_308_1138.Q_flow; TC_308_1138.port_b.Q_flow = -TC_308_1138.Q_flow; TC_309_310.Q_flow = TC_309_310.G * TC_309_310.dT; TC_309_310.dT = TC_309_310.port_a.T - TC_309_310.port_b.T; TC_309_310.port_a.Q_flow = TC_309_310.Q_flow; TC_309_310.port_b.Q_flow = -TC_309_310.Q_flow; TC_309_363.Q_flow = TC_309_363.G * TC_309_363.dT; TC_309_363.dT = TC_309_363.port_a.T - TC_309_363.port_b.T; TC_309_363.port_a.Q_flow = TC_309_363.Q_flow; TC_309_363.port_b.Q_flow = -TC_309_363.Q_flow; TC_309_472.Q_flow = TC_309_472.G * TC_309_472.dT; TC_309_472.dT = TC_309_472.port_a.T - TC_309_472.port_b.T; TC_309_472.port_a.Q_flow = TC_309_472.Q_flow; TC_309_472.port_b.Q_flow = -TC_309_472.Q_flow; TC_309_1139.Q_flow = TC_309_1139.G * TC_309_1139.dT; TC_309_1139.dT = TC_309_1139.port_a.T - TC_309_1139.port_b.T; TC_309_1139.port_a.Q_flow = TC_309_1139.Q_flow; TC_309_1139.port_b.Q_flow = -TC_309_1139.Q_flow; TC_310_311.Q_flow = TC_310_311.G * TC_310_311.dT; TC_310_311.dT = TC_310_311.port_a.T - TC_310_311.port_b.T; TC_310_311.port_a.Q_flow = TC_310_311.Q_flow; TC_310_311.port_b.Q_flow = -TC_310_311.Q_flow; TC_310_364.Q_flow = TC_310_364.G * TC_310_364.dT; TC_310_364.dT = TC_310_364.port_a.T - TC_310_364.port_b.T; TC_310_364.port_a.Q_flow = TC_310_364.Q_flow; TC_310_364.port_b.Q_flow = -TC_310_364.Q_flow; TC_310_473.Q_flow = TC_310_473.G * TC_310_473.dT; TC_310_473.dT = TC_310_473.port_a.T - TC_310_473.port_b.T; TC_310_473.port_a.Q_flow = TC_310_473.Q_flow; TC_310_473.port_b.Q_flow = -TC_310_473.Q_flow; TC_310_1140.Q_flow = TC_310_1140.G * TC_310_1140.dT; TC_310_1140.dT = TC_310_1140.port_a.T - TC_310_1140.port_b.T; TC_310_1140.port_a.Q_flow = TC_310_1140.Q_flow; TC_310_1140.port_b.Q_flow = -TC_310_1140.Q_flow; TC_311_312.Q_flow = TC_311_312.G * TC_311_312.dT; TC_311_312.dT = TC_311_312.port_a.T - TC_311_312.port_b.T; TC_311_312.port_a.Q_flow = TC_311_312.Q_flow; TC_311_312.port_b.Q_flow = -TC_311_312.Q_flow; TC_311_365.Q_flow = TC_311_365.G * TC_311_365.dT; TC_311_365.dT = TC_311_365.port_a.T - TC_311_365.port_b.T; TC_311_365.port_a.Q_flow = TC_311_365.Q_flow; TC_311_365.port_b.Q_flow = -TC_311_365.Q_flow; TC_311_474.Q_flow = TC_311_474.G * TC_311_474.dT; TC_311_474.dT = TC_311_474.port_a.T - TC_311_474.port_b.T; TC_311_474.port_a.Q_flow = TC_311_474.Q_flow; TC_311_474.port_b.Q_flow = -TC_311_474.Q_flow; TC_311_1141.Q_flow = TC_311_1141.G * TC_311_1141.dT; TC_311_1141.dT = TC_311_1141.port_a.T - TC_311_1141.port_b.T; TC_311_1141.port_a.Q_flow = TC_311_1141.Q_flow; TC_311_1141.port_b.Q_flow = -TC_311_1141.Q_flow; TC_312_313.Q_flow = TC_312_313.G * TC_312_313.dT; TC_312_313.dT = TC_312_313.port_a.T - TC_312_313.port_b.T; TC_312_313.port_a.Q_flow = TC_312_313.Q_flow; TC_312_313.port_b.Q_flow = -TC_312_313.Q_flow; TC_312_366.Q_flow = TC_312_366.G * TC_312_366.dT; TC_312_366.dT = TC_312_366.port_a.T - TC_312_366.port_b.T; TC_312_366.port_a.Q_flow = TC_312_366.Q_flow; TC_312_366.port_b.Q_flow = -TC_312_366.Q_flow; TC_312_475.Q_flow = TC_312_475.G * TC_312_475.dT; TC_312_475.dT = TC_312_475.port_a.T - TC_312_475.port_b.T; TC_312_475.port_a.Q_flow = TC_312_475.Q_flow; TC_312_475.port_b.Q_flow = -TC_312_475.Q_flow; TC_312_1142.Q_flow = TC_312_1142.G * TC_312_1142.dT; TC_312_1142.dT = TC_312_1142.port_a.T - TC_312_1142.port_b.T; TC_312_1142.port_a.Q_flow = TC_312_1142.Q_flow; TC_312_1142.port_b.Q_flow = -TC_312_1142.Q_flow; TC_313_314.Q_flow = TC_313_314.G * TC_313_314.dT; TC_313_314.dT = TC_313_314.port_a.T - TC_313_314.port_b.T; TC_313_314.port_a.Q_flow = TC_313_314.Q_flow; TC_313_314.port_b.Q_flow = -TC_313_314.Q_flow; TC_313_367.Q_flow = TC_313_367.G * TC_313_367.dT; TC_313_367.dT = TC_313_367.port_a.T - TC_313_367.port_b.T; TC_313_367.port_a.Q_flow = TC_313_367.Q_flow; TC_313_367.port_b.Q_flow = -TC_313_367.Q_flow; TC_313_476.Q_flow = TC_313_476.G * TC_313_476.dT; TC_313_476.dT = TC_313_476.port_a.T - TC_313_476.port_b.T; TC_313_476.port_a.Q_flow = TC_313_476.Q_flow; TC_313_476.port_b.Q_flow = -TC_313_476.Q_flow; TC_313_1143.Q_flow = TC_313_1143.G * TC_313_1143.dT; TC_313_1143.dT = TC_313_1143.port_a.T - TC_313_1143.port_b.T; TC_313_1143.port_a.Q_flow = TC_313_1143.Q_flow; TC_313_1143.port_b.Q_flow = -TC_313_1143.Q_flow; TC_314_315.Q_flow = TC_314_315.G * TC_314_315.dT; TC_314_315.dT = TC_314_315.port_a.T - TC_314_315.port_b.T; TC_314_315.port_a.Q_flow = TC_314_315.Q_flow; TC_314_315.port_b.Q_flow = -TC_314_315.Q_flow; TC_314_368.Q_flow = TC_314_368.G * TC_314_368.dT; TC_314_368.dT = TC_314_368.port_a.T - TC_314_368.port_b.T; TC_314_368.port_a.Q_flow = TC_314_368.Q_flow; TC_314_368.port_b.Q_flow = -TC_314_368.Q_flow; TC_314_477.Q_flow = TC_314_477.G * TC_314_477.dT; TC_314_477.dT = TC_314_477.port_a.T - TC_314_477.port_b.T; TC_314_477.port_a.Q_flow = TC_314_477.Q_flow; TC_314_477.port_b.Q_flow = -TC_314_477.Q_flow; TC_314_1144.Q_flow = TC_314_1144.G * TC_314_1144.dT; TC_314_1144.dT = TC_314_1144.port_a.T - TC_314_1144.port_b.T; TC_314_1144.port_a.Q_flow = TC_314_1144.Q_flow; TC_314_1144.port_b.Q_flow = -TC_314_1144.Q_flow; TC_315_369.Q_flow = TC_315_369.G * TC_315_369.dT; TC_315_369.dT = TC_315_369.port_a.T - TC_315_369.port_b.T; TC_315_369.port_a.Q_flow = TC_315_369.Q_flow; TC_315_369.port_b.Q_flow = -TC_315_369.Q_flow; TC_315_478.Q_flow = TC_315_478.G * TC_315_478.dT; TC_315_478.dT = TC_315_478.port_a.T - TC_315_478.port_b.T; TC_315_478.port_a.Q_flow = TC_315_478.Q_flow; TC_315_478.port_b.Q_flow = -TC_315_478.Q_flow; TC_316_317.Q_flow = TC_316_317.G * TC_316_317.dT; TC_316_317.dT = TC_316_317.port_a.T - TC_316_317.port_b.T; TC_316_317.port_a.Q_flow = TC_316_317.Q_flow; TC_316_317.port_b.Q_flow = -TC_316_317.Q_flow; TC_316_329.Q_flow = TC_316_329.G * TC_316_329.dT; TC_316_329.dT = TC_316_329.port_a.T - TC_316_329.port_b.T; TC_316_329.port_a.Q_flow = TC_316_329.Q_flow; TC_316_329.port_b.Q_flow = -TC_316_329.Q_flow; TC_316_370.Q_flow = TC_316_370.G * TC_316_370.dT; TC_316_370.dT = TC_316_370.port_a.T - TC_316_370.port_b.T; TC_316_370.port_a.Q_flow = TC_316_370.Q_flow; TC_316_370.port_b.Q_flow = -TC_316_370.Q_flow; TC_317_318.Q_flow = TC_317_318.G * TC_317_318.dT; TC_317_318.dT = TC_317_318.port_a.T - TC_317_318.port_b.T; TC_317_318.port_a.Q_flow = TC_317_318.Q_flow; TC_317_318.port_b.Q_flow = -TC_317_318.Q_flow; TC_317_371.Q_flow = TC_317_371.G * TC_317_371.dT; TC_317_371.dT = TC_317_371.port_a.T - TC_317_371.port_b.T; TC_317_371.port_a.Q_flow = TC_317_371.Q_flow; TC_317_371.port_b.Q_flow = -TC_317_371.Q_flow; TC_317_1145.Q_flow = TC_317_1145.G * TC_317_1145.dT; TC_317_1145.dT = TC_317_1145.port_a.T - TC_317_1145.port_b.T; TC_317_1145.port_a.Q_flow = TC_317_1145.Q_flow; TC_317_1145.port_b.Q_flow = -TC_317_1145.Q_flow; TC_318_319.Q_flow = TC_318_319.G * TC_318_319.dT; TC_318_319.dT = TC_318_319.port_a.T - TC_318_319.port_b.T; TC_318_319.port_a.Q_flow = TC_318_319.Q_flow; TC_318_319.port_b.Q_flow = -TC_318_319.Q_flow; TC_318_372.Q_flow = TC_318_372.G * TC_318_372.dT; TC_318_372.dT = TC_318_372.port_a.T - TC_318_372.port_b.T; TC_318_372.port_a.Q_flow = TC_318_372.Q_flow; TC_318_372.port_b.Q_flow = -TC_318_372.Q_flow; TC_318_1146.Q_flow = TC_318_1146.G * TC_318_1146.dT; TC_318_1146.dT = TC_318_1146.port_a.T - TC_318_1146.port_b.T; TC_318_1146.port_a.Q_flow = TC_318_1146.Q_flow; TC_318_1146.port_b.Q_flow = -TC_318_1146.Q_flow; TC_319_320.Q_flow = TC_319_320.G * TC_319_320.dT; TC_319_320.dT = TC_319_320.port_a.T - TC_319_320.port_b.T; TC_319_320.port_a.Q_flow = TC_319_320.Q_flow; TC_319_320.port_b.Q_flow = -TC_319_320.Q_flow; TC_319_373.Q_flow = TC_319_373.G * TC_319_373.dT; TC_319_373.dT = TC_319_373.port_a.T - TC_319_373.port_b.T; TC_319_373.port_a.Q_flow = TC_319_373.Q_flow; TC_319_373.port_b.Q_flow = -TC_319_373.Q_flow; TC_319_1147.Q_flow = TC_319_1147.G * TC_319_1147.dT; TC_319_1147.dT = TC_319_1147.port_a.T - TC_319_1147.port_b.T; TC_319_1147.port_a.Q_flow = TC_319_1147.Q_flow; TC_319_1147.port_b.Q_flow = -TC_319_1147.Q_flow; TC_320_321.Q_flow = TC_320_321.G * TC_320_321.dT; TC_320_321.dT = TC_320_321.port_a.T - TC_320_321.port_b.T; TC_320_321.port_a.Q_flow = TC_320_321.Q_flow; TC_320_321.port_b.Q_flow = -TC_320_321.Q_flow; TC_320_374.Q_flow = TC_320_374.G * TC_320_374.dT; TC_320_374.dT = TC_320_374.port_a.T - TC_320_374.port_b.T; TC_320_374.port_a.Q_flow = TC_320_374.Q_flow; TC_320_374.port_b.Q_flow = -TC_320_374.Q_flow; TC_320_1148.Q_flow = TC_320_1148.G * TC_320_1148.dT; TC_320_1148.dT = TC_320_1148.port_a.T - TC_320_1148.port_b.T; TC_320_1148.port_a.Q_flow = TC_320_1148.Q_flow; TC_320_1148.port_b.Q_flow = -TC_320_1148.Q_flow; TC_321_322.Q_flow = TC_321_322.G * TC_321_322.dT; TC_321_322.dT = TC_321_322.port_a.T - TC_321_322.port_b.T; TC_321_322.port_a.Q_flow = TC_321_322.Q_flow; TC_321_322.port_b.Q_flow = -TC_321_322.Q_flow; TC_321_375.Q_flow = TC_321_375.G * TC_321_375.dT; TC_321_375.dT = TC_321_375.port_a.T - TC_321_375.port_b.T; TC_321_375.port_a.Q_flow = TC_321_375.Q_flow; TC_321_375.port_b.Q_flow = -TC_321_375.Q_flow; TC_321_1149.Q_flow = TC_321_1149.G * TC_321_1149.dT; TC_321_1149.dT = TC_321_1149.port_a.T - TC_321_1149.port_b.T; TC_321_1149.port_a.Q_flow = TC_321_1149.Q_flow; TC_321_1149.port_b.Q_flow = -TC_321_1149.Q_flow; TC_322_323.Q_flow = TC_322_323.G * TC_322_323.dT; TC_322_323.dT = TC_322_323.port_a.T - TC_322_323.port_b.T; TC_322_323.port_a.Q_flow = TC_322_323.Q_flow; TC_322_323.port_b.Q_flow = -TC_322_323.Q_flow; TC_322_376.Q_flow = TC_322_376.G * TC_322_376.dT; TC_322_376.dT = TC_322_376.port_a.T - TC_322_376.port_b.T; TC_322_376.port_a.Q_flow = TC_322_376.Q_flow; TC_322_376.port_b.Q_flow = -TC_322_376.Q_flow; TC_322_1150.Q_flow = TC_322_1150.G * TC_322_1150.dT; TC_322_1150.dT = TC_322_1150.port_a.T - TC_322_1150.port_b.T; TC_322_1150.port_a.Q_flow = TC_322_1150.Q_flow; TC_322_1150.port_b.Q_flow = -TC_322_1150.Q_flow; TC_323_324.Q_flow = TC_323_324.G * TC_323_324.dT; TC_323_324.dT = TC_323_324.port_a.T - TC_323_324.port_b.T; TC_323_324.port_a.Q_flow = TC_323_324.Q_flow; TC_323_324.port_b.Q_flow = -TC_323_324.Q_flow; TC_323_377.Q_flow = TC_323_377.G * TC_323_377.dT; TC_323_377.dT = TC_323_377.port_a.T - TC_323_377.port_b.T; TC_323_377.port_a.Q_flow = TC_323_377.Q_flow; TC_323_377.port_b.Q_flow = -TC_323_377.Q_flow; TC_323_1151.Q_flow = TC_323_1151.G * TC_323_1151.dT; TC_323_1151.dT = TC_323_1151.port_a.T - TC_323_1151.port_b.T; TC_323_1151.port_a.Q_flow = TC_323_1151.Q_flow; TC_323_1151.port_b.Q_flow = -TC_323_1151.Q_flow; TC_324_325.Q_flow = TC_324_325.G * TC_324_325.dT; TC_324_325.dT = TC_324_325.port_a.T - TC_324_325.port_b.T; TC_324_325.port_a.Q_flow = TC_324_325.Q_flow; TC_324_325.port_b.Q_flow = -TC_324_325.Q_flow; TC_324_378.Q_flow = TC_324_378.G * TC_324_378.dT; TC_324_378.dT = TC_324_378.port_a.T - TC_324_378.port_b.T; TC_324_378.port_a.Q_flow = TC_324_378.Q_flow; TC_324_378.port_b.Q_flow = -TC_324_378.Q_flow; TC_324_1152.Q_flow = TC_324_1152.G * TC_324_1152.dT; TC_324_1152.dT = TC_324_1152.port_a.T - TC_324_1152.port_b.T; TC_324_1152.port_a.Q_flow = TC_324_1152.Q_flow; TC_324_1152.port_b.Q_flow = -TC_324_1152.Q_flow; TC_325_326.Q_flow = TC_325_326.G * TC_325_326.dT; TC_325_326.dT = TC_325_326.port_a.T - TC_325_326.port_b.T; TC_325_326.port_a.Q_flow = TC_325_326.Q_flow; TC_325_326.port_b.Q_flow = -TC_325_326.Q_flow; TC_325_379.Q_flow = TC_325_379.G * TC_325_379.dT; TC_325_379.dT = TC_325_379.port_a.T - TC_325_379.port_b.T; TC_325_379.port_a.Q_flow = TC_325_379.Q_flow; TC_325_379.port_b.Q_flow = -TC_325_379.Q_flow; TC_325_1153.Q_flow = TC_325_1153.G * TC_325_1153.dT; TC_325_1153.dT = TC_325_1153.port_a.T - TC_325_1153.port_b.T; TC_325_1153.port_a.Q_flow = TC_325_1153.Q_flow; TC_325_1153.port_b.Q_flow = -TC_325_1153.Q_flow; TC_326_327.Q_flow = TC_326_327.G * TC_326_327.dT; TC_326_327.dT = TC_326_327.port_a.T - TC_326_327.port_b.T; TC_326_327.port_a.Q_flow = TC_326_327.Q_flow; TC_326_327.port_b.Q_flow = -TC_326_327.Q_flow; TC_326_380.Q_flow = TC_326_380.G * TC_326_380.dT; TC_326_380.dT = TC_326_380.port_a.T - TC_326_380.port_b.T; TC_326_380.port_a.Q_flow = TC_326_380.Q_flow; TC_326_380.port_b.Q_flow = -TC_326_380.Q_flow; TC_326_1154.Q_flow = TC_326_1154.G * TC_326_1154.dT; TC_326_1154.dT = TC_326_1154.port_a.T - TC_326_1154.port_b.T; TC_326_1154.port_a.Q_flow = TC_326_1154.Q_flow; TC_326_1154.port_b.Q_flow = -TC_326_1154.Q_flow; TC_327_328.Q_flow = TC_327_328.G * TC_327_328.dT; TC_327_328.dT = TC_327_328.port_a.T - TC_327_328.port_b.T; TC_327_328.port_a.Q_flow = TC_327_328.Q_flow; TC_327_328.port_b.Q_flow = -TC_327_328.Q_flow; TC_327_381.Q_flow = TC_327_381.G * TC_327_381.dT; TC_327_381.dT = TC_327_381.port_a.T - TC_327_381.port_b.T; TC_327_381.port_a.Q_flow = TC_327_381.Q_flow; TC_327_381.port_b.Q_flow = -TC_327_381.Q_flow; TC_327_1155.Q_flow = TC_327_1155.G * TC_327_1155.dT; TC_327_1155.dT = TC_327_1155.port_a.T - TC_327_1155.port_b.T; TC_327_1155.port_a.Q_flow = TC_327_1155.Q_flow; TC_327_1155.port_b.Q_flow = -TC_327_1155.Q_flow; TC_328_330.Q_flow = TC_328_330.G * TC_328_330.dT; TC_328_330.dT = TC_328_330.port_a.T - TC_328_330.port_b.T; TC_328_330.port_a.Q_flow = TC_328_330.Q_flow; TC_328_330.port_b.Q_flow = -TC_328_330.Q_flow; TC_328_382.Q_flow = TC_328_382.G * TC_328_382.dT; TC_328_382.dT = TC_328_382.port_a.T - TC_328_382.port_b.T; TC_328_382.port_a.Q_flow = TC_328_382.Q_flow; TC_328_382.port_b.Q_flow = -TC_328_382.Q_flow; TC_329_331.Q_flow = TC_329_331.G * TC_329_331.dT; TC_329_331.dT = TC_329_331.port_a.T - TC_329_331.port_b.T; TC_329_331.port_a.Q_flow = TC_329_331.Q_flow; TC_329_331.port_b.Q_flow = -TC_329_331.Q_flow; TC_329_383.Q_flow = TC_329_383.G * TC_329_383.dT; TC_329_383.dT = TC_329_383.port_a.T - TC_329_383.port_b.T; TC_329_383.port_a.Q_flow = TC_329_383.Q_flow; TC_329_383.port_b.Q_flow = -TC_329_383.Q_flow; TC_329_1145.Q_flow = TC_329_1145.G * TC_329_1145.dT; TC_329_1145.dT = TC_329_1145.port_a.T - TC_329_1145.port_b.T; TC_329_1145.port_a.Q_flow = TC_329_1145.Q_flow; TC_329_1145.port_b.Q_flow = -TC_329_1145.Q_flow; TC_330_332.Q_flow = TC_330_332.G * TC_330_332.dT; TC_330_332.dT = TC_330_332.port_a.T - TC_330_332.port_b.T; TC_330_332.port_a.Q_flow = TC_330_332.Q_flow; TC_330_332.port_b.Q_flow = -TC_330_332.Q_flow; TC_330_384.Q_flow = TC_330_384.G * TC_330_384.dT; TC_330_384.dT = TC_330_384.port_a.T - TC_330_384.port_b.T; TC_330_384.port_a.Q_flow = TC_330_384.Q_flow; TC_330_384.port_b.Q_flow = -TC_330_384.Q_flow; TC_330_1155.Q_flow = TC_330_1155.G * TC_330_1155.dT; TC_330_1155.dT = TC_330_1155.port_a.T - TC_330_1155.port_b.T; TC_330_1155.port_a.Q_flow = TC_330_1155.Q_flow; TC_330_1155.port_b.Q_flow = -TC_330_1155.Q_flow; TC_331_333.Q_flow = TC_331_333.G * TC_331_333.dT; TC_331_333.dT = TC_331_333.port_a.T - TC_331_333.port_b.T; TC_331_333.port_a.Q_flow = TC_331_333.Q_flow; TC_331_333.port_b.Q_flow = -TC_331_333.Q_flow; TC_331_385.Q_flow = TC_331_385.G * TC_331_385.dT; TC_331_385.dT = TC_331_385.port_a.T - TC_331_385.port_b.T; TC_331_385.port_a.Q_flow = TC_331_385.Q_flow; TC_331_385.port_b.Q_flow = -TC_331_385.Q_flow; TC_331_1156.Q_flow = TC_331_1156.G * TC_331_1156.dT; TC_331_1156.dT = TC_331_1156.port_a.T - TC_331_1156.port_b.T; TC_331_1156.port_a.Q_flow = TC_331_1156.Q_flow; TC_331_1156.port_b.Q_flow = -TC_331_1156.Q_flow; TC_332_334.Q_flow = TC_332_334.G * TC_332_334.dT; TC_332_334.dT = TC_332_334.port_a.T - TC_332_334.port_b.T; TC_332_334.port_a.Q_flow = TC_332_334.Q_flow; TC_332_334.port_b.Q_flow = -TC_332_334.Q_flow; TC_332_386.Q_flow = TC_332_386.G * TC_332_386.dT; TC_332_386.dT = TC_332_386.port_a.T - TC_332_386.port_b.T; TC_332_386.port_a.Q_flow = TC_332_386.Q_flow; TC_332_386.port_b.Q_flow = -TC_332_386.Q_flow; TC_332_1166.Q_flow = TC_332_1166.G * TC_332_1166.dT; TC_332_1166.dT = TC_332_1166.port_a.T - TC_332_1166.port_b.T; TC_332_1166.port_a.Q_flow = TC_332_1166.Q_flow; TC_332_1166.port_b.Q_flow = -TC_332_1166.Q_flow; TC_333_335.Q_flow = TC_333_335.G * TC_333_335.dT; TC_333_335.dT = TC_333_335.port_a.T - TC_333_335.port_b.T; TC_333_335.port_a.Q_flow = TC_333_335.Q_flow; TC_333_335.port_b.Q_flow = -TC_333_335.Q_flow; TC_333_387.Q_flow = TC_333_387.G * TC_333_387.dT; TC_333_387.dT = TC_333_387.port_a.T - TC_333_387.port_b.T; TC_333_387.port_a.Q_flow = TC_333_387.Q_flow; TC_333_387.port_b.Q_flow = -TC_333_387.Q_flow; TC_333_1167.Q_flow = TC_333_1167.G * TC_333_1167.dT; TC_333_1167.dT = TC_333_1167.port_a.T - TC_333_1167.port_b.T; TC_333_1167.port_a.Q_flow = TC_333_1167.Q_flow; TC_333_1167.port_b.Q_flow = -TC_333_1167.Q_flow; TC_334_336.Q_flow = TC_334_336.G * TC_334_336.dT; TC_334_336.dT = TC_334_336.port_a.T - TC_334_336.port_b.T; TC_334_336.port_a.Q_flow = TC_334_336.Q_flow; TC_334_336.port_b.Q_flow = -TC_334_336.Q_flow; TC_334_388.Q_flow = TC_334_388.G * TC_334_388.dT; TC_334_388.dT = TC_334_388.port_a.T - TC_334_388.port_b.T; TC_334_388.port_a.Q_flow = TC_334_388.Q_flow; TC_334_388.port_b.Q_flow = -TC_334_388.Q_flow; TC_334_1173.Q_flow = TC_334_1173.G * TC_334_1173.dT; TC_334_1173.dT = TC_334_1173.port_a.T - TC_334_1173.port_b.T; TC_334_1173.port_a.Q_flow = TC_334_1173.Q_flow; TC_334_1173.port_b.Q_flow = -TC_334_1173.Q_flow; TC_335_337.Q_flow = TC_335_337.G * TC_335_337.dT; TC_335_337.dT = TC_335_337.port_a.T - TC_335_337.port_b.T; TC_335_337.port_a.Q_flow = TC_335_337.Q_flow; TC_335_337.port_b.Q_flow = -TC_335_337.Q_flow; TC_335_389.Q_flow = TC_335_389.G * TC_335_389.dT; TC_335_389.dT = TC_335_389.port_a.T - TC_335_389.port_b.T; TC_335_389.port_a.Q_flow = TC_335_389.Q_flow; TC_335_389.port_b.Q_flow = -TC_335_389.Q_flow; TC_335_1174.Q_flow = TC_335_1174.G * TC_335_1174.dT; TC_335_1174.dT = TC_335_1174.port_a.T - TC_335_1174.port_b.T; TC_335_1174.port_a.Q_flow = TC_335_1174.Q_flow; TC_335_1174.port_b.Q_flow = -TC_335_1174.Q_flow; TC_336_338.Q_flow = TC_336_338.G * TC_336_338.dT; TC_336_338.dT = TC_336_338.port_a.T - TC_336_338.port_b.T; TC_336_338.port_a.Q_flow = TC_336_338.Q_flow; TC_336_338.port_b.Q_flow = -TC_336_338.Q_flow; TC_336_390.Q_flow = TC_336_390.G * TC_336_390.dT; TC_336_390.dT = TC_336_390.port_a.T - TC_336_390.port_b.T; TC_336_390.port_a.Q_flow = TC_336_390.Q_flow; TC_336_390.port_b.Q_flow = -TC_336_390.Q_flow; TC_336_1180.Q_flow = TC_336_1180.G * TC_336_1180.dT; TC_336_1180.dT = TC_336_1180.port_a.T - TC_336_1180.port_b.T; TC_336_1180.port_a.Q_flow = TC_336_1180.Q_flow; TC_336_1180.port_b.Q_flow = -TC_336_1180.Q_flow; TC_337_339.Q_flow = TC_337_339.G * TC_337_339.dT; TC_337_339.dT = TC_337_339.port_a.T - TC_337_339.port_b.T; TC_337_339.port_a.Q_flow = TC_337_339.Q_flow; TC_337_339.port_b.Q_flow = -TC_337_339.Q_flow; TC_337_391.Q_flow = TC_337_391.G * TC_337_391.dT; TC_337_391.dT = TC_337_391.port_a.T - TC_337_391.port_b.T; TC_337_391.port_a.Q_flow = TC_337_391.Q_flow; TC_337_391.port_b.Q_flow = -TC_337_391.Q_flow; TC_337_1181.Q_flow = TC_337_1181.G * TC_337_1181.dT; TC_337_1181.dT = TC_337_1181.port_a.T - TC_337_1181.port_b.T; TC_337_1181.port_a.Q_flow = TC_337_1181.Q_flow; TC_337_1181.port_b.Q_flow = -TC_337_1181.Q_flow; TC_338_340.Q_flow = TC_338_340.G * TC_338_340.dT; TC_338_340.dT = TC_338_340.port_a.T - TC_338_340.port_b.T; TC_338_340.port_a.Q_flow = TC_338_340.Q_flow; TC_338_340.port_b.Q_flow = -TC_338_340.Q_flow; TC_338_392.Q_flow = TC_338_392.G * TC_338_392.dT; TC_338_392.dT = TC_338_392.port_a.T - TC_338_392.port_b.T; TC_338_392.port_a.Q_flow = TC_338_392.Q_flow; TC_338_392.port_b.Q_flow = -TC_338_392.Q_flow; TC_338_1187.Q_flow = TC_338_1187.G * TC_338_1187.dT; TC_338_1187.dT = TC_338_1187.port_a.T - TC_338_1187.port_b.T; TC_338_1187.port_a.Q_flow = TC_338_1187.Q_flow; TC_338_1187.port_b.Q_flow = -TC_338_1187.Q_flow; TC_339_341.Q_flow = TC_339_341.G * TC_339_341.dT; TC_339_341.dT = TC_339_341.port_a.T - TC_339_341.port_b.T; TC_339_341.port_a.Q_flow = TC_339_341.Q_flow; TC_339_341.port_b.Q_flow = -TC_339_341.Q_flow; TC_339_393.Q_flow = TC_339_393.G * TC_339_393.dT; TC_339_393.dT = TC_339_393.port_a.T - TC_339_393.port_b.T; TC_339_393.port_a.Q_flow = TC_339_393.Q_flow; TC_339_393.port_b.Q_flow = -TC_339_393.Q_flow; TC_339_1188.Q_flow = TC_339_1188.G * TC_339_1188.dT; TC_339_1188.dT = TC_339_1188.port_a.T - TC_339_1188.port_b.T; TC_339_1188.port_a.Q_flow = TC_339_1188.Q_flow; TC_339_1188.port_b.Q_flow = -TC_339_1188.Q_flow; TC_340_342.Q_flow = TC_340_342.G * TC_340_342.dT; TC_340_342.dT = TC_340_342.port_a.T - TC_340_342.port_b.T; TC_340_342.port_a.Q_flow = TC_340_342.Q_flow; TC_340_342.port_b.Q_flow = -TC_340_342.Q_flow; TC_340_394.Q_flow = TC_340_394.G * TC_340_394.dT; TC_340_394.dT = TC_340_394.port_a.T - TC_340_394.port_b.T; TC_340_394.port_a.Q_flow = TC_340_394.Q_flow; TC_340_394.port_b.Q_flow = -TC_340_394.Q_flow; TC_340_1198.Q_flow = TC_340_1198.G * TC_340_1198.dT; TC_340_1198.dT = TC_340_1198.port_a.T - TC_340_1198.port_b.T; TC_340_1198.port_a.Q_flow = TC_340_1198.Q_flow; TC_340_1198.port_b.Q_flow = -TC_340_1198.Q_flow; TC_341_343.Q_flow = TC_341_343.G * TC_341_343.dT; TC_341_343.dT = TC_341_343.port_a.T - TC_341_343.port_b.T; TC_341_343.port_a.Q_flow = TC_341_343.Q_flow; TC_341_343.port_b.Q_flow = -TC_341_343.Q_flow; TC_341_395.Q_flow = TC_341_395.G * TC_341_395.dT; TC_341_395.dT = TC_341_395.port_a.T - TC_341_395.port_b.T; TC_341_395.port_a.Q_flow = TC_341_395.Q_flow; TC_341_395.port_b.Q_flow = -TC_341_395.Q_flow; TC_341_1199.Q_flow = TC_341_1199.G * TC_341_1199.dT; TC_341_1199.dT = TC_341_1199.port_a.T - TC_341_1199.port_b.T; TC_341_1199.port_a.Q_flow = TC_341_1199.Q_flow; TC_341_1199.port_b.Q_flow = -TC_341_1199.Q_flow; TC_342_344.Q_flow = TC_342_344.G * TC_342_344.dT; TC_342_344.dT = TC_342_344.port_a.T - TC_342_344.port_b.T; TC_342_344.port_a.Q_flow = TC_342_344.Q_flow; TC_342_344.port_b.Q_flow = -TC_342_344.Q_flow; TC_342_396.Q_flow = TC_342_396.G * TC_342_396.dT; TC_342_396.dT = TC_342_396.port_a.T - TC_342_396.port_b.T; TC_342_396.port_a.Q_flow = TC_342_396.Q_flow; TC_342_396.port_b.Q_flow = -TC_342_396.Q_flow; TC_342_1206.Q_flow = TC_342_1206.G * TC_342_1206.dT; TC_342_1206.dT = TC_342_1206.port_a.T - TC_342_1206.port_b.T; TC_342_1206.port_a.Q_flow = TC_342_1206.Q_flow; TC_342_1206.port_b.Q_flow = -TC_342_1206.Q_flow; TC_343_345.Q_flow = TC_343_345.G * TC_343_345.dT; TC_343_345.dT = TC_343_345.port_a.T - TC_343_345.port_b.T; TC_343_345.port_a.Q_flow = TC_343_345.Q_flow; TC_343_345.port_b.Q_flow = -TC_343_345.Q_flow; TC_343_397.Q_flow = TC_343_397.G * TC_343_397.dT; TC_343_397.dT = TC_343_397.port_a.T - TC_343_397.port_b.T; TC_343_397.port_a.Q_flow = TC_343_397.Q_flow; TC_343_397.port_b.Q_flow = -TC_343_397.Q_flow; TC_343_1207.Q_flow = TC_343_1207.G * TC_343_1207.dT; TC_343_1207.dT = TC_343_1207.port_a.T - TC_343_1207.port_b.T; TC_343_1207.port_a.Q_flow = TC_343_1207.Q_flow; TC_343_1207.port_b.Q_flow = -TC_343_1207.Q_flow; TC_344_346.Q_flow = TC_344_346.G * TC_344_346.dT; TC_344_346.dT = TC_344_346.port_a.T - TC_344_346.port_b.T; TC_344_346.port_a.Q_flow = TC_344_346.Q_flow; TC_344_346.port_b.Q_flow = -TC_344_346.Q_flow; TC_344_398.Q_flow = TC_344_398.G * TC_344_398.dT; TC_344_398.dT = TC_344_398.port_a.T - TC_344_398.port_b.T; TC_344_398.port_a.Q_flow = TC_344_398.Q_flow; TC_344_398.port_b.Q_flow = -TC_344_398.Q_flow; TC_344_1214.Q_flow = TC_344_1214.G * TC_344_1214.dT; TC_344_1214.dT = TC_344_1214.port_a.T - TC_344_1214.port_b.T; TC_344_1214.port_a.Q_flow = TC_344_1214.Q_flow; TC_344_1214.port_b.Q_flow = -TC_344_1214.Q_flow; TC_345_347.Q_flow = TC_345_347.G * TC_345_347.dT; TC_345_347.dT = TC_345_347.port_a.T - TC_345_347.port_b.T; TC_345_347.port_a.Q_flow = TC_345_347.Q_flow; TC_345_347.port_b.Q_flow = -TC_345_347.Q_flow; TC_345_399.Q_flow = TC_345_399.G * TC_345_399.dT; TC_345_399.dT = TC_345_399.port_a.T - TC_345_399.port_b.T; TC_345_399.port_a.Q_flow = TC_345_399.Q_flow; TC_345_399.port_b.Q_flow = -TC_345_399.Q_flow; TC_345_1215.Q_flow = TC_345_1215.G * TC_345_1215.dT; TC_345_1215.dT = TC_345_1215.port_a.T - TC_345_1215.port_b.T; TC_345_1215.port_a.Q_flow = TC_345_1215.Q_flow; TC_345_1215.port_b.Q_flow = -TC_345_1215.Q_flow; TC_346_348.Q_flow = TC_346_348.G * TC_346_348.dT; TC_346_348.dT = TC_346_348.port_a.T - TC_346_348.port_b.T; TC_346_348.port_a.Q_flow = TC_346_348.Q_flow; TC_346_348.port_b.Q_flow = -TC_346_348.Q_flow; TC_346_400.Q_flow = TC_346_400.G * TC_346_400.dT; TC_346_400.dT = TC_346_400.port_a.T - TC_346_400.port_b.T; TC_346_400.port_a.Q_flow = TC_346_400.Q_flow; TC_346_400.port_b.Q_flow = -TC_346_400.Q_flow; TC_346_1222.Q_flow = TC_346_1222.G * TC_346_1222.dT; TC_346_1222.dT = TC_346_1222.port_a.T - TC_346_1222.port_b.T; TC_346_1222.port_a.Q_flow = TC_346_1222.Q_flow; TC_346_1222.port_b.Q_flow = -TC_346_1222.Q_flow; TC_347_349.Q_flow = TC_347_349.G * TC_347_349.dT; TC_347_349.dT = TC_347_349.port_a.T - TC_347_349.port_b.T; TC_347_349.port_a.Q_flow = TC_347_349.Q_flow; TC_347_349.port_b.Q_flow = -TC_347_349.Q_flow; TC_347_401.Q_flow = TC_347_401.G * TC_347_401.dT; TC_347_401.dT = TC_347_401.port_a.T - TC_347_401.port_b.T; TC_347_401.port_a.Q_flow = TC_347_401.Q_flow; TC_347_401.port_b.Q_flow = -TC_347_401.Q_flow; TC_347_1223.Q_flow = TC_347_1223.G * TC_347_1223.dT; TC_347_1223.dT = TC_347_1223.port_a.T - TC_347_1223.port_b.T; TC_347_1223.port_a.Q_flow = TC_347_1223.Q_flow; TC_347_1223.port_b.Q_flow = -TC_347_1223.Q_flow; TC_348_350.Q_flow = TC_348_350.G * TC_348_350.dT; TC_348_350.dT = TC_348_350.port_a.T - TC_348_350.port_b.T; TC_348_350.port_a.Q_flow = TC_348_350.Q_flow; TC_348_350.port_b.Q_flow = -TC_348_350.Q_flow; TC_348_402.Q_flow = TC_348_402.G * TC_348_402.dT; TC_348_402.dT = TC_348_402.port_a.T - TC_348_402.port_b.T; TC_348_402.port_a.Q_flow = TC_348_402.Q_flow; TC_348_402.port_b.Q_flow = -TC_348_402.Q_flow; TC_348_1230.Q_flow = TC_348_1230.G * TC_348_1230.dT; TC_348_1230.dT = TC_348_1230.port_a.T - TC_348_1230.port_b.T; TC_348_1230.port_a.Q_flow = TC_348_1230.Q_flow; TC_348_1230.port_b.Q_flow = -TC_348_1230.Q_flow; TC_349_351.Q_flow = TC_349_351.G * TC_349_351.dT; TC_349_351.dT = TC_349_351.port_a.T - TC_349_351.port_b.T; TC_349_351.port_a.Q_flow = TC_349_351.Q_flow; TC_349_351.port_b.Q_flow = -TC_349_351.Q_flow; TC_349_403.Q_flow = TC_349_403.G * TC_349_403.dT; TC_349_403.dT = TC_349_403.port_a.T - TC_349_403.port_b.T; TC_349_403.port_a.Q_flow = TC_349_403.Q_flow; TC_349_403.port_b.Q_flow = -TC_349_403.Q_flow; TC_349_1231.Q_flow = TC_349_1231.G * TC_349_1231.dT; TC_349_1231.dT = TC_349_1231.port_a.T - TC_349_1231.port_b.T; TC_349_1231.port_a.Q_flow = TC_349_1231.Q_flow; TC_349_1231.port_b.Q_flow = -TC_349_1231.Q_flow; TC_350_352.Q_flow = TC_350_352.G * TC_350_352.dT; TC_350_352.dT = TC_350_352.port_a.T - TC_350_352.port_b.T; TC_350_352.port_a.Q_flow = TC_350_352.Q_flow; TC_350_352.port_b.Q_flow = -TC_350_352.Q_flow; TC_350_404.Q_flow = TC_350_404.G * TC_350_404.dT; TC_350_404.dT = TC_350_404.port_a.T - TC_350_404.port_b.T; TC_350_404.port_a.Q_flow = TC_350_404.Q_flow; TC_350_404.port_b.Q_flow = -TC_350_404.Q_flow; TC_350_1238.Q_flow = TC_350_1238.G * TC_350_1238.dT; TC_350_1238.dT = TC_350_1238.port_a.T - TC_350_1238.port_b.T; TC_350_1238.port_a.Q_flow = TC_350_1238.Q_flow; TC_350_1238.port_b.Q_flow = -TC_350_1238.Q_flow; TC_351_353.Q_flow = TC_351_353.G * TC_351_353.dT; TC_351_353.dT = TC_351_353.port_a.T - TC_351_353.port_b.T; TC_351_353.port_a.Q_flow = TC_351_353.Q_flow; TC_351_353.port_b.Q_flow = -TC_351_353.Q_flow; TC_351_405.Q_flow = TC_351_405.G * TC_351_405.dT; TC_351_405.dT = TC_351_405.port_a.T - TC_351_405.port_b.T; TC_351_405.port_a.Q_flow = TC_351_405.Q_flow; TC_351_405.port_b.Q_flow = -TC_351_405.Q_flow; TC_351_1239.Q_flow = TC_351_1239.G * TC_351_1239.dT; TC_351_1239.dT = TC_351_1239.port_a.T - TC_351_1239.port_b.T; TC_351_1239.port_a.Q_flow = TC_351_1239.Q_flow; TC_351_1239.port_b.Q_flow = -TC_351_1239.Q_flow; TC_352_354.Q_flow = TC_352_354.G * TC_352_354.dT; TC_352_354.dT = TC_352_354.port_a.T - TC_352_354.port_b.T; TC_352_354.port_a.Q_flow = TC_352_354.Q_flow; TC_352_354.port_b.Q_flow = -TC_352_354.Q_flow; TC_352_406.Q_flow = TC_352_406.G * TC_352_406.dT; TC_352_406.dT = TC_352_406.port_a.T - TC_352_406.port_b.T; TC_352_406.port_a.Q_flow = TC_352_406.Q_flow; TC_352_406.port_b.Q_flow = -TC_352_406.Q_flow; TC_352_1246.Q_flow = TC_352_1246.G * TC_352_1246.dT; TC_352_1246.dT = TC_352_1246.port_a.T - TC_352_1246.port_b.T; TC_352_1246.port_a.Q_flow = TC_352_1246.Q_flow; TC_352_1246.port_b.Q_flow = -TC_352_1246.Q_flow; TC_353_355.Q_flow = TC_353_355.G * TC_353_355.dT; TC_353_355.dT = TC_353_355.port_a.T - TC_353_355.port_b.T; TC_353_355.port_a.Q_flow = TC_353_355.Q_flow; TC_353_355.port_b.Q_flow = -TC_353_355.Q_flow; TC_353_407.Q_flow = TC_353_407.G * TC_353_407.dT; TC_353_407.dT = TC_353_407.port_a.T - TC_353_407.port_b.T; TC_353_407.port_a.Q_flow = TC_353_407.Q_flow; TC_353_407.port_b.Q_flow = -TC_353_407.Q_flow; TC_353_1247.Q_flow = TC_353_1247.G * TC_353_1247.dT; TC_353_1247.dT = TC_353_1247.port_a.T - TC_353_1247.port_b.T; TC_353_1247.port_a.Q_flow = TC_353_1247.Q_flow; TC_353_1247.port_b.Q_flow = -TC_353_1247.Q_flow; TC_354_356.Q_flow = TC_354_356.G * TC_354_356.dT; TC_354_356.dT = TC_354_356.port_a.T - TC_354_356.port_b.T; TC_354_356.port_a.Q_flow = TC_354_356.Q_flow; TC_354_356.port_b.Q_flow = -TC_354_356.Q_flow; TC_354_408.Q_flow = TC_354_408.G * TC_354_408.dT; TC_354_408.dT = TC_354_408.port_a.T - TC_354_408.port_b.T; TC_354_408.port_a.Q_flow = TC_354_408.Q_flow; TC_354_408.port_b.Q_flow = -TC_354_408.Q_flow; TC_354_1257.Q_flow = TC_354_1257.G * TC_354_1257.dT; TC_354_1257.dT = TC_354_1257.port_a.T - TC_354_1257.port_b.T; TC_354_1257.port_a.Q_flow = TC_354_1257.Q_flow; TC_354_1257.port_b.Q_flow = -TC_354_1257.Q_flow; TC_355_357.Q_flow = TC_355_357.G * TC_355_357.dT; TC_355_357.dT = TC_355_357.port_a.T - TC_355_357.port_b.T; TC_355_357.port_a.Q_flow = TC_355_357.Q_flow; TC_355_357.port_b.Q_flow = -TC_355_357.Q_flow; TC_355_409.Q_flow = TC_355_409.G * TC_355_409.dT; TC_355_409.dT = TC_355_409.port_a.T - TC_355_409.port_b.T; TC_355_409.port_a.Q_flow = TC_355_409.Q_flow; TC_355_409.port_b.Q_flow = -TC_355_409.Q_flow; TC_355_1258.Q_flow = TC_355_1258.G * TC_355_1258.dT; TC_355_1258.dT = TC_355_1258.port_a.T - TC_355_1258.port_b.T; TC_355_1258.port_a.Q_flow = TC_355_1258.Q_flow; TC_355_1258.port_b.Q_flow = -TC_355_1258.Q_flow; TC_356_369.Q_flow = TC_356_369.G * TC_356_369.dT; TC_356_369.dT = TC_356_369.port_a.T - TC_356_369.port_b.T; TC_356_369.port_a.Q_flow = TC_356_369.Q_flow; TC_356_369.port_b.Q_flow = -TC_356_369.Q_flow; TC_356_410.Q_flow = TC_356_410.G * TC_356_410.dT; TC_356_410.dT = TC_356_410.port_a.T - TC_356_410.port_b.T; TC_356_410.port_a.Q_flow = TC_356_410.Q_flow; TC_356_410.port_b.Q_flow = -TC_356_410.Q_flow; TC_356_1268.Q_flow = TC_356_1268.G * TC_356_1268.dT; TC_356_1268.dT = TC_356_1268.port_a.T - TC_356_1268.port_b.T; TC_356_1268.port_a.Q_flow = TC_356_1268.Q_flow; TC_356_1268.port_b.Q_flow = -TC_356_1268.Q_flow; TC_357_358.Q_flow = TC_357_358.G * TC_357_358.dT; TC_357_358.dT = TC_357_358.port_a.T - TC_357_358.port_b.T; TC_357_358.port_a.Q_flow = TC_357_358.Q_flow; TC_357_358.port_b.Q_flow = -TC_357_358.Q_flow; TC_357_411.Q_flow = TC_357_411.G * TC_357_411.dT; TC_357_411.dT = TC_357_411.port_a.T - TC_357_411.port_b.T; TC_357_411.port_a.Q_flow = TC_357_411.Q_flow; TC_357_411.port_b.Q_flow = -TC_357_411.Q_flow; TC_358_359.Q_flow = TC_358_359.G * TC_358_359.dT; TC_358_359.dT = TC_358_359.port_a.T - TC_358_359.port_b.T; TC_358_359.port_a.Q_flow = TC_358_359.Q_flow; TC_358_359.port_b.Q_flow = -TC_358_359.Q_flow; TC_358_412.Q_flow = TC_358_412.G * TC_358_412.dT; TC_358_412.dT = TC_358_412.port_a.T - TC_358_412.port_b.T; TC_358_412.port_a.Q_flow = TC_358_412.Q_flow; TC_358_412.port_b.Q_flow = -TC_358_412.Q_flow; TC_358_1258.Q_flow = TC_358_1258.G * TC_358_1258.dT; TC_358_1258.dT = TC_358_1258.port_a.T - TC_358_1258.port_b.T; TC_358_1258.port_a.Q_flow = TC_358_1258.Q_flow; TC_358_1258.port_b.Q_flow = -TC_358_1258.Q_flow; TC_359_360.Q_flow = TC_359_360.G * TC_359_360.dT; TC_359_360.dT = TC_359_360.port_a.T - TC_359_360.port_b.T; TC_359_360.port_a.Q_flow = TC_359_360.Q_flow; TC_359_360.port_b.Q_flow = -TC_359_360.Q_flow; TC_359_413.Q_flow = TC_359_413.G * TC_359_413.dT; TC_359_413.dT = TC_359_413.port_a.T - TC_359_413.port_b.T; TC_359_413.port_a.Q_flow = TC_359_413.Q_flow; TC_359_413.port_b.Q_flow = -TC_359_413.Q_flow; TC_359_1259.Q_flow = TC_359_1259.G * TC_359_1259.dT; TC_359_1259.dT = TC_359_1259.port_a.T - TC_359_1259.port_b.T; TC_359_1259.port_a.Q_flow = TC_359_1259.Q_flow; TC_359_1259.port_b.Q_flow = -TC_359_1259.Q_flow; TC_360_361.Q_flow = TC_360_361.G * TC_360_361.dT; TC_360_361.dT = TC_360_361.port_a.T - TC_360_361.port_b.T; TC_360_361.port_a.Q_flow = TC_360_361.Q_flow; TC_360_361.port_b.Q_flow = -TC_360_361.Q_flow; TC_360_414.Q_flow = TC_360_414.G * TC_360_414.dT; TC_360_414.dT = TC_360_414.port_a.T - TC_360_414.port_b.T; TC_360_414.port_a.Q_flow = TC_360_414.Q_flow; TC_360_414.port_b.Q_flow = -TC_360_414.Q_flow; TC_360_1260.Q_flow = TC_360_1260.G * TC_360_1260.dT; TC_360_1260.dT = TC_360_1260.port_a.T - TC_360_1260.port_b.T; TC_360_1260.port_a.Q_flow = TC_360_1260.Q_flow; TC_360_1260.port_b.Q_flow = -TC_360_1260.Q_flow; TC_361_362.Q_flow = TC_361_362.G * TC_361_362.dT; TC_361_362.dT = TC_361_362.port_a.T - TC_361_362.port_b.T; TC_361_362.port_a.Q_flow = TC_361_362.Q_flow; TC_361_362.port_b.Q_flow = -TC_361_362.Q_flow; TC_361_415.Q_flow = TC_361_415.G * TC_361_415.dT; TC_361_415.dT = TC_361_415.port_a.T - TC_361_415.port_b.T; TC_361_415.port_a.Q_flow = TC_361_415.Q_flow; TC_361_415.port_b.Q_flow = -TC_361_415.Q_flow; TC_361_1261.Q_flow = TC_361_1261.G * TC_361_1261.dT; TC_361_1261.dT = TC_361_1261.port_a.T - TC_361_1261.port_b.T; TC_361_1261.port_a.Q_flow = TC_361_1261.Q_flow; TC_361_1261.port_b.Q_flow = -TC_361_1261.Q_flow; TC_362_363.Q_flow = TC_362_363.G * TC_362_363.dT; TC_362_363.dT = TC_362_363.port_a.T - TC_362_363.port_b.T; TC_362_363.port_a.Q_flow = TC_362_363.Q_flow; TC_362_363.port_b.Q_flow = -TC_362_363.Q_flow; TC_362_416.Q_flow = TC_362_416.G * TC_362_416.dT; TC_362_416.dT = TC_362_416.port_a.T - TC_362_416.port_b.T; TC_362_416.port_a.Q_flow = TC_362_416.Q_flow; TC_362_416.port_b.Q_flow = -TC_362_416.Q_flow; TC_362_1262.Q_flow = TC_362_1262.G * TC_362_1262.dT; TC_362_1262.dT = TC_362_1262.port_a.T - TC_362_1262.port_b.T; TC_362_1262.port_a.Q_flow = TC_362_1262.Q_flow; TC_362_1262.port_b.Q_flow = -TC_362_1262.Q_flow; TC_363_364.Q_flow = TC_363_364.G * TC_363_364.dT; TC_363_364.dT = TC_363_364.port_a.T - TC_363_364.port_b.T; TC_363_364.port_a.Q_flow = TC_363_364.Q_flow; TC_363_364.port_b.Q_flow = -TC_363_364.Q_flow; TC_363_417.Q_flow = TC_363_417.G * TC_363_417.dT; TC_363_417.dT = TC_363_417.port_a.T - TC_363_417.port_b.T; TC_363_417.port_a.Q_flow = TC_363_417.Q_flow; TC_363_417.port_b.Q_flow = -TC_363_417.Q_flow; TC_363_1263.Q_flow = TC_363_1263.G * TC_363_1263.dT; TC_363_1263.dT = TC_363_1263.port_a.T - TC_363_1263.port_b.T; TC_363_1263.port_a.Q_flow = TC_363_1263.Q_flow; TC_363_1263.port_b.Q_flow = -TC_363_1263.Q_flow; TC_364_365.Q_flow = TC_364_365.G * TC_364_365.dT; TC_364_365.dT = TC_364_365.port_a.T - TC_364_365.port_b.T; TC_364_365.port_a.Q_flow = TC_364_365.Q_flow; TC_364_365.port_b.Q_flow = -TC_364_365.Q_flow; TC_364_418.Q_flow = TC_364_418.G * TC_364_418.dT; TC_364_418.dT = TC_364_418.port_a.T - TC_364_418.port_b.T; TC_364_418.port_a.Q_flow = TC_364_418.Q_flow; TC_364_418.port_b.Q_flow = -TC_364_418.Q_flow; TC_364_1264.Q_flow = TC_364_1264.G * TC_364_1264.dT; TC_364_1264.dT = TC_364_1264.port_a.T - TC_364_1264.port_b.T; TC_364_1264.port_a.Q_flow = TC_364_1264.Q_flow; TC_364_1264.port_b.Q_flow = -TC_364_1264.Q_flow; TC_365_366.Q_flow = TC_365_366.G * TC_365_366.dT; TC_365_366.dT = TC_365_366.port_a.T - TC_365_366.port_b.T; TC_365_366.port_a.Q_flow = TC_365_366.Q_flow; TC_365_366.port_b.Q_flow = -TC_365_366.Q_flow; TC_365_419.Q_flow = TC_365_419.G * TC_365_419.dT; TC_365_419.dT = TC_365_419.port_a.T - TC_365_419.port_b.T; TC_365_419.port_a.Q_flow = TC_365_419.Q_flow; TC_365_419.port_b.Q_flow = -TC_365_419.Q_flow; TC_365_1265.Q_flow = TC_365_1265.G * TC_365_1265.dT; TC_365_1265.dT = TC_365_1265.port_a.T - TC_365_1265.port_b.T; TC_365_1265.port_a.Q_flow = TC_365_1265.Q_flow; TC_365_1265.port_b.Q_flow = -TC_365_1265.Q_flow; TC_366_367.Q_flow = TC_366_367.G * TC_366_367.dT; TC_366_367.dT = TC_366_367.port_a.T - TC_366_367.port_b.T; TC_366_367.port_a.Q_flow = TC_366_367.Q_flow; TC_366_367.port_b.Q_flow = -TC_366_367.Q_flow; TC_366_420.Q_flow = TC_366_420.G * TC_366_420.dT; TC_366_420.dT = TC_366_420.port_a.T - TC_366_420.port_b.T; TC_366_420.port_a.Q_flow = TC_366_420.Q_flow; TC_366_420.port_b.Q_flow = -TC_366_420.Q_flow; TC_366_1266.Q_flow = TC_366_1266.G * TC_366_1266.dT; TC_366_1266.dT = TC_366_1266.port_a.T - TC_366_1266.port_b.T; TC_366_1266.port_a.Q_flow = TC_366_1266.Q_flow; TC_366_1266.port_b.Q_flow = -TC_366_1266.Q_flow; TC_367_368.Q_flow = TC_367_368.G * TC_367_368.dT; TC_367_368.dT = TC_367_368.port_a.T - TC_367_368.port_b.T; TC_367_368.port_a.Q_flow = TC_367_368.Q_flow; TC_367_368.port_b.Q_flow = -TC_367_368.Q_flow; TC_367_421.Q_flow = TC_367_421.G * TC_367_421.dT; TC_367_421.dT = TC_367_421.port_a.T - TC_367_421.port_b.T; TC_367_421.port_a.Q_flow = TC_367_421.Q_flow; TC_367_421.port_b.Q_flow = -TC_367_421.Q_flow; TC_367_1267.Q_flow = TC_367_1267.G * TC_367_1267.dT; TC_367_1267.dT = TC_367_1267.port_a.T - TC_367_1267.port_b.T; TC_367_1267.port_a.Q_flow = TC_367_1267.Q_flow; TC_367_1267.port_b.Q_flow = -TC_367_1267.Q_flow; TC_368_369.Q_flow = TC_368_369.G * TC_368_369.dT; TC_368_369.dT = TC_368_369.port_a.T - TC_368_369.port_b.T; TC_368_369.port_a.Q_flow = TC_368_369.Q_flow; TC_368_369.port_b.Q_flow = -TC_368_369.Q_flow; TC_368_422.Q_flow = TC_368_422.G * TC_368_422.dT; TC_368_422.dT = TC_368_422.port_a.T - TC_368_422.port_b.T; TC_368_422.port_a.Q_flow = TC_368_422.Q_flow; TC_368_422.port_b.Q_flow = -TC_368_422.Q_flow; TC_368_1268.Q_flow = TC_368_1268.G * TC_368_1268.dT; TC_368_1268.dT = TC_368_1268.port_a.T - TC_368_1268.port_b.T; TC_368_1268.port_a.Q_flow = TC_368_1268.Q_flow; TC_368_1268.port_b.Q_flow = -TC_368_1268.Q_flow; TC_369_423.Q_flow = TC_369_423.G * TC_369_423.dT; TC_369_423.dT = TC_369_423.port_a.T - TC_369_423.port_b.T; TC_369_423.port_a.Q_flow = TC_369_423.Q_flow; TC_369_423.port_b.Q_flow = -TC_369_423.Q_flow; TC_370_371.Q_flow = TC_370_371.G * TC_370_371.dT; TC_370_371.dT = TC_370_371.port_a.T - TC_370_371.port_b.T; TC_370_371.port_a.Q_flow = TC_370_371.Q_flow; TC_370_371.port_b.Q_flow = -TC_370_371.Q_flow; TC_370_383.Q_flow = TC_370_383.G * TC_370_383.dT; TC_370_383.dT = TC_370_383.port_a.T - TC_370_383.port_b.T; TC_370_383.port_a.Q_flow = TC_370_383.Q_flow; TC_370_383.port_b.Q_flow = -TC_370_383.Q_flow; TC_370_424.Q_flow = TC_370_424.G * TC_370_424.dT; TC_370_424.dT = TC_370_424.port_a.T - TC_370_424.port_b.T; TC_370_424.port_a.Q_flow = TC_370_424.Q_flow; TC_370_424.port_b.Q_flow = -TC_370_424.Q_flow; TC_371_372.Q_flow = TC_371_372.G * TC_371_372.dT; TC_371_372.dT = TC_371_372.port_a.T - TC_371_372.port_b.T; TC_371_372.port_a.Q_flow = TC_371_372.Q_flow; TC_371_372.port_b.Q_flow = -TC_371_372.Q_flow; TC_371_1269.Q_flow = TC_371_1269.G * TC_371_1269.dT; TC_371_1269.dT = TC_371_1269.port_a.T - TC_371_1269.port_b.T; TC_371_1269.port_a.Q_flow = TC_371_1269.Q_flow; TC_371_1269.port_b.Q_flow = -TC_371_1269.Q_flow; TC_372_373.Q_flow = TC_372_373.G * TC_372_373.dT; TC_372_373.dT = TC_372_373.port_a.T - TC_372_373.port_b.T; TC_372_373.port_a.Q_flow = TC_372_373.Q_flow; TC_372_373.port_b.Q_flow = -TC_372_373.Q_flow; TC_372_1270.Q_flow = TC_372_1270.G * TC_372_1270.dT; TC_372_1270.dT = TC_372_1270.port_a.T - TC_372_1270.port_b.T; TC_372_1270.port_a.Q_flow = TC_372_1270.Q_flow; TC_372_1270.port_b.Q_flow = -TC_372_1270.Q_flow; TC_373_374.Q_flow = TC_373_374.G * TC_373_374.dT; TC_373_374.dT = TC_373_374.port_a.T - TC_373_374.port_b.T; TC_373_374.port_a.Q_flow = TC_373_374.Q_flow; TC_373_374.port_b.Q_flow = -TC_373_374.Q_flow; TC_373_1271.Q_flow = TC_373_1271.G * TC_373_1271.dT; TC_373_1271.dT = TC_373_1271.port_a.T - TC_373_1271.port_b.T; TC_373_1271.port_a.Q_flow = TC_373_1271.Q_flow; TC_373_1271.port_b.Q_flow = -TC_373_1271.Q_flow; TC_374_375.Q_flow = TC_374_375.G * TC_374_375.dT; TC_374_375.dT = TC_374_375.port_a.T - TC_374_375.port_b.T; TC_374_375.port_a.Q_flow = TC_374_375.Q_flow; TC_374_375.port_b.Q_flow = -TC_374_375.Q_flow; TC_374_1272.Q_flow = TC_374_1272.G * TC_374_1272.dT; TC_374_1272.dT = TC_374_1272.port_a.T - TC_374_1272.port_b.T; TC_374_1272.port_a.Q_flow = TC_374_1272.Q_flow; TC_374_1272.port_b.Q_flow = -TC_374_1272.Q_flow; TC_375_376.Q_flow = TC_375_376.G * TC_375_376.dT; TC_375_376.dT = TC_375_376.port_a.T - TC_375_376.port_b.T; TC_375_376.port_a.Q_flow = TC_375_376.Q_flow; TC_375_376.port_b.Q_flow = -TC_375_376.Q_flow; TC_375_1273.Q_flow = TC_375_1273.G * TC_375_1273.dT; TC_375_1273.dT = TC_375_1273.port_a.T - TC_375_1273.port_b.T; TC_375_1273.port_a.Q_flow = TC_375_1273.Q_flow; TC_375_1273.port_b.Q_flow = -TC_375_1273.Q_flow; TC_376_377.Q_flow = TC_376_377.G * TC_376_377.dT; TC_376_377.dT = TC_376_377.port_a.T - TC_376_377.port_b.T; TC_376_377.port_a.Q_flow = TC_376_377.Q_flow; TC_376_377.port_b.Q_flow = -TC_376_377.Q_flow; TC_376_1274.Q_flow = TC_376_1274.G * TC_376_1274.dT; TC_376_1274.dT = TC_376_1274.port_a.T - TC_376_1274.port_b.T; TC_376_1274.port_a.Q_flow = TC_376_1274.Q_flow; TC_376_1274.port_b.Q_flow = -TC_376_1274.Q_flow; TC_377_378.Q_flow = TC_377_378.G * TC_377_378.dT; TC_377_378.dT = TC_377_378.port_a.T - TC_377_378.port_b.T; TC_377_378.port_a.Q_flow = TC_377_378.Q_flow; TC_377_378.port_b.Q_flow = -TC_377_378.Q_flow; TC_377_1275.Q_flow = TC_377_1275.G * TC_377_1275.dT; TC_377_1275.dT = TC_377_1275.port_a.T - TC_377_1275.port_b.T; TC_377_1275.port_a.Q_flow = TC_377_1275.Q_flow; TC_377_1275.port_b.Q_flow = -TC_377_1275.Q_flow; TC_378_379.Q_flow = TC_378_379.G * TC_378_379.dT; TC_378_379.dT = TC_378_379.port_a.T - TC_378_379.port_b.T; TC_378_379.port_a.Q_flow = TC_378_379.Q_flow; TC_378_379.port_b.Q_flow = -TC_378_379.Q_flow; TC_378_1276.Q_flow = TC_378_1276.G * TC_378_1276.dT; TC_378_1276.dT = TC_378_1276.port_a.T - TC_378_1276.port_b.T; TC_378_1276.port_a.Q_flow = TC_378_1276.Q_flow; TC_378_1276.port_b.Q_flow = -TC_378_1276.Q_flow; TC_379_380.Q_flow = TC_379_380.G * TC_379_380.dT; TC_379_380.dT = TC_379_380.port_a.T - TC_379_380.port_b.T; TC_379_380.port_a.Q_flow = TC_379_380.Q_flow; TC_379_380.port_b.Q_flow = -TC_379_380.Q_flow; TC_379_1277.Q_flow = TC_379_1277.G * TC_379_1277.dT; TC_379_1277.dT = TC_379_1277.port_a.T - TC_379_1277.port_b.T; TC_379_1277.port_a.Q_flow = TC_379_1277.Q_flow; TC_379_1277.port_b.Q_flow = -TC_379_1277.Q_flow; TC_380_381.Q_flow = TC_380_381.G * TC_380_381.dT; TC_380_381.dT = TC_380_381.port_a.T - TC_380_381.port_b.T; TC_380_381.port_a.Q_flow = TC_380_381.Q_flow; TC_380_381.port_b.Q_flow = -TC_380_381.Q_flow; TC_380_1278.Q_flow = TC_380_1278.G * TC_380_1278.dT; TC_380_1278.dT = TC_380_1278.port_a.T - TC_380_1278.port_b.T; TC_380_1278.port_a.Q_flow = TC_380_1278.Q_flow; TC_380_1278.port_b.Q_flow = -TC_380_1278.Q_flow; TC_381_382.Q_flow = TC_381_382.G * TC_381_382.dT; TC_381_382.dT = TC_381_382.port_a.T - TC_381_382.port_b.T; TC_381_382.port_a.Q_flow = TC_381_382.Q_flow; TC_381_382.port_b.Q_flow = -TC_381_382.Q_flow; TC_381_1279.Q_flow = TC_381_1279.G * TC_381_1279.dT; TC_381_1279.dT = TC_381_1279.port_a.T - TC_381_1279.port_b.T; TC_381_1279.port_a.Q_flow = TC_381_1279.Q_flow; TC_381_1279.port_b.Q_flow = -TC_381_1279.Q_flow; TC_382_384.Q_flow = TC_382_384.G * TC_382_384.dT; TC_382_384.dT = TC_382_384.port_a.T - TC_382_384.port_b.T; TC_382_384.port_a.Q_flow = TC_382_384.Q_flow; TC_382_384.port_b.Q_flow = -TC_382_384.Q_flow; TC_383_385.Q_flow = TC_383_385.G * TC_383_385.dT; TC_383_385.dT = TC_383_385.port_a.T - TC_383_385.port_b.T; TC_383_385.port_a.Q_flow = TC_383_385.Q_flow; TC_383_385.port_b.Q_flow = -TC_383_385.Q_flow; TC_383_1269.Q_flow = TC_383_1269.G * TC_383_1269.dT; TC_383_1269.dT = TC_383_1269.port_a.T - TC_383_1269.port_b.T; TC_383_1269.port_a.Q_flow = TC_383_1269.Q_flow; TC_383_1269.port_b.Q_flow = -TC_383_1269.Q_flow; TC_384_386.Q_flow = TC_384_386.G * TC_384_386.dT; TC_384_386.dT = TC_384_386.port_a.T - TC_384_386.port_b.T; TC_384_386.port_a.Q_flow = TC_384_386.Q_flow; TC_384_386.port_b.Q_flow = -TC_384_386.Q_flow; TC_384_1279.Q_flow = TC_384_1279.G * TC_384_1279.dT; TC_384_1279.dT = TC_384_1279.port_a.T - TC_384_1279.port_b.T; TC_384_1279.port_a.Q_flow = TC_384_1279.Q_flow; TC_384_1279.port_b.Q_flow = -TC_384_1279.Q_flow; TC_385_387.Q_flow = TC_385_387.G * TC_385_387.dT; TC_385_387.dT = TC_385_387.port_a.T - TC_385_387.port_b.T; TC_385_387.port_a.Q_flow = TC_385_387.Q_flow; TC_385_387.port_b.Q_flow = -TC_385_387.Q_flow; TC_385_1280.Q_flow = TC_385_1280.G * TC_385_1280.dT; TC_385_1280.dT = TC_385_1280.port_a.T - TC_385_1280.port_b.T; TC_385_1280.port_a.Q_flow = TC_385_1280.Q_flow; TC_385_1280.port_b.Q_flow = -TC_385_1280.Q_flow; TC_386_388.Q_flow = TC_386_388.G * TC_386_388.dT; TC_386_388.dT = TC_386_388.port_a.T - TC_386_388.port_b.T; TC_386_388.port_a.Q_flow = TC_386_388.Q_flow; TC_386_388.port_b.Q_flow = -TC_386_388.Q_flow; TC_386_1290.Q_flow = TC_386_1290.G * TC_386_1290.dT; TC_386_1290.dT = TC_386_1290.port_a.T - TC_386_1290.port_b.T; TC_386_1290.port_a.Q_flow = TC_386_1290.Q_flow; TC_386_1290.port_b.Q_flow = -TC_386_1290.Q_flow; TC_387_389.Q_flow = TC_387_389.G * TC_387_389.dT; TC_387_389.dT = TC_387_389.port_a.T - TC_387_389.port_b.T; TC_387_389.port_a.Q_flow = TC_387_389.Q_flow; TC_387_389.port_b.Q_flow = -TC_387_389.Q_flow; TC_387_1291.Q_flow = TC_387_1291.G * TC_387_1291.dT; TC_387_1291.dT = TC_387_1291.port_a.T - TC_387_1291.port_b.T; TC_387_1291.port_a.Q_flow = TC_387_1291.Q_flow; TC_387_1291.port_b.Q_flow = -TC_387_1291.Q_flow; TC_388_390.Q_flow = TC_388_390.G * TC_388_390.dT; TC_388_390.dT = TC_388_390.port_a.T - TC_388_390.port_b.T; TC_388_390.port_a.Q_flow = TC_388_390.Q_flow; TC_388_390.port_b.Q_flow = -TC_388_390.Q_flow; TC_388_1301.Q_flow = TC_388_1301.G * TC_388_1301.dT; TC_388_1301.dT = TC_388_1301.port_a.T - TC_388_1301.port_b.T; TC_388_1301.port_a.Q_flow = TC_388_1301.Q_flow; TC_388_1301.port_b.Q_flow = -TC_388_1301.Q_flow; TC_389_391.Q_flow = TC_389_391.G * TC_389_391.dT; TC_389_391.dT = TC_389_391.port_a.T - TC_389_391.port_b.T; TC_389_391.port_a.Q_flow = TC_389_391.Q_flow; TC_389_391.port_b.Q_flow = -TC_389_391.Q_flow; TC_389_1302.Q_flow = TC_389_1302.G * TC_389_1302.dT; TC_389_1302.dT = TC_389_1302.port_a.T - TC_389_1302.port_b.T; TC_389_1302.port_a.Q_flow = TC_389_1302.Q_flow; TC_389_1302.port_b.Q_flow = -TC_389_1302.Q_flow; TC_390_392.Q_flow = TC_390_392.G * TC_390_392.dT; TC_390_392.dT = TC_390_392.port_a.T - TC_390_392.port_b.T; TC_390_392.port_a.Q_flow = TC_390_392.Q_flow; TC_390_392.port_b.Q_flow = -TC_390_392.Q_flow; TC_390_1312.Q_flow = TC_390_1312.G * TC_390_1312.dT; TC_390_1312.dT = TC_390_1312.port_a.T - TC_390_1312.port_b.T; TC_390_1312.port_a.Q_flow = TC_390_1312.Q_flow; TC_390_1312.port_b.Q_flow = -TC_390_1312.Q_flow; TC_391_393.Q_flow = TC_391_393.G * TC_391_393.dT; TC_391_393.dT = TC_391_393.port_a.T - TC_391_393.port_b.T; TC_391_393.port_a.Q_flow = TC_391_393.Q_flow; TC_391_393.port_b.Q_flow = -TC_391_393.Q_flow; TC_391_1313.Q_flow = TC_391_1313.G * TC_391_1313.dT; TC_391_1313.dT = TC_391_1313.port_a.T - TC_391_1313.port_b.T; TC_391_1313.port_a.Q_flow = TC_391_1313.Q_flow; TC_391_1313.port_b.Q_flow = -TC_391_1313.Q_flow; TC_392_394.Q_flow = TC_392_394.G * TC_392_394.dT; TC_392_394.dT = TC_392_394.port_a.T - TC_392_394.port_b.T; TC_392_394.port_a.Q_flow = TC_392_394.Q_flow; TC_392_394.port_b.Q_flow = -TC_392_394.Q_flow; TC_392_1323.Q_flow = TC_392_1323.G * TC_392_1323.dT; TC_392_1323.dT = TC_392_1323.port_a.T - TC_392_1323.port_b.T; TC_392_1323.port_a.Q_flow = TC_392_1323.Q_flow; TC_392_1323.port_b.Q_flow = -TC_392_1323.Q_flow; TC_393_395.Q_flow = TC_393_395.G * TC_393_395.dT; TC_393_395.dT = TC_393_395.port_a.T - TC_393_395.port_b.T; TC_393_395.port_a.Q_flow = TC_393_395.Q_flow; TC_393_395.port_b.Q_flow = -TC_393_395.Q_flow; TC_393_1324.Q_flow = TC_393_1324.G * TC_393_1324.dT; TC_393_1324.dT = TC_393_1324.port_a.T - TC_393_1324.port_b.T; TC_393_1324.port_a.Q_flow = TC_393_1324.Q_flow; TC_393_1324.port_b.Q_flow = -TC_393_1324.Q_flow; TC_394_396.Q_flow = TC_394_396.G * TC_394_396.dT; TC_394_396.dT = TC_394_396.port_a.T - TC_394_396.port_b.T; TC_394_396.port_a.Q_flow = TC_394_396.Q_flow; TC_394_396.port_b.Q_flow = -TC_394_396.Q_flow; TC_394_1334.Q_flow = TC_394_1334.G * TC_394_1334.dT; TC_394_1334.dT = TC_394_1334.port_a.T - TC_394_1334.port_b.T; TC_394_1334.port_a.Q_flow = TC_394_1334.Q_flow; TC_394_1334.port_b.Q_flow = -TC_394_1334.Q_flow; TC_395_397.Q_flow = TC_395_397.G * TC_395_397.dT; TC_395_397.dT = TC_395_397.port_a.T - TC_395_397.port_b.T; TC_395_397.port_a.Q_flow = TC_395_397.Q_flow; TC_395_397.port_b.Q_flow = -TC_395_397.Q_flow; TC_395_1335.Q_flow = TC_395_1335.G * TC_395_1335.dT; TC_395_1335.dT = TC_395_1335.port_a.T - TC_395_1335.port_b.T; TC_395_1335.port_a.Q_flow = TC_395_1335.Q_flow; TC_395_1335.port_b.Q_flow = -TC_395_1335.Q_flow; TC_396_398.Q_flow = TC_396_398.G * TC_396_398.dT; TC_396_398.dT = TC_396_398.port_a.T - TC_396_398.port_b.T; TC_396_398.port_a.Q_flow = TC_396_398.Q_flow; TC_396_398.port_b.Q_flow = -TC_396_398.Q_flow; TC_396_1342.Q_flow = TC_396_1342.G * TC_396_1342.dT; TC_396_1342.dT = TC_396_1342.port_a.T - TC_396_1342.port_b.T; TC_396_1342.port_a.Q_flow = TC_396_1342.Q_flow; TC_396_1342.port_b.Q_flow = -TC_396_1342.Q_flow; TC_397_399.Q_flow = TC_397_399.G * TC_397_399.dT; TC_397_399.dT = TC_397_399.port_a.T - TC_397_399.port_b.T; TC_397_399.port_a.Q_flow = TC_397_399.Q_flow; TC_397_399.port_b.Q_flow = -TC_397_399.Q_flow; TC_397_1343.Q_flow = TC_397_1343.G * TC_397_1343.dT; TC_397_1343.dT = TC_397_1343.port_a.T - TC_397_1343.port_b.T; TC_397_1343.port_a.Q_flow = TC_397_1343.Q_flow; TC_397_1343.port_b.Q_flow = -TC_397_1343.Q_flow; TC_398_400.Q_flow = TC_398_400.G * TC_398_400.dT; TC_398_400.dT = TC_398_400.port_a.T - TC_398_400.port_b.T; TC_398_400.port_a.Q_flow = TC_398_400.Q_flow; TC_398_400.port_b.Q_flow = -TC_398_400.Q_flow; TC_398_1350.Q_flow = TC_398_1350.G * TC_398_1350.dT; TC_398_1350.dT = TC_398_1350.port_a.T - TC_398_1350.port_b.T; TC_398_1350.port_a.Q_flow = TC_398_1350.Q_flow; TC_398_1350.port_b.Q_flow = -TC_398_1350.Q_flow; TC_399_401.Q_flow = TC_399_401.G * TC_399_401.dT; TC_399_401.dT = TC_399_401.port_a.T - TC_399_401.port_b.T; TC_399_401.port_a.Q_flow = TC_399_401.Q_flow; TC_399_401.port_b.Q_flow = -TC_399_401.Q_flow; TC_399_1351.Q_flow = TC_399_1351.G * TC_399_1351.dT; TC_399_1351.dT = TC_399_1351.port_a.T - TC_399_1351.port_b.T; TC_399_1351.port_a.Q_flow = TC_399_1351.Q_flow; TC_399_1351.port_b.Q_flow = -TC_399_1351.Q_flow; TC_400_402.Q_flow = TC_400_402.G * TC_400_402.dT; TC_400_402.dT = TC_400_402.port_a.T - TC_400_402.port_b.T; TC_400_402.port_a.Q_flow = TC_400_402.Q_flow; TC_400_402.port_b.Q_flow = -TC_400_402.Q_flow; TC_400_1358.Q_flow = TC_400_1358.G * TC_400_1358.dT; TC_400_1358.dT = TC_400_1358.port_a.T - TC_400_1358.port_b.T; TC_400_1358.port_a.Q_flow = TC_400_1358.Q_flow; TC_400_1358.port_b.Q_flow = -TC_400_1358.Q_flow; TC_401_403.Q_flow = TC_401_403.G * TC_401_403.dT; TC_401_403.dT = TC_401_403.port_a.T - TC_401_403.port_b.T; TC_401_403.port_a.Q_flow = TC_401_403.Q_flow; TC_401_403.port_b.Q_flow = -TC_401_403.Q_flow; TC_401_1359.Q_flow = TC_401_1359.G * TC_401_1359.dT; TC_401_1359.dT = TC_401_1359.port_a.T - TC_401_1359.port_b.T; TC_401_1359.port_a.Q_flow = TC_401_1359.Q_flow; TC_401_1359.port_b.Q_flow = -TC_401_1359.Q_flow; TC_402_404.Q_flow = TC_402_404.G * TC_402_404.dT; TC_402_404.dT = TC_402_404.port_a.T - TC_402_404.port_b.T; TC_402_404.port_a.Q_flow = TC_402_404.Q_flow; TC_402_404.port_b.Q_flow = -TC_402_404.Q_flow; TC_402_1369.Q_flow = TC_402_1369.G * TC_402_1369.dT; TC_402_1369.dT = TC_402_1369.port_a.T - TC_402_1369.port_b.T; TC_402_1369.port_a.Q_flow = TC_402_1369.Q_flow; TC_402_1369.port_b.Q_flow = -TC_402_1369.Q_flow; TC_403_405.Q_flow = TC_403_405.G * TC_403_405.dT; TC_403_405.dT = TC_403_405.port_a.T - TC_403_405.port_b.T; TC_403_405.port_a.Q_flow = TC_403_405.Q_flow; TC_403_405.port_b.Q_flow = -TC_403_405.Q_flow; TC_403_1370.Q_flow = TC_403_1370.G * TC_403_1370.dT; TC_403_1370.dT = TC_403_1370.port_a.T - TC_403_1370.port_b.T; TC_403_1370.port_a.Q_flow = TC_403_1370.Q_flow; TC_403_1370.port_b.Q_flow = -TC_403_1370.Q_flow; TC_404_406.Q_flow = TC_404_406.G * TC_404_406.dT; TC_404_406.dT = TC_404_406.port_a.T - TC_404_406.port_b.T; TC_404_406.port_a.Q_flow = TC_404_406.Q_flow; TC_404_406.port_b.Q_flow = -TC_404_406.Q_flow; TC_404_1380.Q_flow = TC_404_1380.G * TC_404_1380.dT; TC_404_1380.dT = TC_404_1380.port_a.T - TC_404_1380.port_b.T; TC_404_1380.port_a.Q_flow = TC_404_1380.Q_flow; TC_404_1380.port_b.Q_flow = -TC_404_1380.Q_flow; TC_405_407.Q_flow = TC_405_407.G * TC_405_407.dT; TC_405_407.dT = TC_405_407.port_a.T - TC_405_407.port_b.T; TC_405_407.port_a.Q_flow = TC_405_407.Q_flow; TC_405_407.port_b.Q_flow = -TC_405_407.Q_flow; TC_405_1381.Q_flow = TC_405_1381.G * TC_405_1381.dT; TC_405_1381.dT = TC_405_1381.port_a.T - TC_405_1381.port_b.T; TC_405_1381.port_a.Q_flow = TC_405_1381.Q_flow; TC_405_1381.port_b.Q_flow = -TC_405_1381.Q_flow; TC_406_408.Q_flow = TC_406_408.G * TC_406_408.dT; TC_406_408.dT = TC_406_408.port_a.T - TC_406_408.port_b.T; TC_406_408.port_a.Q_flow = TC_406_408.Q_flow; TC_406_408.port_b.Q_flow = -TC_406_408.Q_flow; TC_406_1391.Q_flow = TC_406_1391.G * TC_406_1391.dT; TC_406_1391.dT = TC_406_1391.port_a.T - TC_406_1391.port_b.T; TC_406_1391.port_a.Q_flow = TC_406_1391.Q_flow; TC_406_1391.port_b.Q_flow = -TC_406_1391.Q_flow; TC_407_409.Q_flow = TC_407_409.G * TC_407_409.dT; TC_407_409.dT = TC_407_409.port_a.T - TC_407_409.port_b.T; TC_407_409.port_a.Q_flow = TC_407_409.Q_flow; TC_407_409.port_b.Q_flow = -TC_407_409.Q_flow; TC_407_1392.Q_flow = TC_407_1392.G * TC_407_1392.dT; TC_407_1392.dT = TC_407_1392.port_a.T - TC_407_1392.port_b.T; TC_407_1392.port_a.Q_flow = TC_407_1392.Q_flow; TC_407_1392.port_b.Q_flow = -TC_407_1392.Q_flow; TC_408_410.Q_flow = TC_408_410.G * TC_408_410.dT; TC_408_410.dT = TC_408_410.port_a.T - TC_408_410.port_b.T; TC_408_410.port_a.Q_flow = TC_408_410.Q_flow; TC_408_410.port_b.Q_flow = -TC_408_410.Q_flow; TC_408_1402.Q_flow = TC_408_1402.G * TC_408_1402.dT; TC_408_1402.dT = TC_408_1402.port_a.T - TC_408_1402.port_b.T; TC_408_1402.port_a.Q_flow = TC_408_1402.Q_flow; TC_408_1402.port_b.Q_flow = -TC_408_1402.Q_flow; TC_409_411.Q_flow = TC_409_411.G * TC_409_411.dT; TC_409_411.dT = TC_409_411.port_a.T - TC_409_411.port_b.T; TC_409_411.port_a.Q_flow = TC_409_411.Q_flow; TC_409_411.port_b.Q_flow = -TC_409_411.Q_flow; TC_409_1403.Q_flow = TC_409_1403.G * TC_409_1403.dT; TC_409_1403.dT = TC_409_1403.port_a.T - TC_409_1403.port_b.T; TC_409_1403.port_a.Q_flow = TC_409_1403.Q_flow; TC_409_1403.port_b.Q_flow = -TC_409_1403.Q_flow; TC_410_423.Q_flow = TC_410_423.G * TC_410_423.dT; TC_410_423.dT = TC_410_423.port_a.T - TC_410_423.port_b.T; TC_410_423.port_a.Q_flow = TC_410_423.Q_flow; TC_410_423.port_b.Q_flow = -TC_410_423.Q_flow; TC_410_1413.Q_flow = TC_410_1413.G * TC_410_1413.dT; TC_410_1413.dT = TC_410_1413.port_a.T - TC_410_1413.port_b.T; TC_410_1413.port_a.Q_flow = TC_410_1413.Q_flow; TC_410_1413.port_b.Q_flow = -TC_410_1413.Q_flow; TC_411_412.Q_flow = TC_411_412.G * TC_411_412.dT; TC_411_412.dT = TC_411_412.port_a.T - TC_411_412.port_b.T; TC_411_412.port_a.Q_flow = TC_411_412.Q_flow; TC_411_412.port_b.Q_flow = -TC_411_412.Q_flow; TC_412_413.Q_flow = TC_412_413.G * TC_412_413.dT; TC_412_413.dT = TC_412_413.port_a.T - TC_412_413.port_b.T; TC_412_413.port_a.Q_flow = TC_412_413.Q_flow; TC_412_413.port_b.Q_flow = -TC_412_413.Q_flow; TC_412_1403.Q_flow = TC_412_1403.G * TC_412_1403.dT; TC_412_1403.dT = TC_412_1403.port_a.T - TC_412_1403.port_b.T; TC_412_1403.port_a.Q_flow = TC_412_1403.Q_flow; TC_412_1403.port_b.Q_flow = -TC_412_1403.Q_flow; TC_413_414.Q_flow = TC_413_414.G * TC_413_414.dT; TC_413_414.dT = TC_413_414.port_a.T - TC_413_414.port_b.T; TC_413_414.port_a.Q_flow = TC_413_414.Q_flow; TC_413_414.port_b.Q_flow = -TC_413_414.Q_flow; TC_413_1404.Q_flow = TC_413_1404.G * TC_413_1404.dT; TC_413_1404.dT = TC_413_1404.port_a.T - TC_413_1404.port_b.T; TC_413_1404.port_a.Q_flow = TC_413_1404.Q_flow; TC_413_1404.port_b.Q_flow = -TC_413_1404.Q_flow; TC_414_415.Q_flow = TC_414_415.G * TC_414_415.dT; TC_414_415.dT = TC_414_415.port_a.T - TC_414_415.port_b.T; TC_414_415.port_a.Q_flow = TC_414_415.Q_flow; TC_414_415.port_b.Q_flow = -TC_414_415.Q_flow; TC_414_1405.Q_flow = TC_414_1405.G * TC_414_1405.dT; TC_414_1405.dT = TC_414_1405.port_a.T - TC_414_1405.port_b.T; TC_414_1405.port_a.Q_flow = TC_414_1405.Q_flow; TC_414_1405.port_b.Q_flow = -TC_414_1405.Q_flow; TC_415_416.Q_flow = TC_415_416.G * TC_415_416.dT; TC_415_416.dT = TC_415_416.port_a.T - TC_415_416.port_b.T; TC_415_416.port_a.Q_flow = TC_415_416.Q_flow; TC_415_416.port_b.Q_flow = -TC_415_416.Q_flow; TC_415_1406.Q_flow = TC_415_1406.G * TC_415_1406.dT; TC_415_1406.dT = TC_415_1406.port_a.T - TC_415_1406.port_b.T; TC_415_1406.port_a.Q_flow = TC_415_1406.Q_flow; TC_415_1406.port_b.Q_flow = -TC_415_1406.Q_flow; TC_416_417.Q_flow = TC_416_417.G * TC_416_417.dT; TC_416_417.dT = TC_416_417.port_a.T - TC_416_417.port_b.T; TC_416_417.port_a.Q_flow = TC_416_417.Q_flow; TC_416_417.port_b.Q_flow = -TC_416_417.Q_flow; TC_416_1407.Q_flow = TC_416_1407.G * TC_416_1407.dT; TC_416_1407.dT = TC_416_1407.port_a.T - TC_416_1407.port_b.T; TC_416_1407.port_a.Q_flow = TC_416_1407.Q_flow; TC_416_1407.port_b.Q_flow = -TC_416_1407.Q_flow; TC_417_418.Q_flow = TC_417_418.G * TC_417_418.dT; TC_417_418.dT = TC_417_418.port_a.T - TC_417_418.port_b.T; TC_417_418.port_a.Q_flow = TC_417_418.Q_flow; TC_417_418.port_b.Q_flow = -TC_417_418.Q_flow; TC_417_1408.Q_flow = TC_417_1408.G * TC_417_1408.dT; TC_417_1408.dT = TC_417_1408.port_a.T - TC_417_1408.port_b.T; TC_417_1408.port_a.Q_flow = TC_417_1408.Q_flow; TC_417_1408.port_b.Q_flow = -TC_417_1408.Q_flow; TC_418_419.Q_flow = TC_418_419.G * TC_418_419.dT; TC_418_419.dT = TC_418_419.port_a.T - TC_418_419.port_b.T; TC_418_419.port_a.Q_flow = TC_418_419.Q_flow; TC_418_419.port_b.Q_flow = -TC_418_419.Q_flow; TC_418_1409.Q_flow = TC_418_1409.G * TC_418_1409.dT; TC_418_1409.dT = TC_418_1409.port_a.T - TC_418_1409.port_b.T; TC_418_1409.port_a.Q_flow = TC_418_1409.Q_flow; TC_418_1409.port_b.Q_flow = -TC_418_1409.Q_flow; TC_419_420.Q_flow = TC_419_420.G * TC_419_420.dT; TC_419_420.dT = TC_419_420.port_a.T - TC_419_420.port_b.T; TC_419_420.port_a.Q_flow = TC_419_420.Q_flow; TC_419_420.port_b.Q_flow = -TC_419_420.Q_flow; TC_419_1410.Q_flow = TC_419_1410.G * TC_419_1410.dT; TC_419_1410.dT = TC_419_1410.port_a.T - TC_419_1410.port_b.T; TC_419_1410.port_a.Q_flow = TC_419_1410.Q_flow; TC_419_1410.port_b.Q_flow = -TC_419_1410.Q_flow; TC_420_421.Q_flow = TC_420_421.G * TC_420_421.dT; TC_420_421.dT = TC_420_421.port_a.T - TC_420_421.port_b.T; TC_420_421.port_a.Q_flow = TC_420_421.Q_flow; TC_420_421.port_b.Q_flow = -TC_420_421.Q_flow; TC_420_1411.Q_flow = TC_420_1411.G * TC_420_1411.dT; TC_420_1411.dT = TC_420_1411.port_a.T - TC_420_1411.port_b.T; TC_420_1411.port_a.Q_flow = TC_420_1411.Q_flow; TC_420_1411.port_b.Q_flow = -TC_420_1411.Q_flow; TC_421_422.Q_flow = TC_421_422.G * TC_421_422.dT; TC_421_422.dT = TC_421_422.port_a.T - TC_421_422.port_b.T; TC_421_422.port_a.Q_flow = TC_421_422.Q_flow; TC_421_422.port_b.Q_flow = -TC_421_422.Q_flow; TC_421_1412.Q_flow = TC_421_1412.G * TC_421_1412.dT; TC_421_1412.dT = TC_421_1412.port_a.T - TC_421_1412.port_b.T; TC_421_1412.port_a.Q_flow = TC_421_1412.Q_flow; TC_421_1412.port_b.Q_flow = -TC_421_1412.Q_flow; TC_422_423.Q_flow = TC_422_423.G * TC_422_423.dT; TC_422_423.dT = TC_422_423.port_a.T - TC_422_423.port_b.T; TC_422_423.port_a.Q_flow = TC_422_423.Q_flow; TC_422_423.port_b.Q_flow = -TC_422_423.Q_flow; TC_422_1413.Q_flow = TC_422_1413.G * TC_422_1413.dT; TC_422_1413.dT = TC_422_1413.port_a.T - TC_422_1413.port_b.T; TC_422_1413.port_a.Q_flow = TC_422_1413.Q_flow; TC_422_1413.port_b.Q_flow = -TC_422_1413.Q_flow; TC_425_426.Q_flow = TC_425_426.G * TC_425_426.dT; TC_425_426.dT = TC_425_426.port_a.T - TC_425_426.port_b.T; TC_425_426.port_a.Q_flow = TC_425_426.Q_flow; TC_425_426.port_b.Q_flow = -TC_425_426.Q_flow; TC_425_438.Q_flow = TC_425_438.G * TC_425_438.dT; TC_425_438.dT = TC_425_438.port_a.T - TC_425_438.port_b.T; TC_425_438.port_a.Q_flow = TC_425_438.Q_flow; TC_425_438.port_b.Q_flow = -TC_425_438.Q_flow; TC_425_479.Q_flow = TC_425_479.G * TC_425_479.dT; TC_425_479.dT = TC_425_479.port_a.T - TC_425_479.port_b.T; TC_425_479.port_a.Q_flow = TC_425_479.Q_flow; TC_425_479.port_b.Q_flow = -TC_425_479.Q_flow; TC_426_427.Q_flow = TC_426_427.G * TC_426_427.dT; TC_426_427.dT = TC_426_427.port_a.T - TC_426_427.port_b.T; TC_426_427.port_a.Q_flow = TC_426_427.Q_flow; TC_426_427.port_b.Q_flow = -TC_426_427.Q_flow; TC_426_480.Q_flow = TC_426_480.G * TC_426_480.dT; TC_426_480.dT = TC_426_480.port_a.T - TC_426_480.port_b.T; TC_426_480.port_a.Q_flow = TC_426_480.Q_flow; TC_426_480.port_b.Q_flow = -TC_426_480.Q_flow; TC_426_1066.Q_flow = TC_426_1066.G * TC_426_1066.dT; TC_426_1066.dT = TC_426_1066.port_a.T - TC_426_1066.port_b.T; TC_426_1066.port_a.Q_flow = TC_426_1066.Q_flow; TC_426_1066.port_b.Q_flow = -TC_426_1066.Q_flow; TC_427_428.Q_flow = TC_427_428.G * TC_427_428.dT; TC_427_428.dT = TC_427_428.port_a.T - TC_427_428.port_b.T; TC_427_428.port_a.Q_flow = TC_427_428.Q_flow; TC_427_428.port_b.Q_flow = -TC_427_428.Q_flow; TC_427_481.Q_flow = TC_427_481.G * TC_427_481.dT; TC_427_481.dT = TC_427_481.port_a.T - TC_427_481.port_b.T; TC_427_481.port_a.Q_flow = TC_427_481.Q_flow; TC_427_481.port_b.Q_flow = -TC_427_481.Q_flow; TC_427_1067.Q_flow = TC_427_1067.G * TC_427_1067.dT; TC_427_1067.dT = TC_427_1067.port_a.T - TC_427_1067.port_b.T; TC_427_1067.port_a.Q_flow = TC_427_1067.Q_flow; TC_427_1067.port_b.Q_flow = -TC_427_1067.Q_flow; TC_428_429.Q_flow = TC_428_429.G * TC_428_429.dT; TC_428_429.dT = TC_428_429.port_a.T - TC_428_429.port_b.T; TC_428_429.port_a.Q_flow = TC_428_429.Q_flow; TC_428_429.port_b.Q_flow = -TC_428_429.Q_flow; TC_428_482.Q_flow = TC_428_482.G * TC_428_482.dT; TC_428_482.dT = TC_428_482.port_a.T - TC_428_482.port_b.T; TC_428_482.port_a.Q_flow = TC_428_482.Q_flow; TC_428_482.port_b.Q_flow = -TC_428_482.Q_flow; TC_428_1068.Q_flow = TC_428_1068.G * TC_428_1068.dT; TC_428_1068.dT = TC_428_1068.port_a.T - TC_428_1068.port_b.T; TC_428_1068.port_a.Q_flow = TC_428_1068.Q_flow; TC_428_1068.port_b.Q_flow = -TC_428_1068.Q_flow; TC_429_430.Q_flow = TC_429_430.G * TC_429_430.dT; TC_429_430.dT = TC_429_430.port_a.T - TC_429_430.port_b.T; TC_429_430.port_a.Q_flow = TC_429_430.Q_flow; TC_429_430.port_b.Q_flow = -TC_429_430.Q_flow; TC_429_483.Q_flow = TC_429_483.G * TC_429_483.dT; TC_429_483.dT = TC_429_483.port_a.T - TC_429_483.port_b.T; TC_429_483.port_a.Q_flow = TC_429_483.Q_flow; TC_429_483.port_b.Q_flow = -TC_429_483.Q_flow; TC_429_1069.Q_flow = TC_429_1069.G * TC_429_1069.dT; TC_429_1069.dT = TC_429_1069.port_a.T - TC_429_1069.port_b.T; TC_429_1069.port_a.Q_flow = TC_429_1069.Q_flow; TC_429_1069.port_b.Q_flow = -TC_429_1069.Q_flow; TC_430_431.Q_flow = TC_430_431.G * TC_430_431.dT; TC_430_431.dT = TC_430_431.port_a.T - TC_430_431.port_b.T; TC_430_431.port_a.Q_flow = TC_430_431.Q_flow; TC_430_431.port_b.Q_flow = -TC_430_431.Q_flow; TC_430_484.Q_flow = TC_430_484.G * TC_430_484.dT; TC_430_484.dT = TC_430_484.port_a.T - TC_430_484.port_b.T; TC_430_484.port_a.Q_flow = TC_430_484.Q_flow; TC_430_484.port_b.Q_flow = -TC_430_484.Q_flow; TC_430_1070.Q_flow = TC_430_1070.G * TC_430_1070.dT; TC_430_1070.dT = TC_430_1070.port_a.T - TC_430_1070.port_b.T; TC_430_1070.port_a.Q_flow = TC_430_1070.Q_flow; TC_430_1070.port_b.Q_flow = -TC_430_1070.Q_flow; TC_431_432.Q_flow = TC_431_432.G * TC_431_432.dT; TC_431_432.dT = TC_431_432.port_a.T - TC_431_432.port_b.T; TC_431_432.port_a.Q_flow = TC_431_432.Q_flow; TC_431_432.port_b.Q_flow = -TC_431_432.Q_flow; TC_431_485.Q_flow = TC_431_485.G * TC_431_485.dT; TC_431_485.dT = TC_431_485.port_a.T - TC_431_485.port_b.T; TC_431_485.port_a.Q_flow = TC_431_485.Q_flow; TC_431_485.port_b.Q_flow = -TC_431_485.Q_flow; TC_431_1071.Q_flow = TC_431_1071.G * TC_431_1071.dT; TC_431_1071.dT = TC_431_1071.port_a.T - TC_431_1071.port_b.T; TC_431_1071.port_a.Q_flow = TC_431_1071.Q_flow; TC_431_1071.port_b.Q_flow = -TC_431_1071.Q_flow; TC_432_433.Q_flow = TC_432_433.G * TC_432_433.dT; TC_432_433.dT = TC_432_433.port_a.T - TC_432_433.port_b.T; TC_432_433.port_a.Q_flow = TC_432_433.Q_flow; TC_432_433.port_b.Q_flow = -TC_432_433.Q_flow; TC_432_486.Q_flow = TC_432_486.G * TC_432_486.dT; TC_432_486.dT = TC_432_486.port_a.T - TC_432_486.port_b.T; TC_432_486.port_a.Q_flow = TC_432_486.Q_flow; TC_432_486.port_b.Q_flow = -TC_432_486.Q_flow; TC_432_1072.Q_flow = TC_432_1072.G * TC_432_1072.dT; TC_432_1072.dT = TC_432_1072.port_a.T - TC_432_1072.port_b.T; TC_432_1072.port_a.Q_flow = TC_432_1072.Q_flow; TC_432_1072.port_b.Q_flow = -TC_432_1072.Q_flow; TC_433_434.Q_flow = TC_433_434.G * TC_433_434.dT; TC_433_434.dT = TC_433_434.port_a.T - TC_433_434.port_b.T; TC_433_434.port_a.Q_flow = TC_433_434.Q_flow; TC_433_434.port_b.Q_flow = -TC_433_434.Q_flow; TC_433_487.Q_flow = TC_433_487.G * TC_433_487.dT; TC_433_487.dT = TC_433_487.port_a.T - TC_433_487.port_b.T; TC_433_487.port_a.Q_flow = TC_433_487.Q_flow; TC_433_487.port_b.Q_flow = -TC_433_487.Q_flow; TC_433_1073.Q_flow = TC_433_1073.G * TC_433_1073.dT; TC_433_1073.dT = TC_433_1073.port_a.T - TC_433_1073.port_b.T; TC_433_1073.port_a.Q_flow = TC_433_1073.Q_flow; TC_433_1073.port_b.Q_flow = -TC_433_1073.Q_flow; TC_434_435.Q_flow = TC_434_435.G * TC_434_435.dT; TC_434_435.dT = TC_434_435.port_a.T - TC_434_435.port_b.T; TC_434_435.port_a.Q_flow = TC_434_435.Q_flow; TC_434_435.port_b.Q_flow = -TC_434_435.Q_flow; TC_434_488.Q_flow = TC_434_488.G * TC_434_488.dT; TC_434_488.dT = TC_434_488.port_a.T - TC_434_488.port_b.T; TC_434_488.port_a.Q_flow = TC_434_488.Q_flow; TC_434_488.port_b.Q_flow = -TC_434_488.Q_flow; TC_434_1074.Q_flow = TC_434_1074.G * TC_434_1074.dT; TC_434_1074.dT = TC_434_1074.port_a.T - TC_434_1074.port_b.T; TC_434_1074.port_a.Q_flow = TC_434_1074.Q_flow; TC_434_1074.port_b.Q_flow = -TC_434_1074.Q_flow; TC_435_436.Q_flow = TC_435_436.G * TC_435_436.dT; TC_435_436.dT = TC_435_436.port_a.T - TC_435_436.port_b.T; TC_435_436.port_a.Q_flow = TC_435_436.Q_flow; TC_435_436.port_b.Q_flow = -TC_435_436.Q_flow; TC_435_489.Q_flow = TC_435_489.G * TC_435_489.dT; TC_435_489.dT = TC_435_489.port_a.T - TC_435_489.port_b.T; TC_435_489.port_a.Q_flow = TC_435_489.Q_flow; TC_435_489.port_b.Q_flow = -TC_435_489.Q_flow; TC_435_1075.Q_flow = TC_435_1075.G * TC_435_1075.dT; TC_435_1075.dT = TC_435_1075.port_a.T - TC_435_1075.port_b.T; TC_435_1075.port_a.Q_flow = TC_435_1075.Q_flow; TC_435_1075.port_b.Q_flow = -TC_435_1075.Q_flow; TC_436_437.Q_flow = TC_436_437.G * TC_436_437.dT; TC_436_437.dT = TC_436_437.port_a.T - TC_436_437.port_b.T; TC_436_437.port_a.Q_flow = TC_436_437.Q_flow; TC_436_437.port_b.Q_flow = -TC_436_437.Q_flow; TC_436_490.Q_flow = TC_436_490.G * TC_436_490.dT; TC_436_490.dT = TC_436_490.port_a.T - TC_436_490.port_b.T; TC_436_490.port_a.Q_flow = TC_436_490.Q_flow; TC_436_490.port_b.Q_flow = -TC_436_490.Q_flow; TC_436_1076.Q_flow = TC_436_1076.G * TC_436_1076.dT; TC_436_1076.dT = TC_436_1076.port_a.T - TC_436_1076.port_b.T; TC_436_1076.port_a.Q_flow = TC_436_1076.Q_flow; TC_436_1076.port_b.Q_flow = -TC_436_1076.Q_flow; TC_437_439.Q_flow = TC_437_439.G * TC_437_439.dT; TC_437_439.dT = TC_437_439.port_a.T - TC_437_439.port_b.T; TC_437_439.port_a.Q_flow = TC_437_439.Q_flow; TC_437_439.port_b.Q_flow = -TC_437_439.Q_flow; TC_437_491.Q_flow = TC_437_491.G * TC_437_491.dT; TC_437_491.dT = TC_437_491.port_a.T - TC_437_491.port_b.T; TC_437_491.port_a.Q_flow = TC_437_491.Q_flow; TC_437_491.port_b.Q_flow = -TC_437_491.Q_flow; TC_438_440.Q_flow = TC_438_440.G * TC_438_440.dT; TC_438_440.dT = TC_438_440.port_a.T - TC_438_440.port_b.T; TC_438_440.port_a.Q_flow = TC_438_440.Q_flow; TC_438_440.port_b.Q_flow = -TC_438_440.Q_flow; TC_438_492.Q_flow = TC_438_492.G * TC_438_492.dT; TC_438_492.dT = TC_438_492.port_a.T - TC_438_492.port_b.T; TC_438_492.port_a.Q_flow = TC_438_492.Q_flow; TC_438_492.port_b.Q_flow = -TC_438_492.Q_flow; TC_438_1066.Q_flow = TC_438_1066.G * TC_438_1066.dT; TC_438_1066.dT = TC_438_1066.port_a.T - TC_438_1066.port_b.T; TC_438_1066.port_a.Q_flow = TC_438_1066.Q_flow; TC_438_1066.port_b.Q_flow = -TC_438_1066.Q_flow; TC_439_441.Q_flow = TC_439_441.G * TC_439_441.dT; TC_439_441.dT = TC_439_441.port_a.T - TC_439_441.port_b.T; TC_439_441.port_a.Q_flow = TC_439_441.Q_flow; TC_439_441.port_b.Q_flow = -TC_439_441.Q_flow; TC_439_493.Q_flow = TC_439_493.G * TC_439_493.dT; TC_439_493.dT = TC_439_493.port_a.T - TC_439_493.port_b.T; TC_439_493.port_a.Q_flow = TC_439_493.Q_flow; TC_439_493.port_b.Q_flow = -TC_439_493.Q_flow; TC_439_1076.Q_flow = TC_439_1076.G * TC_439_1076.dT; TC_439_1076.dT = TC_439_1076.port_a.T - TC_439_1076.port_b.T; TC_439_1076.port_a.Q_flow = TC_439_1076.Q_flow; TC_439_1076.port_b.Q_flow = -TC_439_1076.Q_flow; TC_440_442.Q_flow = TC_440_442.G * TC_440_442.dT; TC_440_442.dT = TC_440_442.port_a.T - TC_440_442.port_b.T; TC_440_442.port_a.Q_flow = TC_440_442.Q_flow; TC_440_442.port_b.Q_flow = -TC_440_442.Q_flow; TC_440_494.Q_flow = TC_440_494.G * TC_440_494.dT; TC_440_494.dT = TC_440_494.port_a.T - TC_440_494.port_b.T; TC_440_494.port_a.Q_flow = TC_440_494.Q_flow; TC_440_494.port_b.Q_flow = -TC_440_494.Q_flow; TC_440_1077.Q_flow = TC_440_1077.G * TC_440_1077.dT; TC_440_1077.dT = TC_440_1077.port_a.T - TC_440_1077.port_b.T; TC_440_1077.port_a.Q_flow = TC_440_1077.Q_flow; TC_440_1077.port_b.Q_flow = -TC_440_1077.Q_flow; TC_441_443.Q_flow = TC_441_443.G * TC_441_443.dT; TC_441_443.dT = TC_441_443.port_a.T - TC_441_443.port_b.T; TC_441_443.port_a.Q_flow = TC_441_443.Q_flow; TC_441_443.port_b.Q_flow = -TC_441_443.Q_flow; TC_441_495.Q_flow = TC_441_495.G * TC_441_495.dT; TC_441_495.dT = TC_441_495.port_a.T - TC_441_495.port_b.T; TC_441_495.port_a.Q_flow = TC_441_495.Q_flow; TC_441_495.port_b.Q_flow = -TC_441_495.Q_flow; TC_441_1087.Q_flow = TC_441_1087.G * TC_441_1087.dT; TC_441_1087.dT = TC_441_1087.port_a.T - TC_441_1087.port_b.T; TC_441_1087.port_a.Q_flow = TC_441_1087.Q_flow; TC_441_1087.port_b.Q_flow = -TC_441_1087.Q_flow; TC_442_444.Q_flow = TC_442_444.G * TC_442_444.dT; TC_442_444.dT = TC_442_444.port_a.T - TC_442_444.port_b.T; TC_442_444.port_a.Q_flow = TC_442_444.Q_flow; TC_442_444.port_b.Q_flow = -TC_442_444.Q_flow; TC_442_496.Q_flow = TC_442_496.G * TC_442_496.dT; TC_442_496.dT = TC_442_496.port_a.T - TC_442_496.port_b.T; TC_442_496.port_a.Q_flow = TC_442_496.Q_flow; TC_442_496.port_b.Q_flow = -TC_442_496.Q_flow; TC_442_1088.Q_flow = TC_442_1088.G * TC_442_1088.dT; TC_442_1088.dT = TC_442_1088.port_a.T - TC_442_1088.port_b.T; TC_442_1088.port_a.Q_flow = TC_442_1088.Q_flow; TC_442_1088.port_b.Q_flow = -TC_442_1088.Q_flow; TC_443_445.Q_flow = TC_443_445.G * TC_443_445.dT; TC_443_445.dT = TC_443_445.port_a.T - TC_443_445.port_b.T; TC_443_445.port_a.Q_flow = TC_443_445.Q_flow; TC_443_445.port_b.Q_flow = -TC_443_445.Q_flow; TC_443_497.Q_flow = TC_443_497.G * TC_443_497.dT; TC_443_497.dT = TC_443_497.port_a.T - TC_443_497.port_b.T; TC_443_497.port_a.Q_flow = TC_443_497.Q_flow; TC_443_497.port_b.Q_flow = -TC_443_497.Q_flow; TC_443_1094.Q_flow = TC_443_1094.G * TC_443_1094.dT; TC_443_1094.dT = TC_443_1094.port_a.T - TC_443_1094.port_b.T; TC_443_1094.port_a.Q_flow = TC_443_1094.Q_flow; TC_443_1094.port_b.Q_flow = -TC_443_1094.Q_flow; TC_444_446.Q_flow = TC_444_446.G * TC_444_446.dT; TC_444_446.dT = TC_444_446.port_a.T - TC_444_446.port_b.T; TC_444_446.port_a.Q_flow = TC_444_446.Q_flow; TC_444_446.port_b.Q_flow = -TC_444_446.Q_flow; TC_444_498.Q_flow = TC_444_498.G * TC_444_498.dT; TC_444_498.dT = TC_444_498.port_a.T - TC_444_498.port_b.T; TC_444_498.port_a.Q_flow = TC_444_498.Q_flow; TC_444_498.port_b.Q_flow = -TC_444_498.Q_flow; TC_444_1095.Q_flow = TC_444_1095.G * TC_444_1095.dT; TC_444_1095.dT = TC_444_1095.port_a.T - TC_444_1095.port_b.T; TC_444_1095.port_a.Q_flow = TC_444_1095.Q_flow; TC_444_1095.port_b.Q_flow = -TC_444_1095.Q_flow; TC_445_447.Q_flow = TC_445_447.G * TC_445_447.dT; TC_445_447.dT = TC_445_447.port_a.T - TC_445_447.port_b.T; TC_445_447.port_a.Q_flow = TC_445_447.Q_flow; TC_445_447.port_b.Q_flow = -TC_445_447.Q_flow; TC_445_499.Q_flow = TC_445_499.G * TC_445_499.dT; TC_445_499.dT = TC_445_499.port_a.T - TC_445_499.port_b.T; TC_445_499.port_a.Q_flow = TC_445_499.Q_flow; TC_445_499.port_b.Q_flow = -TC_445_499.Q_flow; TC_445_1030.Q_flow = TC_445_1030.G * TC_445_1030.dT; TC_445_1030.dT = TC_445_1030.port_a.T - TC_445_1030.port_b.T; TC_445_1030.port_a.Q_flow = TC_445_1030.Q_flow; TC_445_1030.port_b.Q_flow = -TC_445_1030.Q_flow; TC_446_448.Q_flow = TC_446_448.G * TC_446_448.dT; TC_446_448.dT = TC_446_448.port_a.T - TC_446_448.port_b.T; TC_446_448.port_a.Q_flow = TC_446_448.Q_flow; TC_446_448.port_b.Q_flow = -TC_446_448.Q_flow; TC_446_500.Q_flow = TC_446_500.G * TC_446_500.dT; TC_446_500.dT = TC_446_500.port_a.T - TC_446_500.port_b.T; TC_446_500.port_a.Q_flow = TC_446_500.Q_flow; TC_446_500.port_b.Q_flow = -TC_446_500.Q_flow; TC_446_1031.Q_flow = TC_446_1031.G * TC_446_1031.dT; TC_446_1031.dT = TC_446_1031.port_a.T - TC_446_1031.port_b.T; TC_446_1031.port_a.Q_flow = TC_446_1031.Q_flow; TC_446_1031.port_b.Q_flow = -TC_446_1031.Q_flow; TC_447_449.Q_flow = TC_447_449.G * TC_447_449.dT; TC_447_449.dT = TC_447_449.port_a.T - TC_447_449.port_b.T; TC_447_449.port_a.Q_flow = TC_447_449.Q_flow; TC_447_449.port_b.Q_flow = -TC_447_449.Q_flow; TC_447_501.Q_flow = TC_447_501.G * TC_447_501.dT; TC_447_501.dT = TC_447_501.port_a.T - TC_447_501.port_b.T; TC_447_501.port_a.Q_flow = TC_447_501.Q_flow; TC_447_501.port_b.Q_flow = -TC_447_501.Q_flow; TC_447_1037.Q_flow = TC_447_1037.G * TC_447_1037.dT; TC_447_1037.dT = TC_447_1037.port_a.T - TC_447_1037.port_b.T; TC_447_1037.port_a.Q_flow = TC_447_1037.Q_flow; TC_447_1037.port_b.Q_flow = -TC_447_1037.Q_flow; TC_448_450.Q_flow = TC_448_450.G * TC_448_450.dT; TC_448_450.dT = TC_448_450.port_a.T - TC_448_450.port_b.T; TC_448_450.port_a.Q_flow = TC_448_450.Q_flow; TC_448_450.port_b.Q_flow = -TC_448_450.Q_flow; TC_448_502.Q_flow = TC_448_502.G * TC_448_502.dT; TC_448_502.dT = TC_448_502.port_a.T - TC_448_502.port_b.T; TC_448_502.port_a.Q_flow = TC_448_502.Q_flow; TC_448_502.port_b.Q_flow = -TC_448_502.Q_flow; TC_448_1038.Q_flow = TC_448_1038.G * TC_448_1038.dT; TC_448_1038.dT = TC_448_1038.port_a.T - TC_448_1038.port_b.T; TC_448_1038.port_a.Q_flow = TC_448_1038.Q_flow; TC_448_1038.port_b.Q_flow = -TC_448_1038.Q_flow; TC_449_451.Q_flow = TC_449_451.G * TC_449_451.dT; TC_449_451.dT = TC_449_451.port_a.T - TC_449_451.port_b.T; TC_449_451.port_a.Q_flow = TC_449_451.Q_flow; TC_449_451.port_b.Q_flow = -TC_449_451.Q_flow; TC_449_503.Q_flow = TC_449_503.G * TC_449_503.dT; TC_449_503.dT = TC_449_503.port_a.T - TC_449_503.port_b.T; TC_449_503.port_a.Q_flow = TC_449_503.Q_flow; TC_449_503.port_b.Q_flow = -TC_449_503.Q_flow; TC_449_1048.Q_flow = TC_449_1048.G * TC_449_1048.dT; TC_449_1048.dT = TC_449_1048.port_a.T - TC_449_1048.port_b.T; TC_449_1048.port_a.Q_flow = TC_449_1048.Q_flow; TC_449_1048.port_b.Q_flow = -TC_449_1048.Q_flow; TC_450_452.Q_flow = TC_450_452.G * TC_450_452.dT; TC_450_452.dT = TC_450_452.port_a.T - TC_450_452.port_b.T; TC_450_452.port_a.Q_flow = TC_450_452.Q_flow; TC_450_452.port_b.Q_flow = -TC_450_452.Q_flow; TC_450_504.Q_flow = TC_450_504.G * TC_450_504.dT; TC_450_504.dT = TC_450_504.port_a.T - TC_450_504.port_b.T; TC_450_504.port_a.Q_flow = TC_450_504.Q_flow; TC_450_504.port_b.Q_flow = -TC_450_504.Q_flow; TC_450_1049.Q_flow = TC_450_1049.G * TC_450_1049.dT; TC_450_1049.dT = TC_450_1049.port_a.T - TC_450_1049.port_b.T; TC_450_1049.port_a.Q_flow = TC_450_1049.Q_flow; TC_450_1049.port_b.Q_flow = -TC_450_1049.Q_flow; TC_451_453.Q_flow = TC_451_453.G * TC_451_453.dT; TC_451_453.dT = TC_451_453.port_a.T - TC_451_453.port_b.T; TC_451_453.port_a.Q_flow = TC_451_453.Q_flow; TC_451_453.port_b.Q_flow = -TC_451_453.Q_flow; TC_451_505.Q_flow = TC_451_505.G * TC_451_505.dT; TC_451_505.dT = TC_451_505.port_a.T - TC_451_505.port_b.T; TC_451_505.port_a.Q_flow = TC_451_505.Q_flow; TC_451_505.port_b.Q_flow = -TC_451_505.Q_flow; TC_451_1059.Q_flow = TC_451_1059.G * TC_451_1059.dT; TC_451_1059.dT = TC_451_1059.port_a.T - TC_451_1059.port_b.T; TC_451_1059.port_a.Q_flow = TC_451_1059.Q_flow; TC_451_1059.port_b.Q_flow = -TC_451_1059.Q_flow; TC_452_454.Q_flow = TC_452_454.G * TC_452_454.dT; TC_452_454.dT = TC_452_454.port_a.T - TC_452_454.port_b.T; TC_452_454.port_a.Q_flow = TC_452_454.Q_flow; TC_452_454.port_b.Q_flow = -TC_452_454.Q_flow; TC_452_506.Q_flow = TC_452_506.G * TC_452_506.dT; TC_452_506.dT = TC_452_506.port_a.T - TC_452_506.port_b.T; TC_452_506.port_a.Q_flow = TC_452_506.Q_flow; TC_452_506.port_b.Q_flow = -TC_452_506.Q_flow; TC_452_1060.Q_flow = TC_452_1060.G * TC_452_1060.dT; TC_452_1060.dT = TC_452_1060.port_a.T - TC_452_1060.port_b.T; TC_452_1060.port_a.Q_flow = TC_452_1060.Q_flow; TC_452_1060.port_b.Q_flow = -TC_452_1060.Q_flow; TC_453_455.Q_flow = TC_453_455.G * TC_453_455.dT; TC_453_455.dT = TC_453_455.port_a.T - TC_453_455.port_b.T; TC_453_455.port_a.Q_flow = TC_453_455.Q_flow; TC_453_455.port_b.Q_flow = -TC_453_455.Q_flow; TC_453_507.Q_flow = TC_453_507.G * TC_453_507.dT; TC_453_507.dT = TC_453_507.port_a.T - TC_453_507.port_b.T; TC_453_507.port_a.Q_flow = TC_453_507.Q_flow; TC_453_507.port_b.Q_flow = -TC_453_507.Q_flow; TC_453_976.Q_flow = TC_453_976.G * TC_453_976.dT; TC_453_976.dT = TC_453_976.port_a.T - TC_453_976.port_b.T; TC_453_976.port_a.Q_flow = TC_453_976.Q_flow; TC_453_976.port_b.Q_flow = -TC_453_976.Q_flow; TC_454_456.Q_flow = TC_454_456.G * TC_454_456.dT; TC_454_456.dT = TC_454_456.port_a.T - TC_454_456.port_b.T; TC_454_456.port_a.Q_flow = TC_454_456.Q_flow; TC_454_456.port_b.Q_flow = -TC_454_456.Q_flow; TC_454_508.Q_flow = TC_454_508.G * TC_454_508.dT; TC_454_508.dT = TC_454_508.port_a.T - TC_454_508.port_b.T; TC_454_508.port_a.Q_flow = TC_454_508.Q_flow; TC_454_508.port_b.Q_flow = -TC_454_508.Q_flow; TC_454_977.Q_flow = TC_454_977.G * TC_454_977.dT; TC_454_977.dT = TC_454_977.port_a.T - TC_454_977.port_b.T; TC_454_977.port_a.Q_flow = TC_454_977.Q_flow; TC_454_977.port_b.Q_flow = -TC_454_977.Q_flow; TC_455_457.Q_flow = TC_455_457.G * TC_455_457.dT; TC_455_457.dT = TC_455_457.port_a.T - TC_455_457.port_b.T; TC_455_457.port_a.Q_flow = TC_455_457.Q_flow; TC_455_457.port_b.Q_flow = -TC_455_457.Q_flow; TC_455_509.Q_flow = TC_455_509.G * TC_455_509.dT; TC_455_509.dT = TC_455_509.port_a.T - TC_455_509.port_b.T; TC_455_509.port_a.Q_flow = TC_455_509.Q_flow; TC_455_509.port_b.Q_flow = -TC_455_509.Q_flow; TC_455_984.Q_flow = TC_455_984.G * TC_455_984.dT; TC_455_984.dT = TC_455_984.port_a.T - TC_455_984.port_b.T; TC_455_984.port_a.Q_flow = TC_455_984.Q_flow; TC_455_984.port_b.Q_flow = -TC_455_984.Q_flow; TC_456_458.Q_flow = TC_456_458.G * TC_456_458.dT; TC_456_458.dT = TC_456_458.port_a.T - TC_456_458.port_b.T; TC_456_458.port_a.Q_flow = TC_456_458.Q_flow; TC_456_458.port_b.Q_flow = -TC_456_458.Q_flow; TC_456_510.Q_flow = TC_456_510.G * TC_456_510.dT; TC_456_510.dT = TC_456_510.port_a.T - TC_456_510.port_b.T; TC_456_510.port_a.Q_flow = TC_456_510.Q_flow; TC_456_510.port_b.Q_flow = -TC_456_510.Q_flow; TC_456_985.Q_flow = TC_456_985.G * TC_456_985.dT; TC_456_985.dT = TC_456_985.port_a.T - TC_456_985.port_b.T; TC_456_985.port_a.Q_flow = TC_456_985.Q_flow; TC_456_985.port_b.Q_flow = -TC_456_985.Q_flow; TC_457_459.Q_flow = TC_457_459.G * TC_457_459.dT; TC_457_459.dT = TC_457_459.port_a.T - TC_457_459.port_b.T; TC_457_459.port_a.Q_flow = TC_457_459.Q_flow; TC_457_459.port_b.Q_flow = -TC_457_459.Q_flow; TC_457_511.Q_flow = TC_457_511.G * TC_457_511.dT; TC_457_511.dT = TC_457_511.port_a.T - TC_457_511.port_b.T; TC_457_511.port_a.Q_flow = TC_457_511.Q_flow; TC_457_511.port_b.Q_flow = -TC_457_511.Q_flow; TC_457_989.Q_flow = TC_457_989.G * TC_457_989.dT; TC_457_989.dT = TC_457_989.port_a.T - TC_457_989.port_b.T; TC_457_989.port_a.Q_flow = TC_457_989.Q_flow; TC_457_989.port_b.Q_flow = -TC_457_989.Q_flow; TC_458_460.Q_flow = TC_458_460.G * TC_458_460.dT; TC_458_460.dT = TC_458_460.port_a.T - TC_458_460.port_b.T; TC_458_460.port_a.Q_flow = TC_458_460.Q_flow; TC_458_460.port_b.Q_flow = -TC_458_460.Q_flow; TC_458_512.Q_flow = TC_458_512.G * TC_458_512.dT; TC_458_512.dT = TC_458_512.port_a.T - TC_458_512.port_b.T; TC_458_512.port_a.Q_flow = TC_458_512.Q_flow; TC_458_512.port_b.Q_flow = -TC_458_512.Q_flow; TC_458_990.Q_flow = TC_458_990.G * TC_458_990.dT; TC_458_990.dT = TC_458_990.port_a.T - TC_458_990.port_b.T; TC_458_990.port_a.Q_flow = TC_458_990.Q_flow; TC_458_990.port_b.Q_flow = -TC_458_990.Q_flow; TC_459_461.Q_flow = TC_459_461.G * TC_459_461.dT; TC_459_461.dT = TC_459_461.port_a.T - TC_459_461.port_b.T; TC_459_461.port_a.Q_flow = TC_459_461.Q_flow; TC_459_461.port_b.Q_flow = -TC_459_461.Q_flow; TC_459_513.Q_flow = TC_459_513.G * TC_459_513.dT; TC_459_513.dT = TC_459_513.port_a.T - TC_459_513.port_b.T; TC_459_513.port_a.Q_flow = TC_459_513.Q_flow; TC_459_513.port_b.Q_flow = -TC_459_513.Q_flow; TC_459_997.Q_flow = TC_459_997.G * TC_459_997.dT; TC_459_997.dT = TC_459_997.port_a.T - TC_459_997.port_b.T; TC_459_997.port_a.Q_flow = TC_459_997.Q_flow; TC_459_997.port_b.Q_flow = -TC_459_997.Q_flow; TC_460_462.Q_flow = TC_460_462.G * TC_460_462.dT; TC_460_462.dT = TC_460_462.port_a.T - TC_460_462.port_b.T; TC_460_462.port_a.Q_flow = TC_460_462.Q_flow; TC_460_462.port_b.Q_flow = -TC_460_462.Q_flow; TC_460_514.Q_flow = TC_460_514.G * TC_460_514.dT; TC_460_514.dT = TC_460_514.port_a.T - TC_460_514.port_b.T; TC_460_514.port_a.Q_flow = TC_460_514.Q_flow; TC_460_514.port_b.Q_flow = -TC_460_514.Q_flow; TC_460_998.Q_flow = TC_460_998.G * TC_460_998.dT; TC_460_998.dT = TC_460_998.port_a.T - TC_460_998.port_b.T; TC_460_998.port_a.Q_flow = TC_460_998.Q_flow; TC_460_998.port_b.Q_flow = -TC_460_998.Q_flow; TC_461_463.Q_flow = TC_461_463.G * TC_461_463.dT; TC_461_463.dT = TC_461_463.port_a.T - TC_461_463.port_b.T; TC_461_463.port_a.Q_flow = TC_461_463.Q_flow; TC_461_463.port_b.Q_flow = -TC_461_463.Q_flow; TC_461_515.Q_flow = TC_461_515.G * TC_461_515.dT; TC_461_515.dT = TC_461_515.port_a.T - TC_461_515.port_b.T; TC_461_515.port_a.Q_flow = TC_461_515.Q_flow; TC_461_515.port_b.Q_flow = -TC_461_515.Q_flow; TC_461_1005.Q_flow = TC_461_1005.G * TC_461_1005.dT; TC_461_1005.dT = TC_461_1005.port_a.T - TC_461_1005.port_b.T; TC_461_1005.port_a.Q_flow = TC_461_1005.Q_flow; TC_461_1005.port_b.Q_flow = -TC_461_1005.Q_flow; TC_462_464.Q_flow = TC_462_464.G * TC_462_464.dT; TC_462_464.dT = TC_462_464.port_a.T - TC_462_464.port_b.T; TC_462_464.port_a.Q_flow = TC_462_464.Q_flow; TC_462_464.port_b.Q_flow = -TC_462_464.Q_flow; TC_462_516.Q_flow = TC_462_516.G * TC_462_516.dT; TC_462_516.dT = TC_462_516.port_a.T - TC_462_516.port_b.T; TC_462_516.port_a.Q_flow = TC_462_516.Q_flow; TC_462_516.port_b.Q_flow = -TC_462_516.Q_flow; TC_462_1006.Q_flow = TC_462_1006.G * TC_462_1006.dT; TC_462_1006.dT = TC_462_1006.port_a.T - TC_462_1006.port_b.T; TC_462_1006.port_a.Q_flow = TC_462_1006.Q_flow; TC_462_1006.port_b.Q_flow = -TC_462_1006.Q_flow; TC_463_465.Q_flow = TC_463_465.G * TC_463_465.dT; TC_463_465.dT = TC_463_465.port_a.T - TC_463_465.port_b.T; TC_463_465.port_a.Q_flow = TC_463_465.Q_flow; TC_463_465.port_b.Q_flow = -TC_463_465.Q_flow; TC_463_517.Q_flow = TC_463_517.G * TC_463_517.dT; TC_463_517.dT = TC_463_517.port_a.T - TC_463_517.port_b.T; TC_463_517.port_a.Q_flow = TC_463_517.Q_flow; TC_463_517.port_b.Q_flow = -TC_463_517.Q_flow; TC_463_1016.Q_flow = TC_463_1016.G * TC_463_1016.dT; TC_463_1016.dT = TC_463_1016.port_a.T - TC_463_1016.port_b.T; TC_463_1016.port_a.Q_flow = TC_463_1016.Q_flow; TC_463_1016.port_b.Q_flow = -TC_463_1016.Q_flow; TC_464_466.Q_flow = TC_464_466.G * TC_464_466.dT; TC_464_466.dT = TC_464_466.port_a.T - TC_464_466.port_b.T; TC_464_466.port_a.Q_flow = TC_464_466.Q_flow; TC_464_466.port_b.Q_flow = -TC_464_466.Q_flow; TC_464_518.Q_flow = TC_464_518.G * TC_464_518.dT; TC_464_518.dT = TC_464_518.port_a.T - TC_464_518.port_b.T; TC_464_518.port_a.Q_flow = TC_464_518.Q_flow; TC_464_518.port_b.Q_flow = -TC_464_518.Q_flow; TC_464_1017.Q_flow = TC_464_1017.G * TC_464_1017.dT; TC_464_1017.dT = TC_464_1017.port_a.T - TC_464_1017.port_b.T; TC_464_1017.port_a.Q_flow = TC_464_1017.Q_flow; TC_464_1017.port_b.Q_flow = -TC_464_1017.Q_flow; TC_465_478.Q_flow = TC_465_478.G * TC_465_478.dT; TC_465_478.dT = TC_465_478.port_a.T - TC_465_478.port_b.T; TC_465_478.port_a.Q_flow = TC_465_478.Q_flow; TC_465_478.port_b.Q_flow = -TC_465_478.Q_flow; TC_465_519.Q_flow = TC_465_519.G * TC_465_519.dT; TC_465_519.dT = TC_465_519.port_a.T - TC_465_519.port_b.T; TC_465_519.port_a.Q_flow = TC_465_519.Q_flow; TC_465_519.port_b.Q_flow = -TC_465_519.Q_flow; TC_465_1027.Q_flow = TC_465_1027.G * TC_465_1027.dT; TC_465_1027.dT = TC_465_1027.port_a.T - TC_465_1027.port_b.T; TC_465_1027.port_a.Q_flow = TC_465_1027.Q_flow; TC_465_1027.port_b.Q_flow = -TC_465_1027.Q_flow; TC_466_467.Q_flow = TC_466_467.G * TC_466_467.dT; TC_466_467.dT = TC_466_467.port_a.T - TC_466_467.port_b.T; TC_466_467.port_a.Q_flow = TC_466_467.Q_flow; TC_466_467.port_b.Q_flow = -TC_466_467.Q_flow; TC_466_520.Q_flow = TC_466_520.G * TC_466_520.dT; TC_466_520.dT = TC_466_520.port_a.T - TC_466_520.port_b.T; TC_466_520.port_a.Q_flow = TC_466_520.Q_flow; TC_466_520.port_b.Q_flow = -TC_466_520.Q_flow; TC_467_468.Q_flow = TC_467_468.G * TC_467_468.dT; TC_467_468.dT = TC_467_468.port_a.T - TC_467_468.port_b.T; TC_467_468.port_a.Q_flow = TC_467_468.Q_flow; TC_467_468.port_b.Q_flow = -TC_467_468.Q_flow; TC_467_521.Q_flow = TC_467_521.G * TC_467_521.dT; TC_467_521.dT = TC_467_521.port_a.T - TC_467_521.port_b.T; TC_467_521.port_a.Q_flow = TC_467_521.Q_flow; TC_467_521.port_b.Q_flow = -TC_467_521.Q_flow; TC_467_1017.Q_flow = TC_467_1017.G * TC_467_1017.dT; TC_467_1017.dT = TC_467_1017.port_a.T - TC_467_1017.port_b.T; TC_467_1017.port_a.Q_flow = TC_467_1017.Q_flow; TC_467_1017.port_b.Q_flow = -TC_467_1017.Q_flow; TC_468_469.Q_flow = TC_468_469.G * TC_468_469.dT; TC_468_469.dT = TC_468_469.port_a.T - TC_468_469.port_b.T; TC_468_469.port_a.Q_flow = TC_468_469.Q_flow; TC_468_469.port_b.Q_flow = -TC_468_469.Q_flow; TC_468_522.Q_flow = TC_468_522.G * TC_468_522.dT; TC_468_522.dT = TC_468_522.port_a.T - TC_468_522.port_b.T; TC_468_522.port_a.Q_flow = TC_468_522.Q_flow; TC_468_522.port_b.Q_flow = -TC_468_522.Q_flow; TC_468_1018.Q_flow = TC_468_1018.G * TC_468_1018.dT; TC_468_1018.dT = TC_468_1018.port_a.T - TC_468_1018.port_b.T; TC_468_1018.port_a.Q_flow = TC_468_1018.Q_flow; TC_468_1018.port_b.Q_flow = -TC_468_1018.Q_flow; TC_469_470.Q_flow = TC_469_470.G * TC_469_470.dT; TC_469_470.dT = TC_469_470.port_a.T - TC_469_470.port_b.T; TC_469_470.port_a.Q_flow = TC_469_470.Q_flow; TC_469_470.port_b.Q_flow = -TC_469_470.Q_flow; TC_469_523.Q_flow = TC_469_523.G * TC_469_523.dT; TC_469_523.dT = TC_469_523.port_a.T - TC_469_523.port_b.T; TC_469_523.port_a.Q_flow = TC_469_523.Q_flow; TC_469_523.port_b.Q_flow = -TC_469_523.Q_flow; TC_469_1019.Q_flow = TC_469_1019.G * TC_469_1019.dT; TC_469_1019.dT = TC_469_1019.port_a.T - TC_469_1019.port_b.T; TC_469_1019.port_a.Q_flow = TC_469_1019.Q_flow; TC_469_1019.port_b.Q_flow = -TC_469_1019.Q_flow; TC_470_471.Q_flow = TC_470_471.G * TC_470_471.dT; TC_470_471.dT = TC_470_471.port_a.T - TC_470_471.port_b.T; TC_470_471.port_a.Q_flow = TC_470_471.Q_flow; TC_470_471.port_b.Q_flow = -TC_470_471.Q_flow; TC_470_524.Q_flow = TC_470_524.G * TC_470_524.dT; TC_470_524.dT = TC_470_524.port_a.T - TC_470_524.port_b.T; TC_470_524.port_a.Q_flow = TC_470_524.Q_flow; TC_470_524.port_b.Q_flow = -TC_470_524.Q_flow; TC_470_1020.Q_flow = TC_470_1020.G * TC_470_1020.dT; TC_470_1020.dT = TC_470_1020.port_a.T - TC_470_1020.port_b.T; TC_470_1020.port_a.Q_flow = TC_470_1020.Q_flow; TC_470_1020.port_b.Q_flow = -TC_470_1020.Q_flow; TC_471_472.Q_flow = TC_471_472.G * TC_471_472.dT; TC_471_472.dT = TC_471_472.port_a.T - TC_471_472.port_b.T; TC_471_472.port_a.Q_flow = TC_471_472.Q_flow; TC_471_472.port_b.Q_flow = -TC_471_472.Q_flow; TC_471_525.Q_flow = TC_471_525.G * TC_471_525.dT; TC_471_525.dT = TC_471_525.port_a.T - TC_471_525.port_b.T; TC_471_525.port_a.Q_flow = TC_471_525.Q_flow; TC_471_525.port_b.Q_flow = -TC_471_525.Q_flow; TC_471_1021.Q_flow = TC_471_1021.G * TC_471_1021.dT; TC_471_1021.dT = TC_471_1021.port_a.T - TC_471_1021.port_b.T; TC_471_1021.port_a.Q_flow = TC_471_1021.Q_flow; TC_471_1021.port_b.Q_flow = -TC_471_1021.Q_flow; TC_472_473.Q_flow = TC_472_473.G * TC_472_473.dT; TC_472_473.dT = TC_472_473.port_a.T - TC_472_473.port_b.T; TC_472_473.port_a.Q_flow = TC_472_473.Q_flow; TC_472_473.port_b.Q_flow = -TC_472_473.Q_flow; TC_472_526.Q_flow = TC_472_526.G * TC_472_526.dT; TC_472_526.dT = TC_472_526.port_a.T - TC_472_526.port_b.T; TC_472_526.port_a.Q_flow = TC_472_526.Q_flow; TC_472_526.port_b.Q_flow = -TC_472_526.Q_flow; TC_472_1022.Q_flow = TC_472_1022.G * TC_472_1022.dT; TC_472_1022.dT = TC_472_1022.port_a.T - TC_472_1022.port_b.T; TC_472_1022.port_a.Q_flow = TC_472_1022.Q_flow; TC_472_1022.port_b.Q_flow = -TC_472_1022.Q_flow; TC_473_474.Q_flow = TC_473_474.G * TC_473_474.dT; TC_473_474.dT = TC_473_474.port_a.T - TC_473_474.port_b.T; TC_473_474.port_a.Q_flow = TC_473_474.Q_flow; TC_473_474.port_b.Q_flow = -TC_473_474.Q_flow; TC_473_527.Q_flow = TC_473_527.G * TC_473_527.dT; TC_473_527.dT = TC_473_527.port_a.T - TC_473_527.port_b.T; TC_473_527.port_a.Q_flow = TC_473_527.Q_flow; TC_473_527.port_b.Q_flow = -TC_473_527.Q_flow; TC_473_1023.Q_flow = TC_473_1023.G * TC_473_1023.dT; TC_473_1023.dT = TC_473_1023.port_a.T - TC_473_1023.port_b.T; TC_473_1023.port_a.Q_flow = TC_473_1023.Q_flow; TC_473_1023.port_b.Q_flow = -TC_473_1023.Q_flow; TC_474_475.Q_flow = TC_474_475.G * TC_474_475.dT; TC_474_475.dT = TC_474_475.port_a.T - TC_474_475.port_b.T; TC_474_475.port_a.Q_flow = TC_474_475.Q_flow; TC_474_475.port_b.Q_flow = -TC_474_475.Q_flow; TC_474_528.Q_flow = TC_474_528.G * TC_474_528.dT; TC_474_528.dT = TC_474_528.port_a.T - TC_474_528.port_b.T; TC_474_528.port_a.Q_flow = TC_474_528.Q_flow; TC_474_528.port_b.Q_flow = -TC_474_528.Q_flow; TC_474_1024.Q_flow = TC_474_1024.G * TC_474_1024.dT; TC_474_1024.dT = TC_474_1024.port_a.T - TC_474_1024.port_b.T; TC_474_1024.port_a.Q_flow = TC_474_1024.Q_flow; TC_474_1024.port_b.Q_flow = -TC_474_1024.Q_flow; TC_475_476.Q_flow = TC_475_476.G * TC_475_476.dT; TC_475_476.dT = TC_475_476.port_a.T - TC_475_476.port_b.T; TC_475_476.port_a.Q_flow = TC_475_476.Q_flow; TC_475_476.port_b.Q_flow = -TC_475_476.Q_flow; TC_475_529.Q_flow = TC_475_529.G * TC_475_529.dT; TC_475_529.dT = TC_475_529.port_a.T - TC_475_529.port_b.T; TC_475_529.port_a.Q_flow = TC_475_529.Q_flow; TC_475_529.port_b.Q_flow = -TC_475_529.Q_flow; TC_475_1025.Q_flow = TC_475_1025.G * TC_475_1025.dT; TC_475_1025.dT = TC_475_1025.port_a.T - TC_475_1025.port_b.T; TC_475_1025.port_a.Q_flow = TC_475_1025.Q_flow; TC_475_1025.port_b.Q_flow = -TC_475_1025.Q_flow; TC_476_477.Q_flow = TC_476_477.G * TC_476_477.dT; TC_476_477.dT = TC_476_477.port_a.T - TC_476_477.port_b.T; TC_476_477.port_a.Q_flow = TC_476_477.Q_flow; TC_476_477.port_b.Q_flow = -TC_476_477.Q_flow; TC_476_530.Q_flow = TC_476_530.G * TC_476_530.dT; TC_476_530.dT = TC_476_530.port_a.T - TC_476_530.port_b.T; TC_476_530.port_a.Q_flow = TC_476_530.Q_flow; TC_476_530.port_b.Q_flow = -TC_476_530.Q_flow; TC_476_1026.Q_flow = TC_476_1026.G * TC_476_1026.dT; TC_476_1026.dT = TC_476_1026.port_a.T - TC_476_1026.port_b.T; TC_476_1026.port_a.Q_flow = TC_476_1026.Q_flow; TC_476_1026.port_b.Q_flow = -TC_476_1026.Q_flow; TC_477_478.Q_flow = TC_477_478.G * TC_477_478.dT; TC_477_478.dT = TC_477_478.port_a.T - TC_477_478.port_b.T; TC_477_478.port_a.Q_flow = TC_477_478.Q_flow; TC_477_478.port_b.Q_flow = -TC_477_478.Q_flow; TC_477_531.Q_flow = TC_477_531.G * TC_477_531.dT; TC_477_531.dT = TC_477_531.port_a.T - TC_477_531.port_b.T; TC_477_531.port_a.Q_flow = TC_477_531.Q_flow; TC_477_531.port_b.Q_flow = -TC_477_531.Q_flow; TC_477_1027.Q_flow = TC_477_1027.G * TC_477_1027.dT; TC_477_1027.dT = TC_477_1027.port_a.T - TC_477_1027.port_b.T; TC_477_1027.port_a.Q_flow = TC_477_1027.Q_flow; TC_477_1027.port_b.Q_flow = -TC_477_1027.Q_flow; TC_478_532.Q_flow = TC_478_532.G * TC_478_532.dT; TC_478_532.dT = TC_478_532.port_a.T - TC_478_532.port_b.T; TC_478_532.port_a.Q_flow = TC_478_532.Q_flow; TC_478_532.port_b.Q_flow = -TC_478_532.Q_flow; TC_479_480.Q_flow = TC_479_480.G * TC_479_480.dT; TC_479_480.dT = TC_479_480.port_a.T - TC_479_480.port_b.T; TC_479_480.port_a.Q_flow = TC_479_480.Q_flow; TC_479_480.port_b.Q_flow = -TC_479_480.Q_flow; TC_479_492.Q_flow = TC_479_492.G * TC_479_492.dT; TC_479_492.dT = TC_479_492.port_a.T - TC_479_492.port_b.T; TC_479_492.port_a.Q_flow = TC_479_492.Q_flow; TC_479_492.port_b.Q_flow = -TC_479_492.Q_flow; TC_479_533.Q_flow = TC_479_533.G * TC_479_533.dT; TC_479_533.dT = TC_479_533.port_a.T - TC_479_533.port_b.T; TC_479_533.port_a.Q_flow = TC_479_533.Q_flow; TC_479_533.port_b.Q_flow = -TC_479_533.Q_flow; TC_480_481.Q_flow = TC_480_481.G * TC_480_481.dT; TC_480_481.dT = TC_480_481.port_a.T - TC_480_481.port_b.T; TC_480_481.port_a.Q_flow = TC_480_481.Q_flow; TC_480_481.port_b.Q_flow = -TC_480_481.Q_flow; TC_480_534.Q_flow = TC_480_534.G * TC_480_534.dT; TC_480_534.dT = TC_480_534.port_a.T - TC_480_534.port_b.T; TC_480_534.port_a.Q_flow = TC_480_534.Q_flow; TC_480_534.port_b.Q_flow = -TC_480_534.Q_flow; TC_480_920.Q_flow = TC_480_920.G * TC_480_920.dT; TC_480_920.dT = TC_480_920.port_a.T - TC_480_920.port_b.T; TC_480_920.port_a.Q_flow = TC_480_920.Q_flow; TC_480_920.port_b.Q_flow = -TC_480_920.Q_flow; TC_481_482.Q_flow = TC_481_482.G * TC_481_482.dT; TC_481_482.dT = TC_481_482.port_a.T - TC_481_482.port_b.T; TC_481_482.port_a.Q_flow = TC_481_482.Q_flow; TC_481_482.port_b.Q_flow = -TC_481_482.Q_flow; TC_481_535.Q_flow = TC_481_535.G * TC_481_535.dT; TC_481_535.dT = TC_481_535.port_a.T - TC_481_535.port_b.T; TC_481_535.port_a.Q_flow = TC_481_535.Q_flow; TC_481_535.port_b.Q_flow = -TC_481_535.Q_flow; TC_481_921.Q_flow = TC_481_921.G * TC_481_921.dT; TC_481_921.dT = TC_481_921.port_a.T - TC_481_921.port_b.T; TC_481_921.port_a.Q_flow = TC_481_921.Q_flow; TC_481_921.port_b.Q_flow = -TC_481_921.Q_flow; TC_482_483.Q_flow = TC_482_483.G * TC_482_483.dT; TC_482_483.dT = TC_482_483.port_a.T - TC_482_483.port_b.T; TC_482_483.port_a.Q_flow = TC_482_483.Q_flow; TC_482_483.port_b.Q_flow = -TC_482_483.Q_flow; TC_482_536.Q_flow = TC_482_536.G * TC_482_536.dT; TC_482_536.dT = TC_482_536.port_a.T - TC_482_536.port_b.T; TC_482_536.port_a.Q_flow = TC_482_536.Q_flow; TC_482_536.port_b.Q_flow = -TC_482_536.Q_flow; TC_482_922.Q_flow = TC_482_922.G * TC_482_922.dT; TC_482_922.dT = TC_482_922.port_a.T - TC_482_922.port_b.T; TC_482_922.port_a.Q_flow = TC_482_922.Q_flow; TC_482_922.port_b.Q_flow = -TC_482_922.Q_flow; TC_483_484.Q_flow = TC_483_484.G * TC_483_484.dT; TC_483_484.dT = TC_483_484.port_a.T - TC_483_484.port_b.T; TC_483_484.port_a.Q_flow = TC_483_484.Q_flow; TC_483_484.port_b.Q_flow = -TC_483_484.Q_flow; TC_483_537.Q_flow = TC_483_537.G * TC_483_537.dT; TC_483_537.dT = TC_483_537.port_a.T - TC_483_537.port_b.T; TC_483_537.port_a.Q_flow = TC_483_537.Q_flow; TC_483_537.port_b.Q_flow = -TC_483_537.Q_flow; TC_483_923.Q_flow = TC_483_923.G * TC_483_923.dT; TC_483_923.dT = TC_483_923.port_a.T - TC_483_923.port_b.T; TC_483_923.port_a.Q_flow = TC_483_923.Q_flow; TC_483_923.port_b.Q_flow = -TC_483_923.Q_flow; TC_484_485.Q_flow = TC_484_485.G * TC_484_485.dT; TC_484_485.dT = TC_484_485.port_a.T - TC_484_485.port_b.T; TC_484_485.port_a.Q_flow = TC_484_485.Q_flow; TC_484_485.port_b.Q_flow = -TC_484_485.Q_flow; TC_484_538.Q_flow = TC_484_538.G * TC_484_538.dT; TC_484_538.dT = TC_484_538.port_a.T - TC_484_538.port_b.T; TC_484_538.port_a.Q_flow = TC_484_538.Q_flow; TC_484_538.port_b.Q_flow = -TC_484_538.Q_flow; TC_484_924.Q_flow = TC_484_924.G * TC_484_924.dT; TC_484_924.dT = TC_484_924.port_a.T - TC_484_924.port_b.T; TC_484_924.port_a.Q_flow = TC_484_924.Q_flow; TC_484_924.port_b.Q_flow = -TC_484_924.Q_flow; TC_485_486.Q_flow = TC_485_486.G * TC_485_486.dT; TC_485_486.dT = TC_485_486.port_a.T - TC_485_486.port_b.T; TC_485_486.port_a.Q_flow = TC_485_486.Q_flow; TC_485_486.port_b.Q_flow = -TC_485_486.Q_flow; TC_485_539.Q_flow = TC_485_539.G * TC_485_539.dT; TC_485_539.dT = TC_485_539.port_a.T - TC_485_539.port_b.T; TC_485_539.port_a.Q_flow = TC_485_539.Q_flow; TC_485_539.port_b.Q_flow = -TC_485_539.Q_flow; TC_485_925.Q_flow = TC_485_925.G * TC_485_925.dT; TC_485_925.dT = TC_485_925.port_a.T - TC_485_925.port_b.T; TC_485_925.port_a.Q_flow = TC_485_925.Q_flow; TC_485_925.port_b.Q_flow = -TC_485_925.Q_flow; TC_486_487.Q_flow = TC_486_487.G * TC_486_487.dT; TC_486_487.dT = TC_486_487.port_a.T - TC_486_487.port_b.T; TC_486_487.port_a.Q_flow = TC_486_487.Q_flow; TC_486_487.port_b.Q_flow = -TC_486_487.Q_flow; TC_486_540.Q_flow = TC_486_540.G * TC_486_540.dT; TC_486_540.dT = TC_486_540.port_a.T - TC_486_540.port_b.T; TC_486_540.port_a.Q_flow = TC_486_540.Q_flow; TC_486_540.port_b.Q_flow = -TC_486_540.Q_flow; TC_486_926.Q_flow = TC_486_926.G * TC_486_926.dT; TC_486_926.dT = TC_486_926.port_a.T - TC_486_926.port_b.T; TC_486_926.port_a.Q_flow = TC_486_926.Q_flow; TC_486_926.port_b.Q_flow = -TC_486_926.Q_flow; TC_487_488.Q_flow = TC_487_488.G * TC_487_488.dT; TC_487_488.dT = TC_487_488.port_a.T - TC_487_488.port_b.T; TC_487_488.port_a.Q_flow = TC_487_488.Q_flow; TC_487_488.port_b.Q_flow = -TC_487_488.Q_flow; TC_487_541.Q_flow = TC_487_541.G * TC_487_541.dT; TC_487_541.dT = TC_487_541.port_a.T - TC_487_541.port_b.T; TC_487_541.port_a.Q_flow = TC_487_541.Q_flow; TC_487_541.port_b.Q_flow = -TC_487_541.Q_flow; TC_487_927.Q_flow = TC_487_927.G * TC_487_927.dT; TC_487_927.dT = TC_487_927.port_a.T - TC_487_927.port_b.T; TC_487_927.port_a.Q_flow = TC_487_927.Q_flow; TC_487_927.port_b.Q_flow = -TC_487_927.Q_flow; TC_488_489.Q_flow = TC_488_489.G * TC_488_489.dT; TC_488_489.dT = TC_488_489.port_a.T - TC_488_489.port_b.T; TC_488_489.port_a.Q_flow = TC_488_489.Q_flow; TC_488_489.port_b.Q_flow = -TC_488_489.Q_flow; TC_488_542.Q_flow = TC_488_542.G * TC_488_542.dT; TC_488_542.dT = TC_488_542.port_a.T - TC_488_542.port_b.T; TC_488_542.port_a.Q_flow = TC_488_542.Q_flow; TC_488_542.port_b.Q_flow = -TC_488_542.Q_flow; TC_488_928.Q_flow = TC_488_928.G * TC_488_928.dT; TC_488_928.dT = TC_488_928.port_a.T - TC_488_928.port_b.T; TC_488_928.port_a.Q_flow = TC_488_928.Q_flow; TC_488_928.port_b.Q_flow = -TC_488_928.Q_flow; TC_489_490.Q_flow = TC_489_490.G * TC_489_490.dT; TC_489_490.dT = TC_489_490.port_a.T - TC_489_490.port_b.T; TC_489_490.port_a.Q_flow = TC_489_490.Q_flow; TC_489_490.port_b.Q_flow = -TC_489_490.Q_flow; TC_489_543.Q_flow = TC_489_543.G * TC_489_543.dT; TC_489_543.dT = TC_489_543.port_a.T - TC_489_543.port_b.T; TC_489_543.port_a.Q_flow = TC_489_543.Q_flow; TC_489_543.port_b.Q_flow = -TC_489_543.Q_flow; TC_489_929.Q_flow = TC_489_929.G * TC_489_929.dT; TC_489_929.dT = TC_489_929.port_a.T - TC_489_929.port_b.T; TC_489_929.port_a.Q_flow = TC_489_929.Q_flow; TC_489_929.port_b.Q_flow = -TC_489_929.Q_flow; TC_490_491.Q_flow = TC_490_491.G * TC_490_491.dT; TC_490_491.dT = TC_490_491.port_a.T - TC_490_491.port_b.T; TC_490_491.port_a.Q_flow = TC_490_491.Q_flow; TC_490_491.port_b.Q_flow = -TC_490_491.Q_flow; TC_490_544.Q_flow = TC_490_544.G * TC_490_544.dT; TC_490_544.dT = TC_490_544.port_a.T - TC_490_544.port_b.T; TC_490_544.port_a.Q_flow = TC_490_544.Q_flow; TC_490_544.port_b.Q_flow = -TC_490_544.Q_flow; TC_490_930.Q_flow = TC_490_930.G * TC_490_930.dT; TC_490_930.dT = TC_490_930.port_a.T - TC_490_930.port_b.T; TC_490_930.port_a.Q_flow = TC_490_930.Q_flow; TC_490_930.port_b.Q_flow = -TC_490_930.Q_flow; TC_491_493.Q_flow = TC_491_493.G * TC_491_493.dT; TC_491_493.dT = TC_491_493.port_a.T - TC_491_493.port_b.T; TC_491_493.port_a.Q_flow = TC_491_493.Q_flow; TC_491_493.port_b.Q_flow = -TC_491_493.Q_flow; TC_491_545.Q_flow = TC_491_545.G * TC_491_545.dT; TC_491_545.dT = TC_491_545.port_a.T - TC_491_545.port_b.T; TC_491_545.port_a.Q_flow = TC_491_545.Q_flow; TC_491_545.port_b.Q_flow = -TC_491_545.Q_flow; TC_492_494.Q_flow = TC_492_494.G * TC_492_494.dT; TC_492_494.dT = TC_492_494.port_a.T - TC_492_494.port_b.T; TC_492_494.port_a.Q_flow = TC_492_494.Q_flow; TC_492_494.port_b.Q_flow = -TC_492_494.Q_flow; TC_492_546.Q_flow = TC_492_546.G * TC_492_546.dT; TC_492_546.dT = TC_492_546.port_a.T - TC_492_546.port_b.T; TC_492_546.port_a.Q_flow = TC_492_546.Q_flow; TC_492_546.port_b.Q_flow = -TC_492_546.Q_flow; TC_492_920.Q_flow = TC_492_920.G * TC_492_920.dT; TC_492_920.dT = TC_492_920.port_a.T - TC_492_920.port_b.T; TC_492_920.port_a.Q_flow = TC_492_920.Q_flow; TC_492_920.port_b.Q_flow = -TC_492_920.Q_flow; TC_493_495.Q_flow = TC_493_495.G * TC_493_495.dT; TC_493_495.dT = TC_493_495.port_a.T - TC_493_495.port_b.T; TC_493_495.port_a.Q_flow = TC_493_495.Q_flow; TC_493_495.port_b.Q_flow = -TC_493_495.Q_flow; TC_493_558.Q_flow = TC_493_558.G * TC_493_558.dT; TC_493_558.dT = TC_493_558.port_a.T - TC_493_558.port_b.T; TC_493_558.port_a.Q_flow = TC_493_558.Q_flow; TC_493_558.port_b.Q_flow = -TC_493_558.Q_flow; TC_493_930.Q_flow = TC_493_930.G * TC_493_930.dT; TC_493_930.dT = TC_493_930.port_a.T - TC_493_930.port_b.T; TC_493_930.port_a.Q_flow = TC_493_930.Q_flow; TC_493_930.port_b.Q_flow = -TC_493_930.Q_flow; TC_494_496.Q_flow = TC_494_496.G * TC_494_496.dT; TC_494_496.dT = TC_494_496.port_a.T - TC_494_496.port_b.T; TC_494_496.port_a.Q_flow = TC_494_496.Q_flow; TC_494_496.port_b.Q_flow = -TC_494_496.Q_flow; TC_494_559.Q_flow = TC_494_559.G * TC_494_559.dT; TC_494_559.dT = TC_494_559.port_a.T - TC_494_559.port_b.T; TC_494_559.port_a.Q_flow = TC_494_559.Q_flow; TC_494_559.port_b.Q_flow = -TC_494_559.Q_flow; TC_494_931.Q_flow = TC_494_931.G * TC_494_931.dT; TC_494_931.dT = TC_494_931.port_a.T - TC_494_931.port_b.T; TC_494_931.port_a.Q_flow = TC_494_931.Q_flow; TC_494_931.port_b.Q_flow = -TC_494_931.Q_flow; TC_495_497.Q_flow = TC_495_497.G * TC_495_497.dT; TC_495_497.dT = TC_495_497.port_a.T - TC_495_497.port_b.T; TC_495_497.port_a.Q_flow = TC_495_497.Q_flow; TC_495_497.port_b.Q_flow = -TC_495_497.Q_flow; TC_495_571.Q_flow = TC_495_571.G * TC_495_571.dT; TC_495_571.dT = TC_495_571.port_a.T - TC_495_571.port_b.T; TC_495_571.port_a.Q_flow = TC_495_571.Q_flow; TC_495_571.port_b.Q_flow = -TC_495_571.Q_flow; TC_495_941.Q_flow = TC_495_941.G * TC_495_941.dT; TC_495_941.dT = TC_495_941.port_a.T - TC_495_941.port_b.T; TC_495_941.port_a.Q_flow = TC_495_941.Q_flow; TC_495_941.port_b.Q_flow = -TC_495_941.Q_flow; TC_496_498.Q_flow = TC_496_498.G * TC_496_498.dT; TC_496_498.dT = TC_496_498.port_a.T - TC_496_498.port_b.T; TC_496_498.port_a.Q_flow = TC_496_498.Q_flow; TC_496_498.port_b.Q_flow = -TC_496_498.Q_flow; TC_496_572.Q_flow = TC_496_572.G * TC_496_572.dT; TC_496_572.dT = TC_496_572.port_a.T - TC_496_572.port_b.T; TC_496_572.port_a.Q_flow = TC_496_572.Q_flow; TC_496_572.port_b.Q_flow = -TC_496_572.Q_flow; TC_496_942.Q_flow = TC_496_942.G * TC_496_942.dT; TC_496_942.dT = TC_496_942.port_a.T - TC_496_942.port_b.T; TC_496_942.port_a.Q_flow = TC_496_942.Q_flow; TC_496_942.port_b.Q_flow = -TC_496_942.Q_flow; TC_497_499.Q_flow = TC_497_499.G * TC_497_499.dT; TC_497_499.dT = TC_497_499.port_a.T - TC_497_499.port_b.T; TC_497_499.port_a.Q_flow = TC_497_499.Q_flow; TC_497_499.port_b.Q_flow = -TC_497_499.Q_flow; TC_497_584.Q_flow = TC_497_584.G * TC_497_584.dT; TC_497_584.dT = TC_497_584.port_a.T - TC_497_584.port_b.T; TC_497_584.port_a.Q_flow = TC_497_584.Q_flow; TC_497_584.port_b.Q_flow = -TC_497_584.Q_flow; TC_497_952.Q_flow = TC_497_952.G * TC_497_952.dT; TC_497_952.dT = TC_497_952.port_a.T - TC_497_952.port_b.T; TC_497_952.port_a.Q_flow = TC_497_952.Q_flow; TC_497_952.port_b.Q_flow = -TC_497_952.Q_flow; TC_498_500.Q_flow = TC_498_500.G * TC_498_500.dT; TC_498_500.dT = TC_498_500.port_a.T - TC_498_500.port_b.T; TC_498_500.port_a.Q_flow = TC_498_500.Q_flow; TC_498_500.port_b.Q_flow = -TC_498_500.Q_flow; TC_498_585.Q_flow = TC_498_585.G * TC_498_585.dT; TC_498_585.dT = TC_498_585.port_a.T - TC_498_585.port_b.T; TC_498_585.port_a.Q_flow = TC_498_585.Q_flow; TC_498_585.port_b.Q_flow = -TC_498_585.Q_flow; TC_498_953.Q_flow = TC_498_953.G * TC_498_953.dT; TC_498_953.dT = TC_498_953.port_a.T - TC_498_953.port_b.T; TC_498_953.port_a.Q_flow = TC_498_953.Q_flow; TC_498_953.port_b.Q_flow = -TC_498_953.Q_flow; TC_499_501.Q_flow = TC_499_501.G * TC_499_501.dT; TC_499_501.dT = TC_499_501.port_a.T - TC_499_501.port_b.T; TC_499_501.port_a.Q_flow = TC_499_501.Q_flow; TC_499_501.port_b.Q_flow = -TC_499_501.Q_flow; TC_499_597.Q_flow = TC_499_597.G * TC_499_597.dT; TC_499_597.dT = TC_499_597.port_a.T - TC_499_597.port_b.T; TC_499_597.port_a.Q_flow = TC_499_597.Q_flow; TC_499_597.port_b.Q_flow = -TC_499_597.Q_flow; TC_499_963.Q_flow = TC_499_963.G * TC_499_963.dT; TC_499_963.dT = TC_499_963.port_a.T - TC_499_963.port_b.T; TC_499_963.port_a.Q_flow = TC_499_963.Q_flow; TC_499_963.port_b.Q_flow = -TC_499_963.Q_flow; TC_500_502.Q_flow = TC_500_502.G * TC_500_502.dT; TC_500_502.dT = TC_500_502.port_a.T - TC_500_502.port_b.T; TC_500_502.port_a.Q_flow = TC_500_502.Q_flow; TC_500_502.port_b.Q_flow = -TC_500_502.Q_flow; TC_500_598.Q_flow = TC_500_598.G * TC_500_598.dT; TC_500_598.dT = TC_500_598.port_a.T - TC_500_598.port_b.T; TC_500_598.port_a.Q_flow = TC_500_598.Q_flow; TC_500_598.port_b.Q_flow = -TC_500_598.Q_flow; TC_500_964.Q_flow = TC_500_964.G * TC_500_964.dT; TC_500_964.dT = TC_500_964.port_a.T - TC_500_964.port_b.T; TC_500_964.port_a.Q_flow = TC_500_964.Q_flow; TC_500_964.port_b.Q_flow = -TC_500_964.Q_flow; TC_501_503.Q_flow = TC_501_503.G * TC_501_503.dT; TC_501_503.dT = TC_501_503.port_a.T - TC_501_503.port_b.T; TC_501_503.port_a.Q_flow = TC_501_503.Q_flow; TC_501_503.port_b.Q_flow = -TC_501_503.Q_flow; TC_501_610.Q_flow = TC_501_610.G * TC_501_610.dT; TC_501_610.dT = TC_501_610.port_a.T - TC_501_610.port_b.T; TC_501_610.port_a.Q_flow = TC_501_610.Q_flow; TC_501_610.port_b.Q_flow = -TC_501_610.Q_flow; TC_501_974.Q_flow = TC_501_974.G * TC_501_974.dT; TC_501_974.dT = TC_501_974.port_a.T - TC_501_974.port_b.T; TC_501_974.port_a.Q_flow = TC_501_974.Q_flow; TC_501_974.port_b.Q_flow = -TC_501_974.Q_flow; TC_502_504.Q_flow = TC_502_504.G * TC_502_504.dT; TC_502_504.dT = TC_502_504.port_a.T - TC_502_504.port_b.T; TC_502_504.port_a.Q_flow = TC_502_504.Q_flow; TC_502_504.port_b.Q_flow = -TC_502_504.Q_flow; TC_502_611.Q_flow = TC_502_611.G * TC_502_611.dT; TC_502_611.dT = TC_502_611.port_a.T - TC_502_611.port_b.T; TC_502_611.port_a.Q_flow = TC_502_611.Q_flow; TC_502_611.port_b.Q_flow = -TC_502_611.Q_flow; TC_502_843.Q_flow = TC_502_843.G * TC_502_843.dT; TC_502_843.dT = TC_502_843.port_a.T - TC_502_843.port_b.T; TC_502_843.port_a.Q_flow = TC_502_843.Q_flow; TC_502_843.port_b.Q_flow = -TC_502_843.Q_flow; TC_503_505.Q_flow = TC_503_505.G * TC_503_505.dT; TC_503_505.dT = TC_503_505.port_a.T - TC_503_505.port_b.T; TC_503_505.port_a.Q_flow = TC_503_505.Q_flow; TC_503_505.port_b.Q_flow = -TC_503_505.Q_flow; TC_503_623.Q_flow = TC_503_623.G * TC_503_623.dT; TC_503_623.dT = TC_503_623.port_a.T - TC_503_623.port_b.T; TC_503_623.port_a.Q_flow = TC_503_623.Q_flow; TC_503_623.port_b.Q_flow = -TC_503_623.Q_flow; TC_503_853.Q_flow = TC_503_853.G * TC_503_853.dT; TC_503_853.dT = TC_503_853.port_a.T - TC_503_853.port_b.T; TC_503_853.port_a.Q_flow = TC_503_853.Q_flow; TC_503_853.port_b.Q_flow = -TC_503_853.Q_flow; TC_504_506.Q_flow = TC_504_506.G * TC_504_506.dT; TC_504_506.dT = TC_504_506.port_a.T - TC_504_506.port_b.T; TC_504_506.port_a.Q_flow = TC_504_506.Q_flow; TC_504_506.port_b.Q_flow = -TC_504_506.Q_flow; TC_504_624.Q_flow = TC_504_624.G * TC_504_624.dT; TC_504_624.dT = TC_504_624.port_a.T - TC_504_624.port_b.T; TC_504_624.port_a.Q_flow = TC_504_624.Q_flow; TC_504_624.port_b.Q_flow = -TC_504_624.Q_flow; TC_504_854.Q_flow = TC_504_854.G * TC_504_854.dT; TC_504_854.dT = TC_504_854.port_a.T - TC_504_854.port_b.T; TC_504_854.port_a.Q_flow = TC_504_854.Q_flow; TC_504_854.port_b.Q_flow = -TC_504_854.Q_flow; TC_505_507.Q_flow = TC_505_507.G * TC_505_507.dT; TC_505_507.dT = TC_505_507.port_a.T - TC_505_507.port_b.T; TC_505_507.port_a.Q_flow = TC_505_507.Q_flow; TC_505_507.port_b.Q_flow = -TC_505_507.Q_flow; TC_505_636.Q_flow = TC_505_636.G * TC_505_636.dT; TC_505_636.dT = TC_505_636.port_a.T - TC_505_636.port_b.T; TC_505_636.port_a.Q_flow = TC_505_636.Q_flow; TC_505_636.port_b.Q_flow = -TC_505_636.Q_flow; TC_505_864.Q_flow = TC_505_864.G * TC_505_864.dT; TC_505_864.dT = TC_505_864.port_a.T - TC_505_864.port_b.T; TC_505_864.port_a.Q_flow = TC_505_864.Q_flow; TC_505_864.port_b.Q_flow = -TC_505_864.Q_flow; TC_506_508.Q_flow = TC_506_508.G * TC_506_508.dT; TC_506_508.dT = TC_506_508.port_a.T - TC_506_508.port_b.T; TC_506_508.port_a.Q_flow = TC_506_508.Q_flow; TC_506_508.port_b.Q_flow = -TC_506_508.Q_flow; TC_506_637.Q_flow = TC_506_637.G * TC_506_637.dT; TC_506_637.dT = TC_506_637.port_a.T - TC_506_637.port_b.T; TC_506_637.port_a.Q_flow = TC_506_637.Q_flow; TC_506_637.port_b.Q_flow = -TC_506_637.Q_flow; TC_506_865.Q_flow = TC_506_865.G * TC_506_865.dT; TC_506_865.dT = TC_506_865.port_a.T - TC_506_865.port_b.T; TC_506_865.port_a.Q_flow = TC_506_865.Q_flow; TC_506_865.port_b.Q_flow = -TC_506_865.Q_flow; TC_507_509.Q_flow = TC_507_509.G * TC_507_509.dT; TC_507_509.dT = TC_507_509.port_a.T - TC_507_509.port_b.T; TC_507_509.port_a.Q_flow = TC_507_509.Q_flow; TC_507_509.port_b.Q_flow = -TC_507_509.Q_flow; TC_507_649.Q_flow = TC_507_649.G * TC_507_649.dT; TC_507_649.dT = TC_507_649.port_a.T - TC_507_649.port_b.T; TC_507_649.port_a.Q_flow = TC_507_649.Q_flow; TC_507_649.port_b.Q_flow = -TC_507_649.Q_flow; TC_507_875.Q_flow = TC_507_875.G * TC_507_875.dT; TC_507_875.dT = TC_507_875.port_a.T - TC_507_875.port_b.T; TC_507_875.port_a.Q_flow = TC_507_875.Q_flow; TC_507_875.port_b.Q_flow = -TC_507_875.Q_flow; TC_508_510.Q_flow = TC_508_510.G * TC_508_510.dT; TC_508_510.dT = TC_508_510.port_a.T - TC_508_510.port_b.T; TC_508_510.port_a.Q_flow = TC_508_510.Q_flow; TC_508_510.port_b.Q_flow = -TC_508_510.Q_flow; TC_508_650.Q_flow = TC_508_650.G * TC_508_650.dT; TC_508_650.dT = TC_508_650.port_a.T - TC_508_650.port_b.T; TC_508_650.port_a.Q_flow = TC_508_650.Q_flow; TC_508_650.port_b.Q_flow = -TC_508_650.Q_flow; TC_508_876.Q_flow = TC_508_876.G * TC_508_876.dT; TC_508_876.dT = TC_508_876.port_a.T - TC_508_876.port_b.T; TC_508_876.port_a.Q_flow = TC_508_876.Q_flow; TC_508_876.port_b.Q_flow = -TC_508_876.Q_flow; TC_509_511.Q_flow = TC_509_511.G * TC_509_511.dT; TC_509_511.dT = TC_509_511.port_a.T - TC_509_511.port_b.T; TC_509_511.port_a.Q_flow = TC_509_511.Q_flow; TC_509_511.port_b.Q_flow = -TC_509_511.Q_flow; TC_509_662.Q_flow = TC_509_662.G * TC_509_662.dT; TC_509_662.dT = TC_509_662.port_a.T - TC_509_662.port_b.T; TC_509_662.port_a.Q_flow = TC_509_662.Q_flow; TC_509_662.port_b.Q_flow = -TC_509_662.Q_flow; TC_509_886.Q_flow = TC_509_886.G * TC_509_886.dT; TC_509_886.dT = TC_509_886.port_a.T - TC_509_886.port_b.T; TC_509_886.port_a.Q_flow = TC_509_886.Q_flow; TC_509_886.port_b.Q_flow = -TC_509_886.Q_flow; TC_510_512.Q_flow = TC_510_512.G * TC_510_512.dT; TC_510_512.dT = TC_510_512.port_a.T - TC_510_512.port_b.T; TC_510_512.port_a.Q_flow = TC_510_512.Q_flow; TC_510_512.port_b.Q_flow = -TC_510_512.Q_flow; TC_510_663.Q_flow = TC_510_663.G * TC_510_663.dT; TC_510_663.dT = TC_510_663.port_a.T - TC_510_663.port_b.T; TC_510_663.port_a.Q_flow = TC_510_663.Q_flow; TC_510_663.port_b.Q_flow = -TC_510_663.Q_flow; TC_510_887.Q_flow = TC_510_887.G * TC_510_887.dT; TC_510_887.dT = TC_510_887.port_a.T - TC_510_887.port_b.T; TC_510_887.port_a.Q_flow = TC_510_887.Q_flow; TC_510_887.port_b.Q_flow = -TC_510_887.Q_flow; TC_511_513.Q_flow = TC_511_513.G * TC_511_513.dT; TC_511_513.dT = TC_511_513.port_a.T - TC_511_513.port_b.T; TC_511_513.port_a.Q_flow = TC_511_513.Q_flow; TC_511_513.port_b.Q_flow = -TC_511_513.Q_flow; TC_511_675.Q_flow = TC_511_675.G * TC_511_675.dT; TC_511_675.dT = TC_511_675.port_a.T - TC_511_675.port_b.T; TC_511_675.port_a.Q_flow = TC_511_675.Q_flow; TC_511_675.port_b.Q_flow = -TC_511_675.Q_flow; TC_511_897.Q_flow = TC_511_897.G * TC_511_897.dT; TC_511_897.dT = TC_511_897.port_a.T - TC_511_897.port_b.T; TC_511_897.port_a.Q_flow = TC_511_897.Q_flow; TC_511_897.port_b.Q_flow = -TC_511_897.Q_flow; TC_512_514.Q_flow = TC_512_514.G * TC_512_514.dT; TC_512_514.dT = TC_512_514.port_a.T - TC_512_514.port_b.T; TC_512_514.port_a.Q_flow = TC_512_514.Q_flow; TC_512_514.port_b.Q_flow = -TC_512_514.Q_flow; TC_512_676.Q_flow = TC_512_676.G * TC_512_676.dT; TC_512_676.dT = TC_512_676.port_a.T - TC_512_676.port_b.T; TC_512_676.port_a.Q_flow = TC_512_676.Q_flow; TC_512_676.port_b.Q_flow = -TC_512_676.Q_flow; TC_512_898.Q_flow = TC_512_898.G * TC_512_898.dT; TC_512_898.dT = TC_512_898.port_a.T - TC_512_898.port_b.T; TC_512_898.port_a.Q_flow = TC_512_898.Q_flow; TC_512_898.port_b.Q_flow = -TC_512_898.Q_flow; TC_513_515.Q_flow = TC_513_515.G * TC_513_515.dT; TC_513_515.dT = TC_513_515.port_a.T - TC_513_515.port_b.T; TC_513_515.port_a.Q_flow = TC_513_515.Q_flow; TC_513_515.port_b.Q_flow = -TC_513_515.Q_flow; TC_513_688.Q_flow = TC_513_688.G * TC_513_688.dT; TC_513_688.dT = TC_513_688.port_a.T - TC_513_688.port_b.T; TC_513_688.port_a.Q_flow = TC_513_688.Q_flow; TC_513_688.port_b.Q_flow = -TC_513_688.Q_flow; TC_513_908.Q_flow = TC_513_908.G * TC_513_908.dT; TC_513_908.dT = TC_513_908.port_a.T - TC_513_908.port_b.T; TC_513_908.port_a.Q_flow = TC_513_908.Q_flow; TC_513_908.port_b.Q_flow = -TC_513_908.Q_flow; TC_514_516.Q_flow = TC_514_516.G * TC_514_516.dT; TC_514_516.dT = TC_514_516.port_a.T - TC_514_516.port_b.T; TC_514_516.port_a.Q_flow = TC_514_516.Q_flow; TC_514_516.port_b.Q_flow = -TC_514_516.Q_flow; TC_514_689.Q_flow = TC_514_689.G * TC_514_689.dT; TC_514_689.dT = TC_514_689.port_a.T - TC_514_689.port_b.T; TC_514_689.port_a.Q_flow = TC_514_689.Q_flow; TC_514_689.port_b.Q_flow = -TC_514_689.Q_flow; TC_514_909.Q_flow = TC_514_909.G * TC_514_909.dT; TC_514_909.dT = TC_514_909.port_a.T - TC_514_909.port_b.T; TC_514_909.port_a.Q_flow = TC_514_909.Q_flow; TC_514_909.port_b.Q_flow = -TC_514_909.Q_flow; TC_515_517.Q_flow = TC_515_517.G * TC_515_517.dT; TC_515_517.dT = TC_515_517.port_a.T - TC_515_517.port_b.T; TC_515_517.port_a.Q_flow = TC_515_517.Q_flow; TC_515_517.port_b.Q_flow = -TC_515_517.Q_flow; TC_515_701.Q_flow = TC_515_701.G * TC_515_701.dT; TC_515_701.dT = TC_515_701.port_a.T - TC_515_701.port_b.T; TC_515_701.port_a.Q_flow = TC_515_701.Q_flow; TC_515_701.port_b.Q_flow = -TC_515_701.Q_flow; TC_515_919.Q_flow = TC_515_919.G * TC_515_919.dT; TC_515_919.dT = TC_515_919.port_a.T - TC_515_919.port_b.T; TC_515_919.port_a.Q_flow = TC_515_919.Q_flow; TC_515_919.port_b.Q_flow = -TC_515_919.Q_flow; TC_516_518.Q_flow = TC_516_518.G * TC_516_518.dT; TC_516_518.dT = TC_516_518.port_a.T - TC_516_518.port_b.T; TC_516_518.port_a.Q_flow = TC_516_518.Q_flow; TC_516_518.port_b.Q_flow = -TC_516_518.Q_flow; TC_516_702.Q_flow = TC_516_702.G * TC_516_702.dT; TC_516_702.dT = TC_516_702.port_a.T - TC_516_702.port_b.T; TC_516_702.port_a.Q_flow = TC_516_702.Q_flow; TC_516_702.port_b.Q_flow = -TC_516_702.Q_flow; TC_516_832.Q_flow = TC_516_832.G * TC_516_832.dT; TC_516_832.dT = TC_516_832.port_a.T - TC_516_832.port_b.T; TC_516_832.port_a.Q_flow = TC_516_832.Q_flow; TC_516_832.port_b.Q_flow = -TC_516_832.Q_flow; TC_517_519.Q_flow = TC_517_519.G * TC_517_519.dT; TC_517_519.dT = TC_517_519.port_a.T - TC_517_519.port_b.T; TC_517_519.port_a.Q_flow = TC_517_519.Q_flow; TC_517_519.port_b.Q_flow = -TC_517_519.Q_flow; TC_517_714.Q_flow = TC_517_714.G * TC_517_714.dT; TC_517_714.dT = TC_517_714.port_a.T - TC_517_714.port_b.T; TC_517_714.port_a.Q_flow = TC_517_714.Q_flow; TC_517_714.port_b.Q_flow = -TC_517_714.Q_flow; TC_517_842.Q_flow = TC_517_842.G * TC_517_842.dT; TC_517_842.dT = TC_517_842.port_a.T - TC_517_842.port_b.T; TC_517_842.port_a.Q_flow = TC_517_842.Q_flow; TC_517_842.port_b.Q_flow = -TC_517_842.Q_flow; TC_518_520.Q_flow = TC_518_520.G * TC_518_520.dT; TC_518_520.dT = TC_518_520.port_a.T - TC_518_520.port_b.T; TC_518_520.port_a.Q_flow = TC_518_520.Q_flow; TC_518_520.port_b.Q_flow = -TC_518_520.Q_flow; TC_518_715.Q_flow = TC_518_715.G * TC_518_715.dT; TC_518_715.dT = TC_518_715.port_a.T - TC_518_715.port_b.T; TC_518_715.port_a.Q_flow = TC_518_715.Q_flow; TC_518_715.port_b.Q_flow = -TC_518_715.Q_flow; TC_518_821.Q_flow = TC_518_821.G * TC_518_821.dT; TC_518_821.dT = TC_518_821.port_a.T - TC_518_821.port_b.T; TC_518_821.port_a.Q_flow = TC_518_821.Q_flow; TC_518_821.port_b.Q_flow = -TC_518_821.Q_flow; TC_519_532.Q_flow = TC_519_532.G * TC_519_532.dT; TC_519_532.dT = TC_519_532.port_a.T - TC_519_532.port_b.T; TC_519_532.port_a.Q_flow = TC_519_532.Q_flow; TC_519_532.port_b.Q_flow = -TC_519_532.Q_flow; TC_519_727.Q_flow = TC_519_727.G * TC_519_727.dT; TC_519_727.dT = TC_519_727.port_a.T - TC_519_727.port_b.T; TC_519_727.port_a.Q_flow = TC_519_727.Q_flow; TC_519_727.port_b.Q_flow = -TC_519_727.Q_flow; TC_519_831.Q_flow = TC_519_831.G * TC_519_831.dT; TC_519_831.dT = TC_519_831.port_a.T - TC_519_831.port_b.T; TC_519_831.port_a.Q_flow = TC_519_831.Q_flow; TC_519_831.port_b.Q_flow = -TC_519_831.Q_flow; TC_520_521.Q_flow = TC_520_521.G * TC_520_521.dT; TC_520_521.dT = TC_520_521.port_a.T - TC_520_521.port_b.T; TC_520_521.port_a.Q_flow = TC_520_521.Q_flow; TC_520_521.port_b.Q_flow = -TC_520_521.Q_flow; TC_520_728.Q_flow = TC_520_728.G * TC_520_728.dT; TC_520_728.dT = TC_520_728.port_a.T - TC_520_728.port_b.T; TC_520_728.port_a.Q_flow = TC_520_728.Q_flow; TC_520_728.port_b.Q_flow = -TC_520_728.Q_flow; TC_521_522.Q_flow = TC_521_522.G * TC_521_522.dT; TC_521_522.dT = TC_521_522.port_a.T - TC_521_522.port_b.T; TC_521_522.port_a.Q_flow = TC_521_522.Q_flow; TC_521_522.port_b.Q_flow = -TC_521_522.Q_flow; TC_521_729.Q_flow = TC_521_729.G * TC_521_729.dT; TC_521_729.dT = TC_521_729.port_a.T - TC_521_729.port_b.T; TC_521_729.port_a.Q_flow = TC_521_729.Q_flow; TC_521_729.port_b.Q_flow = -TC_521_729.Q_flow; TC_521_821.Q_flow = TC_521_821.G * TC_521_821.dT; TC_521_821.dT = TC_521_821.port_a.T - TC_521_821.port_b.T; TC_521_821.port_a.Q_flow = TC_521_821.Q_flow; TC_521_821.port_b.Q_flow = -TC_521_821.Q_flow; TC_522_523.Q_flow = TC_522_523.G * TC_522_523.dT; TC_522_523.dT = TC_522_523.port_a.T - TC_522_523.port_b.T; TC_522_523.port_a.Q_flow = TC_522_523.Q_flow; TC_522_523.port_b.Q_flow = -TC_522_523.Q_flow; TC_522_730.Q_flow = TC_522_730.G * TC_522_730.dT; TC_522_730.dT = TC_522_730.port_a.T - TC_522_730.port_b.T; TC_522_730.port_a.Q_flow = TC_522_730.Q_flow; TC_522_730.port_b.Q_flow = -TC_522_730.Q_flow; TC_522_822.Q_flow = TC_522_822.G * TC_522_822.dT; TC_522_822.dT = TC_522_822.port_a.T - TC_522_822.port_b.T; TC_522_822.port_a.Q_flow = TC_522_822.Q_flow; TC_522_822.port_b.Q_flow = -TC_522_822.Q_flow; TC_523_524.Q_flow = TC_523_524.G * TC_523_524.dT; TC_523_524.dT = TC_523_524.port_a.T - TC_523_524.port_b.T; TC_523_524.port_a.Q_flow = TC_523_524.Q_flow; TC_523_524.port_b.Q_flow = -TC_523_524.Q_flow; TC_523_731.Q_flow = TC_523_731.G * TC_523_731.dT; TC_523_731.dT = TC_523_731.port_a.T - TC_523_731.port_b.T; TC_523_731.port_a.Q_flow = TC_523_731.Q_flow; TC_523_731.port_b.Q_flow = -TC_523_731.Q_flow; TC_523_823.Q_flow = TC_523_823.G * TC_523_823.dT; TC_523_823.dT = TC_523_823.port_a.T - TC_523_823.port_b.T; TC_523_823.port_a.Q_flow = TC_523_823.Q_flow; TC_523_823.port_b.Q_flow = -TC_523_823.Q_flow; TC_524_525.Q_flow = TC_524_525.G * TC_524_525.dT; TC_524_525.dT = TC_524_525.port_a.T - TC_524_525.port_b.T; TC_524_525.port_a.Q_flow = TC_524_525.Q_flow; TC_524_525.port_b.Q_flow = -TC_524_525.Q_flow; TC_524_732.Q_flow = TC_524_732.G * TC_524_732.dT; TC_524_732.dT = TC_524_732.port_a.T - TC_524_732.port_b.T; TC_524_732.port_a.Q_flow = TC_524_732.Q_flow; TC_524_732.port_b.Q_flow = -TC_524_732.Q_flow; TC_524_824.Q_flow = TC_524_824.G * TC_524_824.dT; TC_524_824.dT = TC_524_824.port_a.T - TC_524_824.port_b.T; TC_524_824.port_a.Q_flow = TC_524_824.Q_flow; TC_524_824.port_b.Q_flow = -TC_524_824.Q_flow; TC_525_526.Q_flow = TC_525_526.G * TC_525_526.dT; TC_525_526.dT = TC_525_526.port_a.T - TC_525_526.port_b.T; TC_525_526.port_a.Q_flow = TC_525_526.Q_flow; TC_525_526.port_b.Q_flow = -TC_525_526.Q_flow; TC_525_733.Q_flow = TC_525_733.G * TC_525_733.dT; TC_525_733.dT = TC_525_733.port_a.T - TC_525_733.port_b.T; TC_525_733.port_a.Q_flow = TC_525_733.Q_flow; TC_525_733.port_b.Q_flow = -TC_525_733.Q_flow; TC_525_825.Q_flow = TC_525_825.G * TC_525_825.dT; TC_525_825.dT = TC_525_825.port_a.T - TC_525_825.port_b.T; TC_525_825.port_a.Q_flow = TC_525_825.Q_flow; TC_525_825.port_b.Q_flow = -TC_525_825.Q_flow; TC_526_527.Q_flow = TC_526_527.G * TC_526_527.dT; TC_526_527.dT = TC_526_527.port_a.T - TC_526_527.port_b.T; TC_526_527.port_a.Q_flow = TC_526_527.Q_flow; TC_526_527.port_b.Q_flow = -TC_526_527.Q_flow; TC_526_734.Q_flow = TC_526_734.G * TC_526_734.dT; TC_526_734.dT = TC_526_734.port_a.T - TC_526_734.port_b.T; TC_526_734.port_a.Q_flow = TC_526_734.Q_flow; TC_526_734.port_b.Q_flow = -TC_526_734.Q_flow; TC_526_826.Q_flow = TC_526_826.G * TC_526_826.dT; TC_526_826.dT = TC_526_826.port_a.T - TC_526_826.port_b.T; TC_526_826.port_a.Q_flow = TC_526_826.Q_flow; TC_526_826.port_b.Q_flow = -TC_526_826.Q_flow; TC_527_528.Q_flow = TC_527_528.G * TC_527_528.dT; TC_527_528.dT = TC_527_528.port_a.T - TC_527_528.port_b.T; TC_527_528.port_a.Q_flow = TC_527_528.Q_flow; TC_527_528.port_b.Q_flow = -TC_527_528.Q_flow; TC_527_735.Q_flow = TC_527_735.G * TC_527_735.dT; TC_527_735.dT = TC_527_735.port_a.T - TC_527_735.port_b.T; TC_527_735.port_a.Q_flow = TC_527_735.Q_flow; TC_527_735.port_b.Q_flow = -TC_527_735.Q_flow; TC_527_827.Q_flow = TC_527_827.G * TC_527_827.dT; TC_527_827.dT = TC_527_827.port_a.T - TC_527_827.port_b.T; TC_527_827.port_a.Q_flow = TC_527_827.Q_flow; TC_527_827.port_b.Q_flow = -TC_527_827.Q_flow; TC_528_529.Q_flow = TC_528_529.G * TC_528_529.dT; TC_528_529.dT = TC_528_529.port_a.T - TC_528_529.port_b.T; TC_528_529.port_a.Q_flow = TC_528_529.Q_flow; TC_528_529.port_b.Q_flow = -TC_528_529.Q_flow; TC_528_736.Q_flow = TC_528_736.G * TC_528_736.dT; TC_528_736.dT = TC_528_736.port_a.T - TC_528_736.port_b.T; TC_528_736.port_a.Q_flow = TC_528_736.Q_flow; TC_528_736.port_b.Q_flow = -TC_528_736.Q_flow; TC_528_828.Q_flow = TC_528_828.G * TC_528_828.dT; TC_528_828.dT = TC_528_828.port_a.T - TC_528_828.port_b.T; TC_528_828.port_a.Q_flow = TC_528_828.Q_flow; TC_528_828.port_b.Q_flow = -TC_528_828.Q_flow; TC_529_530.Q_flow = TC_529_530.G * TC_529_530.dT; TC_529_530.dT = TC_529_530.port_a.T - TC_529_530.port_b.T; TC_529_530.port_a.Q_flow = TC_529_530.Q_flow; TC_529_530.port_b.Q_flow = -TC_529_530.Q_flow; TC_529_737.Q_flow = TC_529_737.G * TC_529_737.dT; TC_529_737.dT = TC_529_737.port_a.T - TC_529_737.port_b.T; TC_529_737.port_a.Q_flow = TC_529_737.Q_flow; TC_529_737.port_b.Q_flow = -TC_529_737.Q_flow; TC_529_829.Q_flow = TC_529_829.G * TC_529_829.dT; TC_529_829.dT = TC_529_829.port_a.T - TC_529_829.port_b.T; TC_529_829.port_a.Q_flow = TC_529_829.Q_flow; TC_529_829.port_b.Q_flow = -TC_529_829.Q_flow; TC_530_531.Q_flow = TC_530_531.G * TC_530_531.dT; TC_530_531.dT = TC_530_531.port_a.T - TC_530_531.port_b.T; TC_530_531.port_a.Q_flow = TC_530_531.Q_flow; TC_530_531.port_b.Q_flow = -TC_530_531.Q_flow; TC_530_738.Q_flow = TC_530_738.G * TC_530_738.dT; TC_530_738.dT = TC_530_738.port_a.T - TC_530_738.port_b.T; TC_530_738.port_a.Q_flow = TC_530_738.Q_flow; TC_530_738.port_b.Q_flow = -TC_530_738.Q_flow; TC_530_830.Q_flow = TC_530_830.G * TC_530_830.dT; TC_530_830.dT = TC_530_830.port_a.T - TC_530_830.port_b.T; TC_530_830.port_a.Q_flow = TC_530_830.Q_flow; TC_530_830.port_b.Q_flow = -TC_530_830.Q_flow; TC_531_532.Q_flow = TC_531_532.G * TC_531_532.dT; TC_531_532.dT = TC_531_532.port_a.T - TC_531_532.port_b.T; TC_531_532.port_a.Q_flow = TC_531_532.Q_flow; TC_531_532.port_b.Q_flow = -TC_531_532.Q_flow; TC_531_739.Q_flow = TC_531_739.G * TC_531_739.dT; TC_531_739.dT = TC_531_739.port_a.T - TC_531_739.port_b.T; TC_531_739.port_a.Q_flow = TC_531_739.Q_flow; TC_531_739.port_b.Q_flow = -TC_531_739.Q_flow; TC_531_831.Q_flow = TC_531_831.G * TC_531_831.dT; TC_531_831.dT = TC_531_831.port_a.T - TC_531_831.port_b.T; TC_531_831.port_a.Q_flow = TC_531_831.Q_flow; TC_531_831.port_b.Q_flow = -TC_531_831.Q_flow; TC_532_740.Q_flow = TC_532_740.G * TC_532_740.dT; TC_532_740.dT = TC_532_740.port_a.T - TC_532_740.port_b.T; TC_532_740.port_a.Q_flow = TC_532_740.Q_flow; TC_532_740.port_b.Q_flow = -TC_532_740.Q_flow; TC_533_534.Q_flow = TC_533_534.G * TC_533_534.dT; TC_533_534.dT = TC_533_534.port_a.T - TC_533_534.port_b.T; TC_533_534.port_a.Q_flow = TC_533_534.Q_flow; TC_533_534.port_b.Q_flow = -TC_533_534.Q_flow; TC_533_546.Q_flow = TC_533_546.G * TC_533_546.dT; TC_533_546.dT = TC_533_546.port_a.T - TC_533_546.port_b.T; TC_533_546.port_a.Q_flow = TC_533_546.Q_flow; TC_533_546.port_b.Q_flow = -TC_533_546.Q_flow; TC_534_535.Q_flow = TC_534_535.G * TC_534_535.dT; TC_534_535.dT = TC_534_535.port_a.T - TC_534_535.port_b.T; TC_534_535.port_a.Q_flow = TC_534_535.Q_flow; TC_534_535.port_b.Q_flow = -TC_534_535.Q_flow; TC_534_547.Q_flow = TC_534_547.G * TC_534_547.dT; TC_534_547.dT = TC_534_547.port_a.T - TC_534_547.port_b.T; TC_534_547.port_a.Q_flow = TC_534_547.Q_flow; TC_534_547.port_b.Q_flow = -TC_534_547.Q_flow; TC_535_536.Q_flow = TC_535_536.G * TC_535_536.dT; TC_535_536.dT = TC_535_536.port_a.T - TC_535_536.port_b.T; TC_535_536.port_a.Q_flow = TC_535_536.Q_flow; TC_535_536.port_b.Q_flow = -TC_535_536.Q_flow; TC_535_548.Q_flow = TC_535_548.G * TC_535_548.dT; TC_535_548.dT = TC_535_548.port_a.T - TC_535_548.port_b.T; TC_535_548.port_a.Q_flow = TC_535_548.Q_flow; TC_535_548.port_b.Q_flow = -TC_535_548.Q_flow; TC_536_537.Q_flow = TC_536_537.G * TC_536_537.dT; TC_536_537.dT = TC_536_537.port_a.T - TC_536_537.port_b.T; TC_536_537.port_a.Q_flow = TC_536_537.Q_flow; TC_536_537.port_b.Q_flow = -TC_536_537.Q_flow; TC_536_549.Q_flow = TC_536_549.G * TC_536_549.dT; TC_536_549.dT = TC_536_549.port_a.T - TC_536_549.port_b.T; TC_536_549.port_a.Q_flow = TC_536_549.Q_flow; TC_536_549.port_b.Q_flow = -TC_536_549.Q_flow; TC_537_538.Q_flow = TC_537_538.G * TC_537_538.dT; TC_537_538.dT = TC_537_538.port_a.T - TC_537_538.port_b.T; TC_537_538.port_a.Q_flow = TC_537_538.Q_flow; TC_537_538.port_b.Q_flow = -TC_537_538.Q_flow; TC_537_550.Q_flow = TC_537_550.G * TC_537_550.dT; TC_537_550.dT = TC_537_550.port_a.T - TC_537_550.port_b.T; TC_537_550.port_a.Q_flow = TC_537_550.Q_flow; TC_537_550.port_b.Q_flow = -TC_537_550.Q_flow; TC_538_539.Q_flow = TC_538_539.G * TC_538_539.dT; TC_538_539.dT = TC_538_539.port_a.T - TC_538_539.port_b.T; TC_538_539.port_a.Q_flow = TC_538_539.Q_flow; TC_538_539.port_b.Q_flow = -TC_538_539.Q_flow; TC_538_551.Q_flow = TC_538_551.G * TC_538_551.dT; TC_538_551.dT = TC_538_551.port_a.T - TC_538_551.port_b.T; TC_538_551.port_a.Q_flow = TC_538_551.Q_flow; TC_538_551.port_b.Q_flow = -TC_538_551.Q_flow; TC_539_540.Q_flow = TC_539_540.G * TC_539_540.dT; TC_539_540.dT = TC_539_540.port_a.T - TC_539_540.port_b.T; TC_539_540.port_a.Q_flow = TC_539_540.Q_flow; TC_539_540.port_b.Q_flow = -TC_539_540.Q_flow; TC_539_552.Q_flow = TC_539_552.G * TC_539_552.dT; TC_539_552.dT = TC_539_552.port_a.T - TC_539_552.port_b.T; TC_539_552.port_a.Q_flow = TC_539_552.Q_flow; TC_539_552.port_b.Q_flow = -TC_539_552.Q_flow; TC_540_541.Q_flow = TC_540_541.G * TC_540_541.dT; TC_540_541.dT = TC_540_541.port_a.T - TC_540_541.port_b.T; TC_540_541.port_a.Q_flow = TC_540_541.Q_flow; TC_540_541.port_b.Q_flow = -TC_540_541.Q_flow; TC_540_553.Q_flow = TC_540_553.G * TC_540_553.dT; TC_540_553.dT = TC_540_553.port_a.T - TC_540_553.port_b.T; TC_540_553.port_a.Q_flow = TC_540_553.Q_flow; TC_540_553.port_b.Q_flow = -TC_540_553.Q_flow; TC_541_542.Q_flow = TC_541_542.G * TC_541_542.dT; TC_541_542.dT = TC_541_542.port_a.T - TC_541_542.port_b.T; TC_541_542.port_a.Q_flow = TC_541_542.Q_flow; TC_541_542.port_b.Q_flow = -TC_541_542.Q_flow; TC_541_554.Q_flow = TC_541_554.G * TC_541_554.dT; TC_541_554.dT = TC_541_554.port_a.T - TC_541_554.port_b.T; TC_541_554.port_a.Q_flow = TC_541_554.Q_flow; TC_541_554.port_b.Q_flow = -TC_541_554.Q_flow; TC_542_543.Q_flow = TC_542_543.G * TC_542_543.dT; TC_542_543.dT = TC_542_543.port_a.T - TC_542_543.port_b.T; TC_542_543.port_a.Q_flow = TC_542_543.Q_flow; TC_542_543.port_b.Q_flow = -TC_542_543.Q_flow; TC_542_555.Q_flow = TC_542_555.G * TC_542_555.dT; TC_542_555.dT = TC_542_555.port_a.T - TC_542_555.port_b.T; TC_542_555.port_a.Q_flow = TC_542_555.Q_flow; TC_542_555.port_b.Q_flow = -TC_542_555.Q_flow; TC_543_544.Q_flow = TC_543_544.G * TC_543_544.dT; TC_543_544.dT = TC_543_544.port_a.T - TC_543_544.port_b.T; TC_543_544.port_a.Q_flow = TC_543_544.Q_flow; TC_543_544.port_b.Q_flow = -TC_543_544.Q_flow; TC_543_556.Q_flow = TC_543_556.G * TC_543_556.dT; TC_543_556.dT = TC_543_556.port_a.T - TC_543_556.port_b.T; TC_543_556.port_a.Q_flow = TC_543_556.Q_flow; TC_543_556.port_b.Q_flow = -TC_543_556.Q_flow; TC_544_545.Q_flow = TC_544_545.G * TC_544_545.dT; TC_544_545.dT = TC_544_545.port_a.T - TC_544_545.port_b.T; TC_544_545.port_a.Q_flow = TC_544_545.Q_flow; TC_544_545.port_b.Q_flow = -TC_544_545.Q_flow; TC_544_557.Q_flow = TC_544_557.G * TC_544_557.dT; TC_544_557.dT = TC_544_557.port_a.T - TC_544_557.port_b.T; TC_544_557.port_a.Q_flow = TC_544_557.Q_flow; TC_544_557.port_b.Q_flow = -TC_544_557.Q_flow; TC_545_558.Q_flow = TC_545_558.G * TC_545_558.dT; TC_545_558.dT = TC_545_558.port_a.T - TC_545_558.port_b.T; TC_545_558.port_a.Q_flow = TC_545_558.Q_flow; TC_545_558.port_b.Q_flow = -TC_545_558.Q_flow; TC_546_547.Q_flow = TC_546_547.G * TC_546_547.dT; TC_546_547.dT = TC_546_547.port_a.T - TC_546_547.port_b.T; TC_546_547.port_a.Q_flow = TC_546_547.Q_flow; TC_546_547.port_b.Q_flow = -TC_546_547.Q_flow; TC_546_559.Q_flow = TC_546_559.G * TC_546_559.dT; TC_546_559.dT = TC_546_559.port_a.T - TC_546_559.port_b.T; TC_546_559.port_a.Q_flow = TC_546_559.Q_flow; TC_546_559.port_b.Q_flow = -TC_546_559.Q_flow; TC_547_548.Q_flow = TC_547_548.G * TC_547_548.dT; TC_547_548.dT = TC_547_548.port_a.T - TC_547_548.port_b.T; TC_547_548.port_a.Q_flow = TC_547_548.Q_flow; TC_547_548.port_b.Q_flow = -TC_547_548.Q_flow; TC_547_560.Q_flow = TC_547_560.G * TC_547_560.dT; TC_547_560.dT = TC_547_560.port_a.T - TC_547_560.port_b.T; TC_547_560.port_a.Q_flow = TC_547_560.Q_flow; TC_547_560.port_b.Q_flow = -TC_547_560.Q_flow; TC_547_920.Q_flow = TC_547_920.G * TC_547_920.dT; TC_547_920.dT = TC_547_920.port_a.T - TC_547_920.port_b.T; TC_547_920.port_a.Q_flow = TC_547_920.Q_flow; TC_547_920.port_b.Q_flow = -TC_547_920.Q_flow; TC_548_549.Q_flow = TC_548_549.G * TC_548_549.dT; TC_548_549.dT = TC_548_549.port_a.T - TC_548_549.port_b.T; TC_548_549.port_a.Q_flow = TC_548_549.Q_flow; TC_548_549.port_b.Q_flow = -TC_548_549.Q_flow; TC_548_561.Q_flow = TC_548_561.G * TC_548_561.dT; TC_548_561.dT = TC_548_561.port_a.T - TC_548_561.port_b.T; TC_548_561.port_a.Q_flow = TC_548_561.Q_flow; TC_548_561.port_b.Q_flow = -TC_548_561.Q_flow; TC_548_921.Q_flow = TC_548_921.G * TC_548_921.dT; TC_548_921.dT = TC_548_921.port_a.T - TC_548_921.port_b.T; TC_548_921.port_a.Q_flow = TC_548_921.Q_flow; TC_548_921.port_b.Q_flow = -TC_548_921.Q_flow; TC_549_550.Q_flow = TC_549_550.G * TC_549_550.dT; TC_549_550.dT = TC_549_550.port_a.T - TC_549_550.port_b.T; TC_549_550.port_a.Q_flow = TC_549_550.Q_flow; TC_549_550.port_b.Q_flow = -TC_549_550.Q_flow; TC_549_562.Q_flow = TC_549_562.G * TC_549_562.dT; TC_549_562.dT = TC_549_562.port_a.T - TC_549_562.port_b.T; TC_549_562.port_a.Q_flow = TC_549_562.Q_flow; TC_549_562.port_b.Q_flow = -TC_549_562.Q_flow; TC_549_922.Q_flow = TC_549_922.G * TC_549_922.dT; TC_549_922.dT = TC_549_922.port_a.T - TC_549_922.port_b.T; TC_549_922.port_a.Q_flow = TC_549_922.Q_flow; TC_549_922.port_b.Q_flow = -TC_549_922.Q_flow; TC_550_551.Q_flow = TC_550_551.G * TC_550_551.dT; TC_550_551.dT = TC_550_551.port_a.T - TC_550_551.port_b.T; TC_550_551.port_a.Q_flow = TC_550_551.Q_flow; TC_550_551.port_b.Q_flow = -TC_550_551.Q_flow; TC_550_563.Q_flow = TC_550_563.G * TC_550_563.dT; TC_550_563.dT = TC_550_563.port_a.T - TC_550_563.port_b.T; TC_550_563.port_a.Q_flow = TC_550_563.Q_flow; TC_550_563.port_b.Q_flow = -TC_550_563.Q_flow; TC_550_923.Q_flow = TC_550_923.G * TC_550_923.dT; TC_550_923.dT = TC_550_923.port_a.T - TC_550_923.port_b.T; TC_550_923.port_a.Q_flow = TC_550_923.Q_flow; TC_550_923.port_b.Q_flow = -TC_550_923.Q_flow; TC_551_552.Q_flow = TC_551_552.G * TC_551_552.dT; TC_551_552.dT = TC_551_552.port_a.T - TC_551_552.port_b.T; TC_551_552.port_a.Q_flow = TC_551_552.Q_flow; TC_551_552.port_b.Q_flow = -TC_551_552.Q_flow; TC_551_564.Q_flow = TC_551_564.G * TC_551_564.dT; TC_551_564.dT = TC_551_564.port_a.T - TC_551_564.port_b.T; TC_551_564.port_a.Q_flow = TC_551_564.Q_flow; TC_551_564.port_b.Q_flow = -TC_551_564.Q_flow; TC_551_924.Q_flow = TC_551_924.G * TC_551_924.dT; TC_551_924.dT = TC_551_924.port_a.T - TC_551_924.port_b.T; TC_551_924.port_a.Q_flow = TC_551_924.Q_flow; TC_551_924.port_b.Q_flow = -TC_551_924.Q_flow; TC_552_553.Q_flow = TC_552_553.G * TC_552_553.dT; TC_552_553.dT = TC_552_553.port_a.T - TC_552_553.port_b.T; TC_552_553.port_a.Q_flow = TC_552_553.Q_flow; TC_552_553.port_b.Q_flow = -TC_552_553.Q_flow; TC_552_565.Q_flow = TC_552_565.G * TC_552_565.dT; TC_552_565.dT = TC_552_565.port_a.T - TC_552_565.port_b.T; TC_552_565.port_a.Q_flow = TC_552_565.Q_flow; TC_552_565.port_b.Q_flow = -TC_552_565.Q_flow; TC_552_925.Q_flow = TC_552_925.G * TC_552_925.dT; TC_552_925.dT = TC_552_925.port_a.T - TC_552_925.port_b.T; TC_552_925.port_a.Q_flow = TC_552_925.Q_flow; TC_552_925.port_b.Q_flow = -TC_552_925.Q_flow; TC_553_554.Q_flow = TC_553_554.G * TC_553_554.dT; TC_553_554.dT = TC_553_554.port_a.T - TC_553_554.port_b.T; TC_553_554.port_a.Q_flow = TC_553_554.Q_flow; TC_553_554.port_b.Q_flow = -TC_553_554.Q_flow; TC_553_566.Q_flow = TC_553_566.G * TC_553_566.dT; TC_553_566.dT = TC_553_566.port_a.T - TC_553_566.port_b.T; TC_553_566.port_a.Q_flow = TC_553_566.Q_flow; TC_553_566.port_b.Q_flow = -TC_553_566.Q_flow; TC_553_926.Q_flow = TC_553_926.G * TC_553_926.dT; TC_553_926.dT = TC_553_926.port_a.T - TC_553_926.port_b.T; TC_553_926.port_a.Q_flow = TC_553_926.Q_flow; TC_553_926.port_b.Q_flow = -TC_553_926.Q_flow; TC_554_555.Q_flow = TC_554_555.G * TC_554_555.dT; TC_554_555.dT = TC_554_555.port_a.T - TC_554_555.port_b.T; TC_554_555.port_a.Q_flow = TC_554_555.Q_flow; TC_554_555.port_b.Q_flow = -TC_554_555.Q_flow; TC_554_567.Q_flow = TC_554_567.G * TC_554_567.dT; TC_554_567.dT = TC_554_567.port_a.T - TC_554_567.port_b.T; TC_554_567.port_a.Q_flow = TC_554_567.Q_flow; TC_554_567.port_b.Q_flow = -TC_554_567.Q_flow; TC_554_927.Q_flow = TC_554_927.G * TC_554_927.dT; TC_554_927.dT = TC_554_927.port_a.T - TC_554_927.port_b.T; TC_554_927.port_a.Q_flow = TC_554_927.Q_flow; TC_554_927.port_b.Q_flow = -TC_554_927.Q_flow; TC_555_556.Q_flow = TC_555_556.G * TC_555_556.dT; TC_555_556.dT = TC_555_556.port_a.T - TC_555_556.port_b.T; TC_555_556.port_a.Q_flow = TC_555_556.Q_flow; TC_555_556.port_b.Q_flow = -TC_555_556.Q_flow; TC_555_568.Q_flow = TC_555_568.G * TC_555_568.dT; TC_555_568.dT = TC_555_568.port_a.T - TC_555_568.port_b.T; TC_555_568.port_a.Q_flow = TC_555_568.Q_flow; TC_555_568.port_b.Q_flow = -TC_555_568.Q_flow; TC_555_928.Q_flow = TC_555_928.G * TC_555_928.dT; TC_555_928.dT = TC_555_928.port_a.T - TC_555_928.port_b.T; TC_555_928.port_a.Q_flow = TC_555_928.Q_flow; TC_555_928.port_b.Q_flow = -TC_555_928.Q_flow; TC_556_557.Q_flow = TC_556_557.G * TC_556_557.dT; TC_556_557.dT = TC_556_557.port_a.T - TC_556_557.port_b.T; TC_556_557.port_a.Q_flow = TC_556_557.Q_flow; TC_556_557.port_b.Q_flow = -TC_556_557.Q_flow; TC_556_569.Q_flow = TC_556_569.G * TC_556_569.dT; TC_556_569.dT = TC_556_569.port_a.T - TC_556_569.port_b.T; TC_556_569.port_a.Q_flow = TC_556_569.Q_flow; TC_556_569.port_b.Q_flow = -TC_556_569.Q_flow; TC_556_929.Q_flow = TC_556_929.G * TC_556_929.dT; TC_556_929.dT = TC_556_929.port_a.T - TC_556_929.port_b.T; TC_556_929.port_a.Q_flow = TC_556_929.Q_flow; TC_556_929.port_b.Q_flow = -TC_556_929.Q_flow; TC_557_558.Q_flow = TC_557_558.G * TC_557_558.dT; TC_557_558.dT = TC_557_558.port_a.T - TC_557_558.port_b.T; TC_557_558.port_a.Q_flow = TC_557_558.Q_flow; TC_557_558.port_b.Q_flow = -TC_557_558.Q_flow; TC_557_570.Q_flow = TC_557_570.G * TC_557_570.dT; TC_557_570.dT = TC_557_570.port_a.T - TC_557_570.port_b.T; TC_557_570.port_a.Q_flow = TC_557_570.Q_flow; TC_557_570.port_b.Q_flow = -TC_557_570.Q_flow; TC_557_930.Q_flow = TC_557_930.G * TC_557_930.dT; TC_557_930.dT = TC_557_930.port_a.T - TC_557_930.port_b.T; TC_557_930.port_a.Q_flow = TC_557_930.Q_flow; TC_557_930.port_b.Q_flow = -TC_557_930.Q_flow; TC_558_571.Q_flow = TC_558_571.G * TC_558_571.dT; TC_558_571.dT = TC_558_571.port_a.T - TC_558_571.port_b.T; TC_558_571.port_a.Q_flow = TC_558_571.Q_flow; TC_558_571.port_b.Q_flow = -TC_558_571.Q_flow; TC_559_560.Q_flow = TC_559_560.G * TC_559_560.dT; TC_559_560.dT = TC_559_560.port_a.T - TC_559_560.port_b.T; TC_559_560.port_a.Q_flow = TC_559_560.Q_flow; TC_559_560.port_b.Q_flow = -TC_559_560.Q_flow; TC_559_572.Q_flow = TC_559_572.G * TC_559_572.dT; TC_559_572.dT = TC_559_572.port_a.T - TC_559_572.port_b.T; TC_559_572.port_a.Q_flow = TC_559_572.Q_flow; TC_559_572.port_b.Q_flow = -TC_559_572.Q_flow; TC_560_561.Q_flow = TC_560_561.G * TC_560_561.dT; TC_560_561.dT = TC_560_561.port_a.T - TC_560_561.port_b.T; TC_560_561.port_a.Q_flow = TC_560_561.Q_flow; TC_560_561.port_b.Q_flow = -TC_560_561.Q_flow; TC_560_573.Q_flow = TC_560_573.G * TC_560_573.dT; TC_560_573.dT = TC_560_573.port_a.T - TC_560_573.port_b.T; TC_560_573.port_a.Q_flow = TC_560_573.Q_flow; TC_560_573.port_b.Q_flow = -TC_560_573.Q_flow; TC_560_931.Q_flow = TC_560_931.G * TC_560_931.dT; TC_560_931.dT = TC_560_931.port_a.T - TC_560_931.port_b.T; TC_560_931.port_a.Q_flow = TC_560_931.Q_flow; TC_560_931.port_b.Q_flow = -TC_560_931.Q_flow; TC_561_562.Q_flow = TC_561_562.G * TC_561_562.dT; TC_561_562.dT = TC_561_562.port_a.T - TC_561_562.port_b.T; TC_561_562.port_a.Q_flow = TC_561_562.Q_flow; TC_561_562.port_b.Q_flow = -TC_561_562.Q_flow; TC_561_574.Q_flow = TC_561_574.G * TC_561_574.dT; TC_561_574.dT = TC_561_574.port_a.T - TC_561_574.port_b.T; TC_561_574.port_a.Q_flow = TC_561_574.Q_flow; TC_561_574.port_b.Q_flow = -TC_561_574.Q_flow; TC_561_932.Q_flow = TC_561_932.G * TC_561_932.dT; TC_561_932.dT = TC_561_932.port_a.T - TC_561_932.port_b.T; TC_561_932.port_a.Q_flow = TC_561_932.Q_flow; TC_561_932.port_b.Q_flow = -TC_561_932.Q_flow; TC_562_563.Q_flow = TC_562_563.G * TC_562_563.dT; TC_562_563.dT = TC_562_563.port_a.T - TC_562_563.port_b.T; TC_562_563.port_a.Q_flow = TC_562_563.Q_flow; TC_562_563.port_b.Q_flow = -TC_562_563.Q_flow; TC_562_575.Q_flow = TC_562_575.G * TC_562_575.dT; TC_562_575.dT = TC_562_575.port_a.T - TC_562_575.port_b.T; TC_562_575.port_a.Q_flow = TC_562_575.Q_flow; TC_562_575.port_b.Q_flow = -TC_562_575.Q_flow; TC_562_933.Q_flow = TC_562_933.G * TC_562_933.dT; TC_562_933.dT = TC_562_933.port_a.T - TC_562_933.port_b.T; TC_562_933.port_a.Q_flow = TC_562_933.Q_flow; TC_562_933.port_b.Q_flow = -TC_562_933.Q_flow; TC_563_564.Q_flow = TC_563_564.G * TC_563_564.dT; TC_563_564.dT = TC_563_564.port_a.T - TC_563_564.port_b.T; TC_563_564.port_a.Q_flow = TC_563_564.Q_flow; TC_563_564.port_b.Q_flow = -TC_563_564.Q_flow; TC_563_576.Q_flow = TC_563_576.G * TC_563_576.dT; TC_563_576.dT = TC_563_576.port_a.T - TC_563_576.port_b.T; TC_563_576.port_a.Q_flow = TC_563_576.Q_flow; TC_563_576.port_b.Q_flow = -TC_563_576.Q_flow; TC_563_934.Q_flow = TC_563_934.G * TC_563_934.dT; TC_563_934.dT = TC_563_934.port_a.T - TC_563_934.port_b.T; TC_563_934.port_a.Q_flow = TC_563_934.Q_flow; TC_563_934.port_b.Q_flow = -TC_563_934.Q_flow; TC_564_565.Q_flow = TC_564_565.G * TC_564_565.dT; TC_564_565.dT = TC_564_565.port_a.T - TC_564_565.port_b.T; TC_564_565.port_a.Q_flow = TC_564_565.Q_flow; TC_564_565.port_b.Q_flow = -TC_564_565.Q_flow; TC_564_577.Q_flow = TC_564_577.G * TC_564_577.dT; TC_564_577.dT = TC_564_577.port_a.T - TC_564_577.port_b.T; TC_564_577.port_a.Q_flow = TC_564_577.Q_flow; TC_564_577.port_b.Q_flow = -TC_564_577.Q_flow; TC_564_935.Q_flow = TC_564_935.G * TC_564_935.dT; TC_564_935.dT = TC_564_935.port_a.T - TC_564_935.port_b.T; TC_564_935.port_a.Q_flow = TC_564_935.Q_flow; TC_564_935.port_b.Q_flow = -TC_564_935.Q_flow; TC_565_566.Q_flow = TC_565_566.G * TC_565_566.dT; TC_565_566.dT = TC_565_566.port_a.T - TC_565_566.port_b.T; TC_565_566.port_a.Q_flow = TC_565_566.Q_flow; TC_565_566.port_b.Q_flow = -TC_565_566.Q_flow; TC_565_578.Q_flow = TC_565_578.G * TC_565_578.dT; TC_565_578.dT = TC_565_578.port_a.T - TC_565_578.port_b.T; TC_565_578.port_a.Q_flow = TC_565_578.Q_flow; TC_565_578.port_b.Q_flow = -TC_565_578.Q_flow; TC_565_936.Q_flow = TC_565_936.G * TC_565_936.dT; TC_565_936.dT = TC_565_936.port_a.T - TC_565_936.port_b.T; TC_565_936.port_a.Q_flow = TC_565_936.Q_flow; TC_565_936.port_b.Q_flow = -TC_565_936.Q_flow; TC_566_567.Q_flow = TC_566_567.G * TC_566_567.dT; TC_566_567.dT = TC_566_567.port_a.T - TC_566_567.port_b.T; TC_566_567.port_a.Q_flow = TC_566_567.Q_flow; TC_566_567.port_b.Q_flow = -TC_566_567.Q_flow; TC_566_579.Q_flow = TC_566_579.G * TC_566_579.dT; TC_566_579.dT = TC_566_579.port_a.T - TC_566_579.port_b.T; TC_566_579.port_a.Q_flow = TC_566_579.Q_flow; TC_566_579.port_b.Q_flow = -TC_566_579.Q_flow; TC_566_937.Q_flow = TC_566_937.G * TC_566_937.dT; TC_566_937.dT = TC_566_937.port_a.T - TC_566_937.port_b.T; TC_566_937.port_a.Q_flow = TC_566_937.Q_flow; TC_566_937.port_b.Q_flow = -TC_566_937.Q_flow; TC_567_568.Q_flow = TC_567_568.G * TC_567_568.dT; TC_567_568.dT = TC_567_568.port_a.T - TC_567_568.port_b.T; TC_567_568.port_a.Q_flow = TC_567_568.Q_flow; TC_567_568.port_b.Q_flow = -TC_567_568.Q_flow; TC_567_580.Q_flow = TC_567_580.G * TC_567_580.dT; TC_567_580.dT = TC_567_580.port_a.T - TC_567_580.port_b.T; TC_567_580.port_a.Q_flow = TC_567_580.Q_flow; TC_567_580.port_b.Q_flow = -TC_567_580.Q_flow; TC_567_938.Q_flow = TC_567_938.G * TC_567_938.dT; TC_567_938.dT = TC_567_938.port_a.T - TC_567_938.port_b.T; TC_567_938.port_a.Q_flow = TC_567_938.Q_flow; TC_567_938.port_b.Q_flow = -TC_567_938.Q_flow; TC_568_569.Q_flow = TC_568_569.G * TC_568_569.dT; TC_568_569.dT = TC_568_569.port_a.T - TC_568_569.port_b.T; TC_568_569.port_a.Q_flow = TC_568_569.Q_flow; TC_568_569.port_b.Q_flow = -TC_568_569.Q_flow; TC_568_581.Q_flow = TC_568_581.G * TC_568_581.dT; TC_568_581.dT = TC_568_581.port_a.T - TC_568_581.port_b.T; TC_568_581.port_a.Q_flow = TC_568_581.Q_flow; TC_568_581.port_b.Q_flow = -TC_568_581.Q_flow; TC_568_939.Q_flow = TC_568_939.G * TC_568_939.dT; TC_568_939.dT = TC_568_939.port_a.T - TC_568_939.port_b.T; TC_568_939.port_a.Q_flow = TC_568_939.Q_flow; TC_568_939.port_b.Q_flow = -TC_568_939.Q_flow; TC_569_570.Q_flow = TC_569_570.G * TC_569_570.dT; TC_569_570.dT = TC_569_570.port_a.T - TC_569_570.port_b.T; TC_569_570.port_a.Q_flow = TC_569_570.Q_flow; TC_569_570.port_b.Q_flow = -TC_569_570.Q_flow; TC_569_582.Q_flow = TC_569_582.G * TC_569_582.dT; TC_569_582.dT = TC_569_582.port_a.T - TC_569_582.port_b.T; TC_569_582.port_a.Q_flow = TC_569_582.Q_flow; TC_569_582.port_b.Q_flow = -TC_569_582.Q_flow; TC_569_940.Q_flow = TC_569_940.G * TC_569_940.dT; TC_569_940.dT = TC_569_940.port_a.T - TC_569_940.port_b.T; TC_569_940.port_a.Q_flow = TC_569_940.Q_flow; TC_569_940.port_b.Q_flow = -TC_569_940.Q_flow; TC_570_571.Q_flow = TC_570_571.G * TC_570_571.dT; TC_570_571.dT = TC_570_571.port_a.T - TC_570_571.port_b.T; TC_570_571.port_a.Q_flow = TC_570_571.Q_flow; TC_570_571.port_b.Q_flow = -TC_570_571.Q_flow; TC_570_583.Q_flow = TC_570_583.G * TC_570_583.dT; TC_570_583.dT = TC_570_583.port_a.T - TC_570_583.port_b.T; TC_570_583.port_a.Q_flow = TC_570_583.Q_flow; TC_570_583.port_b.Q_flow = -TC_570_583.Q_flow; TC_570_941.Q_flow = TC_570_941.G * TC_570_941.dT; TC_570_941.dT = TC_570_941.port_a.T - TC_570_941.port_b.T; TC_570_941.port_a.Q_flow = TC_570_941.Q_flow; TC_570_941.port_b.Q_flow = -TC_570_941.Q_flow; TC_571_584.Q_flow = TC_571_584.G * TC_571_584.dT; TC_571_584.dT = TC_571_584.port_a.T - TC_571_584.port_b.T; TC_571_584.port_a.Q_flow = TC_571_584.Q_flow; TC_571_584.port_b.Q_flow = -TC_571_584.Q_flow; TC_572_573.Q_flow = TC_572_573.G * TC_572_573.dT; TC_572_573.dT = TC_572_573.port_a.T - TC_572_573.port_b.T; TC_572_573.port_a.Q_flow = TC_572_573.Q_flow; TC_572_573.port_b.Q_flow = -TC_572_573.Q_flow; TC_572_585.Q_flow = TC_572_585.G * TC_572_585.dT; TC_572_585.dT = TC_572_585.port_a.T - TC_572_585.port_b.T; TC_572_585.port_a.Q_flow = TC_572_585.Q_flow; TC_572_585.port_b.Q_flow = -TC_572_585.Q_flow; TC_573_574.Q_flow = TC_573_574.G * TC_573_574.dT; TC_573_574.dT = TC_573_574.port_a.T - TC_573_574.port_b.T; TC_573_574.port_a.Q_flow = TC_573_574.Q_flow; TC_573_574.port_b.Q_flow = -TC_573_574.Q_flow; TC_573_586.Q_flow = TC_573_586.G * TC_573_586.dT; TC_573_586.dT = TC_573_586.port_a.T - TC_573_586.port_b.T; TC_573_586.port_a.Q_flow = TC_573_586.Q_flow; TC_573_586.port_b.Q_flow = -TC_573_586.Q_flow; TC_573_942.Q_flow = TC_573_942.G * TC_573_942.dT; TC_573_942.dT = TC_573_942.port_a.T - TC_573_942.port_b.T; TC_573_942.port_a.Q_flow = TC_573_942.Q_flow; TC_573_942.port_b.Q_flow = -TC_573_942.Q_flow; TC_574_575.Q_flow = TC_574_575.G * TC_574_575.dT; TC_574_575.dT = TC_574_575.port_a.T - TC_574_575.port_b.T; TC_574_575.port_a.Q_flow = TC_574_575.Q_flow; TC_574_575.port_b.Q_flow = -TC_574_575.Q_flow; TC_574_587.Q_flow = TC_574_587.G * TC_574_587.dT; TC_574_587.dT = TC_574_587.port_a.T - TC_574_587.port_b.T; TC_574_587.port_a.Q_flow = TC_574_587.Q_flow; TC_574_587.port_b.Q_flow = -TC_574_587.Q_flow; TC_574_943.Q_flow = TC_574_943.G * TC_574_943.dT; TC_574_943.dT = TC_574_943.port_a.T - TC_574_943.port_b.T; TC_574_943.port_a.Q_flow = TC_574_943.Q_flow; TC_574_943.port_b.Q_flow = -TC_574_943.Q_flow; TC_575_576.Q_flow = TC_575_576.G * TC_575_576.dT; TC_575_576.dT = TC_575_576.port_a.T - TC_575_576.port_b.T; TC_575_576.port_a.Q_flow = TC_575_576.Q_flow; TC_575_576.port_b.Q_flow = -TC_575_576.Q_flow; TC_575_588.Q_flow = TC_575_588.G * TC_575_588.dT; TC_575_588.dT = TC_575_588.port_a.T - TC_575_588.port_b.T; TC_575_588.port_a.Q_flow = TC_575_588.Q_flow; TC_575_588.port_b.Q_flow = -TC_575_588.Q_flow; TC_575_944.Q_flow = TC_575_944.G * TC_575_944.dT; TC_575_944.dT = TC_575_944.port_a.T - TC_575_944.port_b.T; TC_575_944.port_a.Q_flow = TC_575_944.Q_flow; TC_575_944.port_b.Q_flow = -TC_575_944.Q_flow; TC_576_577.Q_flow = TC_576_577.G * TC_576_577.dT; TC_576_577.dT = TC_576_577.port_a.T - TC_576_577.port_b.T; TC_576_577.port_a.Q_flow = TC_576_577.Q_flow; TC_576_577.port_b.Q_flow = -TC_576_577.Q_flow; TC_576_589.Q_flow = TC_576_589.G * TC_576_589.dT; TC_576_589.dT = TC_576_589.port_a.T - TC_576_589.port_b.T; TC_576_589.port_a.Q_flow = TC_576_589.Q_flow; TC_576_589.port_b.Q_flow = -TC_576_589.Q_flow; TC_576_945.Q_flow = TC_576_945.G * TC_576_945.dT; TC_576_945.dT = TC_576_945.port_a.T - TC_576_945.port_b.T; TC_576_945.port_a.Q_flow = TC_576_945.Q_flow; TC_576_945.port_b.Q_flow = -TC_576_945.Q_flow; TC_577_578.Q_flow = TC_577_578.G * TC_577_578.dT; TC_577_578.dT = TC_577_578.port_a.T - TC_577_578.port_b.T; TC_577_578.port_a.Q_flow = TC_577_578.Q_flow; TC_577_578.port_b.Q_flow = -TC_577_578.Q_flow; TC_577_590.Q_flow = TC_577_590.G * TC_577_590.dT; TC_577_590.dT = TC_577_590.port_a.T - TC_577_590.port_b.T; TC_577_590.port_a.Q_flow = TC_577_590.Q_flow; TC_577_590.port_b.Q_flow = -TC_577_590.Q_flow; TC_577_946.Q_flow = TC_577_946.G * TC_577_946.dT; TC_577_946.dT = TC_577_946.port_a.T - TC_577_946.port_b.T; TC_577_946.port_a.Q_flow = TC_577_946.Q_flow; TC_577_946.port_b.Q_flow = -TC_577_946.Q_flow; TC_578_579.Q_flow = TC_578_579.G * TC_578_579.dT; TC_578_579.dT = TC_578_579.port_a.T - TC_578_579.port_b.T; TC_578_579.port_a.Q_flow = TC_578_579.Q_flow; TC_578_579.port_b.Q_flow = -TC_578_579.Q_flow; TC_578_591.Q_flow = TC_578_591.G * TC_578_591.dT; TC_578_591.dT = TC_578_591.port_a.T - TC_578_591.port_b.T; TC_578_591.port_a.Q_flow = TC_578_591.Q_flow; TC_578_591.port_b.Q_flow = -TC_578_591.Q_flow; TC_578_947.Q_flow = TC_578_947.G * TC_578_947.dT; TC_578_947.dT = TC_578_947.port_a.T - TC_578_947.port_b.T; TC_578_947.port_a.Q_flow = TC_578_947.Q_flow; TC_578_947.port_b.Q_flow = -TC_578_947.Q_flow; TC_579_580.Q_flow = TC_579_580.G * TC_579_580.dT; TC_579_580.dT = TC_579_580.port_a.T - TC_579_580.port_b.T; TC_579_580.port_a.Q_flow = TC_579_580.Q_flow; TC_579_580.port_b.Q_flow = -TC_579_580.Q_flow; TC_579_592.Q_flow = TC_579_592.G * TC_579_592.dT; TC_579_592.dT = TC_579_592.port_a.T - TC_579_592.port_b.T; TC_579_592.port_a.Q_flow = TC_579_592.Q_flow; TC_579_592.port_b.Q_flow = -TC_579_592.Q_flow; TC_579_948.Q_flow = TC_579_948.G * TC_579_948.dT; TC_579_948.dT = TC_579_948.port_a.T - TC_579_948.port_b.T; TC_579_948.port_a.Q_flow = TC_579_948.Q_flow; TC_579_948.port_b.Q_flow = -TC_579_948.Q_flow; TC_580_581.Q_flow = TC_580_581.G * TC_580_581.dT; TC_580_581.dT = TC_580_581.port_a.T - TC_580_581.port_b.T; TC_580_581.port_a.Q_flow = TC_580_581.Q_flow; TC_580_581.port_b.Q_flow = -TC_580_581.Q_flow; TC_580_593.Q_flow = TC_580_593.G * TC_580_593.dT; TC_580_593.dT = TC_580_593.port_a.T - TC_580_593.port_b.T; TC_580_593.port_a.Q_flow = TC_580_593.Q_flow; TC_580_593.port_b.Q_flow = -TC_580_593.Q_flow; TC_580_949.Q_flow = TC_580_949.G * TC_580_949.dT; TC_580_949.dT = TC_580_949.port_a.T - TC_580_949.port_b.T; TC_580_949.port_a.Q_flow = TC_580_949.Q_flow; TC_580_949.port_b.Q_flow = -TC_580_949.Q_flow; TC_581_582.Q_flow = TC_581_582.G * TC_581_582.dT; TC_581_582.dT = TC_581_582.port_a.T - TC_581_582.port_b.T; TC_581_582.port_a.Q_flow = TC_581_582.Q_flow; TC_581_582.port_b.Q_flow = -TC_581_582.Q_flow; TC_581_594.Q_flow = TC_581_594.G * TC_581_594.dT; TC_581_594.dT = TC_581_594.port_a.T - TC_581_594.port_b.T; TC_581_594.port_a.Q_flow = TC_581_594.Q_flow; TC_581_594.port_b.Q_flow = -TC_581_594.Q_flow; TC_581_950.Q_flow = TC_581_950.G * TC_581_950.dT; TC_581_950.dT = TC_581_950.port_a.T - TC_581_950.port_b.T; TC_581_950.port_a.Q_flow = TC_581_950.Q_flow; TC_581_950.port_b.Q_flow = -TC_581_950.Q_flow; TC_582_583.Q_flow = TC_582_583.G * TC_582_583.dT; TC_582_583.dT = TC_582_583.port_a.T - TC_582_583.port_b.T; TC_582_583.port_a.Q_flow = TC_582_583.Q_flow; TC_582_583.port_b.Q_flow = -TC_582_583.Q_flow; TC_582_595.Q_flow = TC_582_595.G * TC_582_595.dT; TC_582_595.dT = TC_582_595.port_a.T - TC_582_595.port_b.T; TC_582_595.port_a.Q_flow = TC_582_595.Q_flow; TC_582_595.port_b.Q_flow = -TC_582_595.Q_flow; TC_582_951.Q_flow = TC_582_951.G * TC_582_951.dT; TC_582_951.dT = TC_582_951.port_a.T - TC_582_951.port_b.T; TC_582_951.port_a.Q_flow = TC_582_951.Q_flow; TC_582_951.port_b.Q_flow = -TC_582_951.Q_flow; TC_583_584.Q_flow = TC_583_584.G * TC_583_584.dT; TC_583_584.dT = TC_583_584.port_a.T - TC_583_584.port_b.T; TC_583_584.port_a.Q_flow = TC_583_584.Q_flow; TC_583_584.port_b.Q_flow = -TC_583_584.Q_flow; TC_583_596.Q_flow = TC_583_596.G * TC_583_596.dT; TC_583_596.dT = TC_583_596.port_a.T - TC_583_596.port_b.T; TC_583_596.port_a.Q_flow = TC_583_596.Q_flow; TC_583_596.port_b.Q_flow = -TC_583_596.Q_flow; TC_583_952.Q_flow = TC_583_952.G * TC_583_952.dT; TC_583_952.dT = TC_583_952.port_a.T - TC_583_952.port_b.T; TC_583_952.port_a.Q_flow = TC_583_952.Q_flow; TC_583_952.port_b.Q_flow = -TC_583_952.Q_flow; TC_584_597.Q_flow = TC_584_597.G * TC_584_597.dT; TC_584_597.dT = TC_584_597.port_a.T - TC_584_597.port_b.T; TC_584_597.port_a.Q_flow = TC_584_597.Q_flow; TC_584_597.port_b.Q_flow = -TC_584_597.Q_flow; TC_585_586.Q_flow = TC_585_586.G * TC_585_586.dT; TC_585_586.dT = TC_585_586.port_a.T - TC_585_586.port_b.T; TC_585_586.port_a.Q_flow = TC_585_586.Q_flow; TC_585_586.port_b.Q_flow = -TC_585_586.Q_flow; TC_585_598.Q_flow = TC_585_598.G * TC_585_598.dT; TC_585_598.dT = TC_585_598.port_a.T - TC_585_598.port_b.T; TC_585_598.port_a.Q_flow = TC_585_598.Q_flow; TC_585_598.port_b.Q_flow = -TC_585_598.Q_flow; TC_586_587.Q_flow = TC_586_587.G * TC_586_587.dT; TC_586_587.dT = TC_586_587.port_a.T - TC_586_587.port_b.T; TC_586_587.port_a.Q_flow = TC_586_587.Q_flow; TC_586_587.port_b.Q_flow = -TC_586_587.Q_flow; TC_586_599.Q_flow = TC_586_599.G * TC_586_599.dT; TC_586_599.dT = TC_586_599.port_a.T - TC_586_599.port_b.T; TC_586_599.port_a.Q_flow = TC_586_599.Q_flow; TC_586_599.port_b.Q_flow = -TC_586_599.Q_flow; TC_586_953.Q_flow = TC_586_953.G * TC_586_953.dT; TC_586_953.dT = TC_586_953.port_a.T - TC_586_953.port_b.T; TC_586_953.port_a.Q_flow = TC_586_953.Q_flow; TC_586_953.port_b.Q_flow = -TC_586_953.Q_flow; TC_587_588.Q_flow = TC_587_588.G * TC_587_588.dT; TC_587_588.dT = TC_587_588.port_a.T - TC_587_588.port_b.T; TC_587_588.port_a.Q_flow = TC_587_588.Q_flow; TC_587_588.port_b.Q_flow = -TC_587_588.Q_flow; TC_587_600.Q_flow = TC_587_600.G * TC_587_600.dT; TC_587_600.dT = TC_587_600.port_a.T - TC_587_600.port_b.T; TC_587_600.port_a.Q_flow = TC_587_600.Q_flow; TC_587_600.port_b.Q_flow = -TC_587_600.Q_flow; TC_587_954.Q_flow = TC_587_954.G * TC_587_954.dT; TC_587_954.dT = TC_587_954.port_a.T - TC_587_954.port_b.T; TC_587_954.port_a.Q_flow = TC_587_954.Q_flow; TC_587_954.port_b.Q_flow = -TC_587_954.Q_flow; TC_588_589.Q_flow = TC_588_589.G * TC_588_589.dT; TC_588_589.dT = TC_588_589.port_a.T - TC_588_589.port_b.T; TC_588_589.port_a.Q_flow = TC_588_589.Q_flow; TC_588_589.port_b.Q_flow = -TC_588_589.Q_flow; TC_588_601.Q_flow = TC_588_601.G * TC_588_601.dT; TC_588_601.dT = TC_588_601.port_a.T - TC_588_601.port_b.T; TC_588_601.port_a.Q_flow = TC_588_601.Q_flow; TC_588_601.port_b.Q_flow = -TC_588_601.Q_flow; TC_588_955.Q_flow = TC_588_955.G * TC_588_955.dT; TC_588_955.dT = TC_588_955.port_a.T - TC_588_955.port_b.T; TC_588_955.port_a.Q_flow = TC_588_955.Q_flow; TC_588_955.port_b.Q_flow = -TC_588_955.Q_flow; TC_589_590.Q_flow = TC_589_590.G * TC_589_590.dT; TC_589_590.dT = TC_589_590.port_a.T - TC_589_590.port_b.T; TC_589_590.port_a.Q_flow = TC_589_590.Q_flow; TC_589_590.port_b.Q_flow = -TC_589_590.Q_flow; TC_589_602.Q_flow = TC_589_602.G * TC_589_602.dT; TC_589_602.dT = TC_589_602.port_a.T - TC_589_602.port_b.T; TC_589_602.port_a.Q_flow = TC_589_602.Q_flow; TC_589_602.port_b.Q_flow = -TC_589_602.Q_flow; TC_589_956.Q_flow = TC_589_956.G * TC_589_956.dT; TC_589_956.dT = TC_589_956.port_a.T - TC_589_956.port_b.T; TC_589_956.port_a.Q_flow = TC_589_956.Q_flow; TC_589_956.port_b.Q_flow = -TC_589_956.Q_flow; TC_590_591.Q_flow = TC_590_591.G * TC_590_591.dT; TC_590_591.dT = TC_590_591.port_a.T - TC_590_591.port_b.T; TC_590_591.port_a.Q_flow = TC_590_591.Q_flow; TC_590_591.port_b.Q_flow = -TC_590_591.Q_flow; TC_590_603.Q_flow = TC_590_603.G * TC_590_603.dT; TC_590_603.dT = TC_590_603.port_a.T - TC_590_603.port_b.T; TC_590_603.port_a.Q_flow = TC_590_603.Q_flow; TC_590_603.port_b.Q_flow = -TC_590_603.Q_flow; TC_590_957.Q_flow = TC_590_957.G * TC_590_957.dT; TC_590_957.dT = TC_590_957.port_a.T - TC_590_957.port_b.T; TC_590_957.port_a.Q_flow = TC_590_957.Q_flow; TC_590_957.port_b.Q_flow = -TC_590_957.Q_flow; TC_591_592.Q_flow = TC_591_592.G * TC_591_592.dT; TC_591_592.dT = TC_591_592.port_a.T - TC_591_592.port_b.T; TC_591_592.port_a.Q_flow = TC_591_592.Q_flow; TC_591_592.port_b.Q_flow = -TC_591_592.Q_flow; TC_591_604.Q_flow = TC_591_604.G * TC_591_604.dT; TC_591_604.dT = TC_591_604.port_a.T - TC_591_604.port_b.T; TC_591_604.port_a.Q_flow = TC_591_604.Q_flow; TC_591_604.port_b.Q_flow = -TC_591_604.Q_flow; TC_591_958.Q_flow = TC_591_958.G * TC_591_958.dT; TC_591_958.dT = TC_591_958.port_a.T - TC_591_958.port_b.T; TC_591_958.port_a.Q_flow = TC_591_958.Q_flow; TC_591_958.port_b.Q_flow = -TC_591_958.Q_flow; TC_592_593.Q_flow = TC_592_593.G * TC_592_593.dT; TC_592_593.dT = TC_592_593.port_a.T - TC_592_593.port_b.T; TC_592_593.port_a.Q_flow = TC_592_593.Q_flow; TC_592_593.port_b.Q_flow = -TC_592_593.Q_flow; TC_592_605.Q_flow = TC_592_605.G * TC_592_605.dT; TC_592_605.dT = TC_592_605.port_a.T - TC_592_605.port_b.T; TC_592_605.port_a.Q_flow = TC_592_605.Q_flow; TC_592_605.port_b.Q_flow = -TC_592_605.Q_flow; TC_592_959.Q_flow = TC_592_959.G * TC_592_959.dT; TC_592_959.dT = TC_592_959.port_a.T - TC_592_959.port_b.T; TC_592_959.port_a.Q_flow = TC_592_959.Q_flow; TC_592_959.port_b.Q_flow = -TC_592_959.Q_flow; TC_593_594.Q_flow = TC_593_594.G * TC_593_594.dT; TC_593_594.dT = TC_593_594.port_a.T - TC_593_594.port_b.T; TC_593_594.port_a.Q_flow = TC_593_594.Q_flow; TC_593_594.port_b.Q_flow = -TC_593_594.Q_flow; TC_593_606.Q_flow = TC_593_606.G * TC_593_606.dT; TC_593_606.dT = TC_593_606.port_a.T - TC_593_606.port_b.T; TC_593_606.port_a.Q_flow = TC_593_606.Q_flow; TC_593_606.port_b.Q_flow = -TC_593_606.Q_flow; TC_593_960.Q_flow = TC_593_960.G * TC_593_960.dT; TC_593_960.dT = TC_593_960.port_a.T - TC_593_960.port_b.T; TC_593_960.port_a.Q_flow = TC_593_960.Q_flow; TC_593_960.port_b.Q_flow = -TC_593_960.Q_flow; TC_594_595.Q_flow = TC_594_595.G * TC_594_595.dT; TC_594_595.dT = TC_594_595.port_a.T - TC_594_595.port_b.T; TC_594_595.port_a.Q_flow = TC_594_595.Q_flow; TC_594_595.port_b.Q_flow = -TC_594_595.Q_flow; TC_594_607.Q_flow = TC_594_607.G * TC_594_607.dT; TC_594_607.dT = TC_594_607.port_a.T - TC_594_607.port_b.T; TC_594_607.port_a.Q_flow = TC_594_607.Q_flow; TC_594_607.port_b.Q_flow = -TC_594_607.Q_flow; TC_594_961.Q_flow = TC_594_961.G * TC_594_961.dT; TC_594_961.dT = TC_594_961.port_a.T - TC_594_961.port_b.T; TC_594_961.port_a.Q_flow = TC_594_961.Q_flow; TC_594_961.port_b.Q_flow = -TC_594_961.Q_flow; TC_595_596.Q_flow = TC_595_596.G * TC_595_596.dT; TC_595_596.dT = TC_595_596.port_a.T - TC_595_596.port_b.T; TC_595_596.port_a.Q_flow = TC_595_596.Q_flow; TC_595_596.port_b.Q_flow = -TC_595_596.Q_flow; TC_595_608.Q_flow = TC_595_608.G * TC_595_608.dT; TC_595_608.dT = TC_595_608.port_a.T - TC_595_608.port_b.T; TC_595_608.port_a.Q_flow = TC_595_608.Q_flow; TC_595_608.port_b.Q_flow = -TC_595_608.Q_flow; TC_595_962.Q_flow = TC_595_962.G * TC_595_962.dT; TC_595_962.dT = TC_595_962.port_a.T - TC_595_962.port_b.T; TC_595_962.port_a.Q_flow = TC_595_962.Q_flow; TC_595_962.port_b.Q_flow = -TC_595_962.Q_flow; TC_596_597.Q_flow = TC_596_597.G * TC_596_597.dT; TC_596_597.dT = TC_596_597.port_a.T - TC_596_597.port_b.T; TC_596_597.port_a.Q_flow = TC_596_597.Q_flow; TC_596_597.port_b.Q_flow = -TC_596_597.Q_flow; TC_596_609.Q_flow = TC_596_609.G * TC_596_609.dT; TC_596_609.dT = TC_596_609.port_a.T - TC_596_609.port_b.T; TC_596_609.port_a.Q_flow = TC_596_609.Q_flow; TC_596_609.port_b.Q_flow = -TC_596_609.Q_flow; TC_596_963.Q_flow = TC_596_963.G * TC_596_963.dT; TC_596_963.dT = TC_596_963.port_a.T - TC_596_963.port_b.T; TC_596_963.port_a.Q_flow = TC_596_963.Q_flow; TC_596_963.port_b.Q_flow = -TC_596_963.Q_flow; TC_597_610.Q_flow = TC_597_610.G * TC_597_610.dT; TC_597_610.dT = TC_597_610.port_a.T - TC_597_610.port_b.T; TC_597_610.port_a.Q_flow = TC_597_610.Q_flow; TC_597_610.port_b.Q_flow = -TC_597_610.Q_flow; TC_598_599.Q_flow = TC_598_599.G * TC_598_599.dT; TC_598_599.dT = TC_598_599.port_a.T - TC_598_599.port_b.T; TC_598_599.port_a.Q_flow = TC_598_599.Q_flow; TC_598_599.port_b.Q_flow = -TC_598_599.Q_flow; TC_598_611.Q_flow = TC_598_611.G * TC_598_611.dT; TC_598_611.dT = TC_598_611.port_a.T - TC_598_611.port_b.T; TC_598_611.port_a.Q_flow = TC_598_611.Q_flow; TC_598_611.port_b.Q_flow = -TC_598_611.Q_flow; TC_599_600.Q_flow = TC_599_600.G * TC_599_600.dT; TC_599_600.dT = TC_599_600.port_a.T - TC_599_600.port_b.T; TC_599_600.port_a.Q_flow = TC_599_600.Q_flow; TC_599_600.port_b.Q_flow = -TC_599_600.Q_flow; TC_599_612.Q_flow = TC_599_612.G * TC_599_612.dT; TC_599_612.dT = TC_599_612.port_a.T - TC_599_612.port_b.T; TC_599_612.port_a.Q_flow = TC_599_612.Q_flow; TC_599_612.port_b.Q_flow = -TC_599_612.Q_flow; TC_599_964.Q_flow = TC_599_964.G * TC_599_964.dT; TC_599_964.dT = TC_599_964.port_a.T - TC_599_964.port_b.T; TC_599_964.port_a.Q_flow = TC_599_964.Q_flow; TC_599_964.port_b.Q_flow = -TC_599_964.Q_flow; TC_600_601.Q_flow = TC_600_601.G * TC_600_601.dT; TC_600_601.dT = TC_600_601.port_a.T - TC_600_601.port_b.T; TC_600_601.port_a.Q_flow = TC_600_601.Q_flow; TC_600_601.port_b.Q_flow = -TC_600_601.Q_flow; TC_600_613.Q_flow = TC_600_613.G * TC_600_613.dT; TC_600_613.dT = TC_600_613.port_a.T - TC_600_613.port_b.T; TC_600_613.port_a.Q_flow = TC_600_613.Q_flow; TC_600_613.port_b.Q_flow = -TC_600_613.Q_flow; TC_600_965.Q_flow = TC_600_965.G * TC_600_965.dT; TC_600_965.dT = TC_600_965.port_a.T - TC_600_965.port_b.T; TC_600_965.port_a.Q_flow = TC_600_965.Q_flow; TC_600_965.port_b.Q_flow = -TC_600_965.Q_flow; TC_601_602.Q_flow = TC_601_602.G * TC_601_602.dT; TC_601_602.dT = TC_601_602.port_a.T - TC_601_602.port_b.T; TC_601_602.port_a.Q_flow = TC_601_602.Q_flow; TC_601_602.port_b.Q_flow = -TC_601_602.Q_flow; TC_601_614.Q_flow = TC_601_614.G * TC_601_614.dT; TC_601_614.dT = TC_601_614.port_a.T - TC_601_614.port_b.T; TC_601_614.port_a.Q_flow = TC_601_614.Q_flow; TC_601_614.port_b.Q_flow = -TC_601_614.Q_flow; TC_601_966.Q_flow = TC_601_966.G * TC_601_966.dT; TC_601_966.dT = TC_601_966.port_a.T - TC_601_966.port_b.T; TC_601_966.port_a.Q_flow = TC_601_966.Q_flow; TC_601_966.port_b.Q_flow = -TC_601_966.Q_flow; TC_602_603.Q_flow = TC_602_603.G * TC_602_603.dT; TC_602_603.dT = TC_602_603.port_a.T - TC_602_603.port_b.T; TC_602_603.port_a.Q_flow = TC_602_603.Q_flow; TC_602_603.port_b.Q_flow = -TC_602_603.Q_flow; TC_602_615.Q_flow = TC_602_615.G * TC_602_615.dT; TC_602_615.dT = TC_602_615.port_a.T - TC_602_615.port_b.T; TC_602_615.port_a.Q_flow = TC_602_615.Q_flow; TC_602_615.port_b.Q_flow = -TC_602_615.Q_flow; TC_602_967.Q_flow = TC_602_967.G * TC_602_967.dT; TC_602_967.dT = TC_602_967.port_a.T - TC_602_967.port_b.T; TC_602_967.port_a.Q_flow = TC_602_967.Q_flow; TC_602_967.port_b.Q_flow = -TC_602_967.Q_flow; TC_603_604.Q_flow = TC_603_604.G * TC_603_604.dT; TC_603_604.dT = TC_603_604.port_a.T - TC_603_604.port_b.T; TC_603_604.port_a.Q_flow = TC_603_604.Q_flow; TC_603_604.port_b.Q_flow = -TC_603_604.Q_flow; TC_603_616.Q_flow = TC_603_616.G * TC_603_616.dT; TC_603_616.dT = TC_603_616.port_a.T - TC_603_616.port_b.T; TC_603_616.port_a.Q_flow = TC_603_616.Q_flow; TC_603_616.port_b.Q_flow = -TC_603_616.Q_flow; TC_603_968.Q_flow = TC_603_968.G * TC_603_968.dT; TC_603_968.dT = TC_603_968.port_a.T - TC_603_968.port_b.T; TC_603_968.port_a.Q_flow = TC_603_968.Q_flow; TC_603_968.port_b.Q_flow = -TC_603_968.Q_flow; TC_604_605.Q_flow = TC_604_605.G * TC_604_605.dT; TC_604_605.dT = TC_604_605.port_a.T - TC_604_605.port_b.T; TC_604_605.port_a.Q_flow = TC_604_605.Q_flow; TC_604_605.port_b.Q_flow = -TC_604_605.Q_flow; TC_604_617.Q_flow = TC_604_617.G * TC_604_617.dT; TC_604_617.dT = TC_604_617.port_a.T - TC_604_617.port_b.T; TC_604_617.port_a.Q_flow = TC_604_617.Q_flow; TC_604_617.port_b.Q_flow = -TC_604_617.Q_flow; TC_604_969.Q_flow = TC_604_969.G * TC_604_969.dT; TC_604_969.dT = TC_604_969.port_a.T - TC_604_969.port_b.T; TC_604_969.port_a.Q_flow = TC_604_969.Q_flow; TC_604_969.port_b.Q_flow = -TC_604_969.Q_flow; TC_605_606.Q_flow = TC_605_606.G * TC_605_606.dT; TC_605_606.dT = TC_605_606.port_a.T - TC_605_606.port_b.T; TC_605_606.port_a.Q_flow = TC_605_606.Q_flow; TC_605_606.port_b.Q_flow = -TC_605_606.Q_flow; TC_605_618.Q_flow = TC_605_618.G * TC_605_618.dT; TC_605_618.dT = TC_605_618.port_a.T - TC_605_618.port_b.T; TC_605_618.port_a.Q_flow = TC_605_618.Q_flow; TC_605_618.port_b.Q_flow = -TC_605_618.Q_flow; TC_605_970.Q_flow = TC_605_970.G * TC_605_970.dT; TC_605_970.dT = TC_605_970.port_a.T - TC_605_970.port_b.T; TC_605_970.port_a.Q_flow = TC_605_970.Q_flow; TC_605_970.port_b.Q_flow = -TC_605_970.Q_flow; TC_606_607.Q_flow = TC_606_607.G * TC_606_607.dT; TC_606_607.dT = TC_606_607.port_a.T - TC_606_607.port_b.T; TC_606_607.port_a.Q_flow = TC_606_607.Q_flow; TC_606_607.port_b.Q_flow = -TC_606_607.Q_flow; TC_606_619.Q_flow = TC_606_619.G * TC_606_619.dT; TC_606_619.dT = TC_606_619.port_a.T - TC_606_619.port_b.T; TC_606_619.port_a.Q_flow = TC_606_619.Q_flow; TC_606_619.port_b.Q_flow = -TC_606_619.Q_flow; TC_606_971.Q_flow = TC_606_971.G * TC_606_971.dT; TC_606_971.dT = TC_606_971.port_a.T - TC_606_971.port_b.T; TC_606_971.port_a.Q_flow = TC_606_971.Q_flow; TC_606_971.port_b.Q_flow = -TC_606_971.Q_flow; TC_607_608.Q_flow = TC_607_608.G * TC_607_608.dT; TC_607_608.dT = TC_607_608.port_a.T - TC_607_608.port_b.T; TC_607_608.port_a.Q_flow = TC_607_608.Q_flow; TC_607_608.port_b.Q_flow = -TC_607_608.Q_flow; TC_607_620.Q_flow = TC_607_620.G * TC_607_620.dT; TC_607_620.dT = TC_607_620.port_a.T - TC_607_620.port_b.T; TC_607_620.port_a.Q_flow = TC_607_620.Q_flow; TC_607_620.port_b.Q_flow = -TC_607_620.Q_flow; TC_607_972.Q_flow = TC_607_972.G * TC_607_972.dT; TC_607_972.dT = TC_607_972.port_a.T - TC_607_972.port_b.T; TC_607_972.port_a.Q_flow = TC_607_972.Q_flow; TC_607_972.port_b.Q_flow = -TC_607_972.Q_flow; TC_608_609.Q_flow = TC_608_609.G * TC_608_609.dT; TC_608_609.dT = TC_608_609.port_a.T - TC_608_609.port_b.T; TC_608_609.port_a.Q_flow = TC_608_609.Q_flow; TC_608_609.port_b.Q_flow = -TC_608_609.Q_flow; TC_608_621.Q_flow = TC_608_621.G * TC_608_621.dT; TC_608_621.dT = TC_608_621.port_a.T - TC_608_621.port_b.T; TC_608_621.port_a.Q_flow = TC_608_621.Q_flow; TC_608_621.port_b.Q_flow = -TC_608_621.Q_flow; TC_608_973.Q_flow = TC_608_973.G * TC_608_973.dT; TC_608_973.dT = TC_608_973.port_a.T - TC_608_973.port_b.T; TC_608_973.port_a.Q_flow = TC_608_973.Q_flow; TC_608_973.port_b.Q_flow = -TC_608_973.Q_flow; TC_609_610.Q_flow = TC_609_610.G * TC_609_610.dT; TC_609_610.dT = TC_609_610.port_a.T - TC_609_610.port_b.T; TC_609_610.port_a.Q_flow = TC_609_610.Q_flow; TC_609_610.port_b.Q_flow = -TC_609_610.Q_flow; TC_609_622.Q_flow = TC_609_622.G * TC_609_622.dT; TC_609_622.dT = TC_609_622.port_a.T - TC_609_622.port_b.T; TC_609_622.port_a.Q_flow = TC_609_622.Q_flow; TC_609_622.port_b.Q_flow = -TC_609_622.Q_flow; TC_609_974.Q_flow = TC_609_974.G * TC_609_974.dT; TC_609_974.dT = TC_609_974.port_a.T - TC_609_974.port_b.T; TC_609_974.port_a.Q_flow = TC_609_974.Q_flow; TC_609_974.port_b.Q_flow = -TC_609_974.Q_flow; TC_610_623.Q_flow = TC_610_623.G * TC_610_623.dT; TC_610_623.dT = TC_610_623.port_a.T - TC_610_623.port_b.T; TC_610_623.port_a.Q_flow = TC_610_623.Q_flow; TC_610_623.port_b.Q_flow = -TC_610_623.Q_flow; TC_611_612.Q_flow = TC_611_612.G * TC_611_612.dT; TC_611_612.dT = TC_611_612.port_a.T - TC_611_612.port_b.T; TC_611_612.port_a.Q_flow = TC_611_612.Q_flow; TC_611_612.port_b.Q_flow = -TC_611_612.Q_flow; TC_611_624.Q_flow = TC_611_624.G * TC_611_624.dT; TC_611_624.dT = TC_611_624.port_a.T - TC_611_624.port_b.T; TC_611_624.port_a.Q_flow = TC_611_624.Q_flow; TC_611_624.port_b.Q_flow = -TC_611_624.Q_flow; TC_612_613.Q_flow = TC_612_613.G * TC_612_613.dT; TC_612_613.dT = TC_612_613.port_a.T - TC_612_613.port_b.T; TC_612_613.port_a.Q_flow = TC_612_613.Q_flow; TC_612_613.port_b.Q_flow = -TC_612_613.Q_flow; TC_612_625.Q_flow = TC_612_625.G * TC_612_625.dT; TC_612_625.dT = TC_612_625.port_a.T - TC_612_625.port_b.T; TC_612_625.port_a.Q_flow = TC_612_625.Q_flow; TC_612_625.port_b.Q_flow = -TC_612_625.Q_flow; TC_612_843.Q_flow = TC_612_843.G * TC_612_843.dT; TC_612_843.dT = TC_612_843.port_a.T - TC_612_843.port_b.T; TC_612_843.port_a.Q_flow = TC_612_843.Q_flow; TC_612_843.port_b.Q_flow = -TC_612_843.Q_flow; TC_613_614.Q_flow = TC_613_614.G * TC_613_614.dT; TC_613_614.dT = TC_613_614.port_a.T - TC_613_614.port_b.T; TC_613_614.port_a.Q_flow = TC_613_614.Q_flow; TC_613_614.port_b.Q_flow = -TC_613_614.Q_flow; TC_613_626.Q_flow = TC_613_626.G * TC_613_626.dT; TC_613_626.dT = TC_613_626.port_a.T - TC_613_626.port_b.T; TC_613_626.port_a.Q_flow = TC_613_626.Q_flow; TC_613_626.port_b.Q_flow = -TC_613_626.Q_flow; TC_613_844.Q_flow = TC_613_844.G * TC_613_844.dT; TC_613_844.dT = TC_613_844.port_a.T - TC_613_844.port_b.T; TC_613_844.port_a.Q_flow = TC_613_844.Q_flow; TC_613_844.port_b.Q_flow = -TC_613_844.Q_flow; TC_614_615.Q_flow = TC_614_615.G * TC_614_615.dT; TC_614_615.dT = TC_614_615.port_a.T - TC_614_615.port_b.T; TC_614_615.port_a.Q_flow = TC_614_615.Q_flow; TC_614_615.port_b.Q_flow = -TC_614_615.Q_flow; TC_614_627.Q_flow = TC_614_627.G * TC_614_627.dT; TC_614_627.dT = TC_614_627.port_a.T - TC_614_627.port_b.T; TC_614_627.port_a.Q_flow = TC_614_627.Q_flow; TC_614_627.port_b.Q_flow = -TC_614_627.Q_flow; TC_614_845.Q_flow = TC_614_845.G * TC_614_845.dT; TC_614_845.dT = TC_614_845.port_a.T - TC_614_845.port_b.T; TC_614_845.port_a.Q_flow = TC_614_845.Q_flow; TC_614_845.port_b.Q_flow = -TC_614_845.Q_flow; TC_615_616.Q_flow = TC_615_616.G * TC_615_616.dT; TC_615_616.dT = TC_615_616.port_a.T - TC_615_616.port_b.T; TC_615_616.port_a.Q_flow = TC_615_616.Q_flow; TC_615_616.port_b.Q_flow = -TC_615_616.Q_flow; TC_615_628.Q_flow = TC_615_628.G * TC_615_628.dT; TC_615_628.dT = TC_615_628.port_a.T - TC_615_628.port_b.T; TC_615_628.port_a.Q_flow = TC_615_628.Q_flow; TC_615_628.port_b.Q_flow = -TC_615_628.Q_flow; TC_615_846.Q_flow = TC_615_846.G * TC_615_846.dT; TC_615_846.dT = TC_615_846.port_a.T - TC_615_846.port_b.T; TC_615_846.port_a.Q_flow = TC_615_846.Q_flow; TC_615_846.port_b.Q_flow = -TC_615_846.Q_flow; TC_616_617.Q_flow = TC_616_617.G * TC_616_617.dT; TC_616_617.dT = TC_616_617.port_a.T - TC_616_617.port_b.T; TC_616_617.port_a.Q_flow = TC_616_617.Q_flow; TC_616_617.port_b.Q_flow = -TC_616_617.Q_flow; TC_616_629.Q_flow = TC_616_629.G * TC_616_629.dT; TC_616_629.dT = TC_616_629.port_a.T - TC_616_629.port_b.T; TC_616_629.port_a.Q_flow = TC_616_629.Q_flow; TC_616_629.port_b.Q_flow = -TC_616_629.Q_flow; TC_616_847.Q_flow = TC_616_847.G * TC_616_847.dT; TC_616_847.dT = TC_616_847.port_a.T - TC_616_847.port_b.T; TC_616_847.port_a.Q_flow = TC_616_847.Q_flow; TC_616_847.port_b.Q_flow = -TC_616_847.Q_flow; TC_617_618.Q_flow = TC_617_618.G * TC_617_618.dT; TC_617_618.dT = TC_617_618.port_a.T - TC_617_618.port_b.T; TC_617_618.port_a.Q_flow = TC_617_618.Q_flow; TC_617_618.port_b.Q_flow = -TC_617_618.Q_flow; TC_617_630.Q_flow = TC_617_630.G * TC_617_630.dT; TC_617_630.dT = TC_617_630.port_a.T - TC_617_630.port_b.T; TC_617_630.port_a.Q_flow = TC_617_630.Q_flow; TC_617_630.port_b.Q_flow = -TC_617_630.Q_flow; TC_617_848.Q_flow = TC_617_848.G * TC_617_848.dT; TC_617_848.dT = TC_617_848.port_a.T - TC_617_848.port_b.T; TC_617_848.port_a.Q_flow = TC_617_848.Q_flow; TC_617_848.port_b.Q_flow = -TC_617_848.Q_flow; TC_618_619.Q_flow = TC_618_619.G * TC_618_619.dT; TC_618_619.dT = TC_618_619.port_a.T - TC_618_619.port_b.T; TC_618_619.port_a.Q_flow = TC_618_619.Q_flow; TC_618_619.port_b.Q_flow = -TC_618_619.Q_flow; TC_618_631.Q_flow = TC_618_631.G * TC_618_631.dT; TC_618_631.dT = TC_618_631.port_a.T - TC_618_631.port_b.T; TC_618_631.port_a.Q_flow = TC_618_631.Q_flow; TC_618_631.port_b.Q_flow = -TC_618_631.Q_flow; TC_618_849.Q_flow = TC_618_849.G * TC_618_849.dT; TC_618_849.dT = TC_618_849.port_a.T - TC_618_849.port_b.T; TC_618_849.port_a.Q_flow = TC_618_849.Q_flow; TC_618_849.port_b.Q_flow = -TC_618_849.Q_flow; TC_619_620.Q_flow = TC_619_620.G * TC_619_620.dT; TC_619_620.dT = TC_619_620.port_a.T - TC_619_620.port_b.T; TC_619_620.port_a.Q_flow = TC_619_620.Q_flow; TC_619_620.port_b.Q_flow = -TC_619_620.Q_flow; TC_619_632.Q_flow = TC_619_632.G * TC_619_632.dT; TC_619_632.dT = TC_619_632.port_a.T - TC_619_632.port_b.T; TC_619_632.port_a.Q_flow = TC_619_632.Q_flow; TC_619_632.port_b.Q_flow = -TC_619_632.Q_flow; TC_619_850.Q_flow = TC_619_850.G * TC_619_850.dT; TC_619_850.dT = TC_619_850.port_a.T - TC_619_850.port_b.T; TC_619_850.port_a.Q_flow = TC_619_850.Q_flow; TC_619_850.port_b.Q_flow = -TC_619_850.Q_flow; TC_620_621.Q_flow = TC_620_621.G * TC_620_621.dT; TC_620_621.dT = TC_620_621.port_a.T - TC_620_621.port_b.T; TC_620_621.port_a.Q_flow = TC_620_621.Q_flow; TC_620_621.port_b.Q_flow = -TC_620_621.Q_flow; TC_620_633.Q_flow = TC_620_633.G * TC_620_633.dT; TC_620_633.dT = TC_620_633.port_a.T - TC_620_633.port_b.T; TC_620_633.port_a.Q_flow = TC_620_633.Q_flow; TC_620_633.port_b.Q_flow = -TC_620_633.Q_flow; TC_620_851.Q_flow = TC_620_851.G * TC_620_851.dT; TC_620_851.dT = TC_620_851.port_a.T - TC_620_851.port_b.T; TC_620_851.port_a.Q_flow = TC_620_851.Q_flow; TC_620_851.port_b.Q_flow = -TC_620_851.Q_flow; TC_621_622.Q_flow = TC_621_622.G * TC_621_622.dT; TC_621_622.dT = TC_621_622.port_a.T - TC_621_622.port_b.T; TC_621_622.port_a.Q_flow = TC_621_622.Q_flow; TC_621_622.port_b.Q_flow = -TC_621_622.Q_flow; TC_621_634.Q_flow = TC_621_634.G * TC_621_634.dT; TC_621_634.dT = TC_621_634.port_a.T - TC_621_634.port_b.T; TC_621_634.port_a.Q_flow = TC_621_634.Q_flow; TC_621_634.port_b.Q_flow = -TC_621_634.Q_flow; TC_621_852.Q_flow = TC_621_852.G * TC_621_852.dT; TC_621_852.dT = TC_621_852.port_a.T - TC_621_852.port_b.T; TC_621_852.port_a.Q_flow = TC_621_852.Q_flow; TC_621_852.port_b.Q_flow = -TC_621_852.Q_flow; TC_622_623.Q_flow = TC_622_623.G * TC_622_623.dT; TC_622_623.dT = TC_622_623.port_a.T - TC_622_623.port_b.T; TC_622_623.port_a.Q_flow = TC_622_623.Q_flow; TC_622_623.port_b.Q_flow = -TC_622_623.Q_flow; TC_622_635.Q_flow = TC_622_635.G * TC_622_635.dT; TC_622_635.dT = TC_622_635.port_a.T - TC_622_635.port_b.T; TC_622_635.port_a.Q_flow = TC_622_635.Q_flow; TC_622_635.port_b.Q_flow = -TC_622_635.Q_flow; TC_622_853.Q_flow = TC_622_853.G * TC_622_853.dT; TC_622_853.dT = TC_622_853.port_a.T - TC_622_853.port_b.T; TC_622_853.port_a.Q_flow = TC_622_853.Q_flow; TC_622_853.port_b.Q_flow = -TC_622_853.Q_flow; TC_623_636.Q_flow = TC_623_636.G * TC_623_636.dT; TC_623_636.dT = TC_623_636.port_a.T - TC_623_636.port_b.T; TC_623_636.port_a.Q_flow = TC_623_636.Q_flow; TC_623_636.port_b.Q_flow = -TC_623_636.Q_flow; TC_624_625.Q_flow = TC_624_625.G * TC_624_625.dT; TC_624_625.dT = TC_624_625.port_a.T - TC_624_625.port_b.T; TC_624_625.port_a.Q_flow = TC_624_625.Q_flow; TC_624_625.port_b.Q_flow = -TC_624_625.Q_flow; TC_624_637.Q_flow = TC_624_637.G * TC_624_637.dT; TC_624_637.dT = TC_624_637.port_a.T - TC_624_637.port_b.T; TC_624_637.port_a.Q_flow = TC_624_637.Q_flow; TC_624_637.port_b.Q_flow = -TC_624_637.Q_flow; TC_625_626.Q_flow = TC_625_626.G * TC_625_626.dT; TC_625_626.dT = TC_625_626.port_a.T - TC_625_626.port_b.T; TC_625_626.port_a.Q_flow = TC_625_626.Q_flow; TC_625_626.port_b.Q_flow = -TC_625_626.Q_flow; TC_625_638.Q_flow = TC_625_638.G * TC_625_638.dT; TC_625_638.dT = TC_625_638.port_a.T - TC_625_638.port_b.T; TC_625_638.port_a.Q_flow = TC_625_638.Q_flow; TC_625_638.port_b.Q_flow = -TC_625_638.Q_flow; TC_625_854.Q_flow = TC_625_854.G * TC_625_854.dT; TC_625_854.dT = TC_625_854.port_a.T - TC_625_854.port_b.T; TC_625_854.port_a.Q_flow = TC_625_854.Q_flow; TC_625_854.port_b.Q_flow = -TC_625_854.Q_flow; TC_626_627.Q_flow = TC_626_627.G * TC_626_627.dT; TC_626_627.dT = TC_626_627.port_a.T - TC_626_627.port_b.T; TC_626_627.port_a.Q_flow = TC_626_627.Q_flow; TC_626_627.port_b.Q_flow = -TC_626_627.Q_flow; TC_626_639.Q_flow = TC_626_639.G * TC_626_639.dT; TC_626_639.dT = TC_626_639.port_a.T - TC_626_639.port_b.T; TC_626_639.port_a.Q_flow = TC_626_639.Q_flow; TC_626_639.port_b.Q_flow = -TC_626_639.Q_flow; TC_626_855.Q_flow = TC_626_855.G * TC_626_855.dT; TC_626_855.dT = TC_626_855.port_a.T - TC_626_855.port_b.T; TC_626_855.port_a.Q_flow = TC_626_855.Q_flow; TC_626_855.port_b.Q_flow = -TC_626_855.Q_flow; TC_627_628.Q_flow = TC_627_628.G * TC_627_628.dT; TC_627_628.dT = TC_627_628.port_a.T - TC_627_628.port_b.T; TC_627_628.port_a.Q_flow = TC_627_628.Q_flow; TC_627_628.port_b.Q_flow = -TC_627_628.Q_flow; TC_627_640.Q_flow = TC_627_640.G * TC_627_640.dT; TC_627_640.dT = TC_627_640.port_a.T - TC_627_640.port_b.T; TC_627_640.port_a.Q_flow = TC_627_640.Q_flow; TC_627_640.port_b.Q_flow = -TC_627_640.Q_flow; TC_627_856.Q_flow = TC_627_856.G * TC_627_856.dT; TC_627_856.dT = TC_627_856.port_a.T - TC_627_856.port_b.T; TC_627_856.port_a.Q_flow = TC_627_856.Q_flow; TC_627_856.port_b.Q_flow = -TC_627_856.Q_flow; TC_628_629.Q_flow = TC_628_629.G * TC_628_629.dT; TC_628_629.dT = TC_628_629.port_a.T - TC_628_629.port_b.T; TC_628_629.port_a.Q_flow = TC_628_629.Q_flow; TC_628_629.port_b.Q_flow = -TC_628_629.Q_flow; TC_628_641.Q_flow = TC_628_641.G * TC_628_641.dT; TC_628_641.dT = TC_628_641.port_a.T - TC_628_641.port_b.T; TC_628_641.port_a.Q_flow = TC_628_641.Q_flow; TC_628_641.port_b.Q_flow = -TC_628_641.Q_flow; TC_628_857.Q_flow = TC_628_857.G * TC_628_857.dT; TC_628_857.dT = TC_628_857.port_a.T - TC_628_857.port_b.T; TC_628_857.port_a.Q_flow = TC_628_857.Q_flow; TC_628_857.port_b.Q_flow = -TC_628_857.Q_flow; TC_629_630.Q_flow = TC_629_630.G * TC_629_630.dT; TC_629_630.dT = TC_629_630.port_a.T - TC_629_630.port_b.T; TC_629_630.port_a.Q_flow = TC_629_630.Q_flow; TC_629_630.port_b.Q_flow = -TC_629_630.Q_flow; TC_629_642.Q_flow = TC_629_642.G * TC_629_642.dT; TC_629_642.dT = TC_629_642.port_a.T - TC_629_642.port_b.T; TC_629_642.port_a.Q_flow = TC_629_642.Q_flow; TC_629_642.port_b.Q_flow = -TC_629_642.Q_flow; TC_629_858.Q_flow = TC_629_858.G * TC_629_858.dT; TC_629_858.dT = TC_629_858.port_a.T - TC_629_858.port_b.T; TC_629_858.port_a.Q_flow = TC_629_858.Q_flow; TC_629_858.port_b.Q_flow = -TC_629_858.Q_flow; TC_630_631.Q_flow = TC_630_631.G * TC_630_631.dT; TC_630_631.dT = TC_630_631.port_a.T - TC_630_631.port_b.T; TC_630_631.port_a.Q_flow = TC_630_631.Q_flow; TC_630_631.port_b.Q_flow = -TC_630_631.Q_flow; TC_630_643.Q_flow = TC_630_643.G * TC_630_643.dT; TC_630_643.dT = TC_630_643.port_a.T - TC_630_643.port_b.T; TC_630_643.port_a.Q_flow = TC_630_643.Q_flow; TC_630_643.port_b.Q_flow = -TC_630_643.Q_flow; TC_630_859.Q_flow = TC_630_859.G * TC_630_859.dT; TC_630_859.dT = TC_630_859.port_a.T - TC_630_859.port_b.T; TC_630_859.port_a.Q_flow = TC_630_859.Q_flow; TC_630_859.port_b.Q_flow = -TC_630_859.Q_flow; TC_631_632.Q_flow = TC_631_632.G * TC_631_632.dT; TC_631_632.dT = TC_631_632.port_a.T - TC_631_632.port_b.T; TC_631_632.port_a.Q_flow = TC_631_632.Q_flow; TC_631_632.port_b.Q_flow = -TC_631_632.Q_flow; TC_631_644.Q_flow = TC_631_644.G * TC_631_644.dT; TC_631_644.dT = TC_631_644.port_a.T - TC_631_644.port_b.T; TC_631_644.port_a.Q_flow = TC_631_644.Q_flow; TC_631_644.port_b.Q_flow = -TC_631_644.Q_flow; TC_631_860.Q_flow = TC_631_860.G * TC_631_860.dT; TC_631_860.dT = TC_631_860.port_a.T - TC_631_860.port_b.T; TC_631_860.port_a.Q_flow = TC_631_860.Q_flow; TC_631_860.port_b.Q_flow = -TC_631_860.Q_flow; TC_632_633.Q_flow = TC_632_633.G * TC_632_633.dT; TC_632_633.dT = TC_632_633.port_a.T - TC_632_633.port_b.T; TC_632_633.port_a.Q_flow = TC_632_633.Q_flow; TC_632_633.port_b.Q_flow = -TC_632_633.Q_flow; TC_632_645.Q_flow = TC_632_645.G * TC_632_645.dT; TC_632_645.dT = TC_632_645.port_a.T - TC_632_645.port_b.T; TC_632_645.port_a.Q_flow = TC_632_645.Q_flow; TC_632_645.port_b.Q_flow = -TC_632_645.Q_flow; TC_632_861.Q_flow = TC_632_861.G * TC_632_861.dT; TC_632_861.dT = TC_632_861.port_a.T - TC_632_861.port_b.T; TC_632_861.port_a.Q_flow = TC_632_861.Q_flow; TC_632_861.port_b.Q_flow = -TC_632_861.Q_flow; TC_633_634.Q_flow = TC_633_634.G * TC_633_634.dT; TC_633_634.dT = TC_633_634.port_a.T - TC_633_634.port_b.T; TC_633_634.port_a.Q_flow = TC_633_634.Q_flow; TC_633_634.port_b.Q_flow = -TC_633_634.Q_flow; TC_633_646.Q_flow = TC_633_646.G * TC_633_646.dT; TC_633_646.dT = TC_633_646.port_a.T - TC_633_646.port_b.T; TC_633_646.port_a.Q_flow = TC_633_646.Q_flow; TC_633_646.port_b.Q_flow = -TC_633_646.Q_flow; TC_633_862.Q_flow = TC_633_862.G * TC_633_862.dT; TC_633_862.dT = TC_633_862.port_a.T - TC_633_862.port_b.T; TC_633_862.port_a.Q_flow = TC_633_862.Q_flow; TC_633_862.port_b.Q_flow = -TC_633_862.Q_flow; TC_634_635.Q_flow = TC_634_635.G * TC_634_635.dT; TC_634_635.dT = TC_634_635.port_a.T - TC_634_635.port_b.T; TC_634_635.port_a.Q_flow = TC_634_635.Q_flow; TC_634_635.port_b.Q_flow = -TC_634_635.Q_flow; TC_634_647.Q_flow = TC_634_647.G * TC_634_647.dT; TC_634_647.dT = TC_634_647.port_a.T - TC_634_647.port_b.T; TC_634_647.port_a.Q_flow = TC_634_647.Q_flow; TC_634_647.port_b.Q_flow = -TC_634_647.Q_flow; TC_634_863.Q_flow = TC_634_863.G * TC_634_863.dT; TC_634_863.dT = TC_634_863.port_a.T - TC_634_863.port_b.T; TC_634_863.port_a.Q_flow = TC_634_863.Q_flow; TC_634_863.port_b.Q_flow = -TC_634_863.Q_flow; TC_635_636.Q_flow = TC_635_636.G * TC_635_636.dT; TC_635_636.dT = TC_635_636.port_a.T - TC_635_636.port_b.T; TC_635_636.port_a.Q_flow = TC_635_636.Q_flow; TC_635_636.port_b.Q_flow = -TC_635_636.Q_flow; TC_635_648.Q_flow = TC_635_648.G * TC_635_648.dT; TC_635_648.dT = TC_635_648.port_a.T - TC_635_648.port_b.T; TC_635_648.port_a.Q_flow = TC_635_648.Q_flow; TC_635_648.port_b.Q_flow = -TC_635_648.Q_flow; TC_635_864.Q_flow = TC_635_864.G * TC_635_864.dT; TC_635_864.dT = TC_635_864.port_a.T - TC_635_864.port_b.T; TC_635_864.port_a.Q_flow = TC_635_864.Q_flow; TC_635_864.port_b.Q_flow = -TC_635_864.Q_flow; TC_636_649.Q_flow = TC_636_649.G * TC_636_649.dT; TC_636_649.dT = TC_636_649.port_a.T - TC_636_649.port_b.T; TC_636_649.port_a.Q_flow = TC_636_649.Q_flow; TC_636_649.port_b.Q_flow = -TC_636_649.Q_flow; TC_637_638.Q_flow = TC_637_638.G * TC_637_638.dT; TC_637_638.dT = TC_637_638.port_a.T - TC_637_638.port_b.T; TC_637_638.port_a.Q_flow = TC_637_638.Q_flow; TC_637_638.port_b.Q_flow = -TC_637_638.Q_flow; TC_637_650.Q_flow = TC_637_650.G * TC_637_650.dT; TC_637_650.dT = TC_637_650.port_a.T - TC_637_650.port_b.T; TC_637_650.port_a.Q_flow = TC_637_650.Q_flow; TC_637_650.port_b.Q_flow = -TC_637_650.Q_flow; TC_638_639.Q_flow = TC_638_639.G * TC_638_639.dT; TC_638_639.dT = TC_638_639.port_a.T - TC_638_639.port_b.T; TC_638_639.port_a.Q_flow = TC_638_639.Q_flow; TC_638_639.port_b.Q_flow = -TC_638_639.Q_flow; TC_638_651.Q_flow = TC_638_651.G * TC_638_651.dT; TC_638_651.dT = TC_638_651.port_a.T - TC_638_651.port_b.T; TC_638_651.port_a.Q_flow = TC_638_651.Q_flow; TC_638_651.port_b.Q_flow = -TC_638_651.Q_flow; TC_638_865.Q_flow = TC_638_865.G * TC_638_865.dT; TC_638_865.dT = TC_638_865.port_a.T - TC_638_865.port_b.T; TC_638_865.port_a.Q_flow = TC_638_865.Q_flow; TC_638_865.port_b.Q_flow = -TC_638_865.Q_flow; TC_639_640.Q_flow = TC_639_640.G * TC_639_640.dT; TC_639_640.dT = TC_639_640.port_a.T - TC_639_640.port_b.T; TC_639_640.port_a.Q_flow = TC_639_640.Q_flow; TC_639_640.port_b.Q_flow = -TC_639_640.Q_flow; TC_639_652.Q_flow = TC_639_652.G * TC_639_652.dT; TC_639_652.dT = TC_639_652.port_a.T - TC_639_652.port_b.T; TC_639_652.port_a.Q_flow = TC_639_652.Q_flow; TC_639_652.port_b.Q_flow = -TC_639_652.Q_flow; TC_639_866.Q_flow = TC_639_866.G * TC_639_866.dT; TC_639_866.dT = TC_639_866.port_a.T - TC_639_866.port_b.T; TC_639_866.port_a.Q_flow = TC_639_866.Q_flow; TC_639_866.port_b.Q_flow = -TC_639_866.Q_flow; TC_640_641.Q_flow = TC_640_641.G * TC_640_641.dT; TC_640_641.dT = TC_640_641.port_a.T - TC_640_641.port_b.T; TC_640_641.port_a.Q_flow = TC_640_641.Q_flow; TC_640_641.port_b.Q_flow = -TC_640_641.Q_flow; TC_640_653.Q_flow = TC_640_653.G * TC_640_653.dT; TC_640_653.dT = TC_640_653.port_a.T - TC_640_653.port_b.T; TC_640_653.port_a.Q_flow = TC_640_653.Q_flow; TC_640_653.port_b.Q_flow = -TC_640_653.Q_flow; TC_640_867.Q_flow = TC_640_867.G * TC_640_867.dT; TC_640_867.dT = TC_640_867.port_a.T - TC_640_867.port_b.T; TC_640_867.port_a.Q_flow = TC_640_867.Q_flow; TC_640_867.port_b.Q_flow = -TC_640_867.Q_flow; TC_641_642.Q_flow = TC_641_642.G * TC_641_642.dT; TC_641_642.dT = TC_641_642.port_a.T - TC_641_642.port_b.T; TC_641_642.port_a.Q_flow = TC_641_642.Q_flow; TC_641_642.port_b.Q_flow = -TC_641_642.Q_flow; TC_641_654.Q_flow = TC_641_654.G * TC_641_654.dT; TC_641_654.dT = TC_641_654.port_a.T - TC_641_654.port_b.T; TC_641_654.port_a.Q_flow = TC_641_654.Q_flow; TC_641_654.port_b.Q_flow = -TC_641_654.Q_flow; TC_641_868.Q_flow = TC_641_868.G * TC_641_868.dT; TC_641_868.dT = TC_641_868.port_a.T - TC_641_868.port_b.T; TC_641_868.port_a.Q_flow = TC_641_868.Q_flow; TC_641_868.port_b.Q_flow = -TC_641_868.Q_flow; TC_642_643.Q_flow = TC_642_643.G * TC_642_643.dT; TC_642_643.dT = TC_642_643.port_a.T - TC_642_643.port_b.T; TC_642_643.port_a.Q_flow = TC_642_643.Q_flow; TC_642_643.port_b.Q_flow = -TC_642_643.Q_flow; TC_642_655.Q_flow = TC_642_655.G * TC_642_655.dT; TC_642_655.dT = TC_642_655.port_a.T - TC_642_655.port_b.T; TC_642_655.port_a.Q_flow = TC_642_655.Q_flow; TC_642_655.port_b.Q_flow = -TC_642_655.Q_flow; TC_642_869.Q_flow = TC_642_869.G * TC_642_869.dT; TC_642_869.dT = TC_642_869.port_a.T - TC_642_869.port_b.T; TC_642_869.port_a.Q_flow = TC_642_869.Q_flow; TC_642_869.port_b.Q_flow = -TC_642_869.Q_flow; TC_643_644.Q_flow = TC_643_644.G * TC_643_644.dT; TC_643_644.dT = TC_643_644.port_a.T - TC_643_644.port_b.T; TC_643_644.port_a.Q_flow = TC_643_644.Q_flow; TC_643_644.port_b.Q_flow = -TC_643_644.Q_flow; TC_643_656.Q_flow = TC_643_656.G * TC_643_656.dT; TC_643_656.dT = TC_643_656.port_a.T - TC_643_656.port_b.T; TC_643_656.port_a.Q_flow = TC_643_656.Q_flow; TC_643_656.port_b.Q_flow = -TC_643_656.Q_flow; TC_643_870.Q_flow = TC_643_870.G * TC_643_870.dT; TC_643_870.dT = TC_643_870.port_a.T - TC_643_870.port_b.T; TC_643_870.port_a.Q_flow = TC_643_870.Q_flow; TC_643_870.port_b.Q_flow = -TC_643_870.Q_flow; TC_644_645.Q_flow = TC_644_645.G * TC_644_645.dT; TC_644_645.dT = TC_644_645.port_a.T - TC_644_645.port_b.T; TC_644_645.port_a.Q_flow = TC_644_645.Q_flow; TC_644_645.port_b.Q_flow = -TC_644_645.Q_flow; TC_644_657.Q_flow = TC_644_657.G * TC_644_657.dT; TC_644_657.dT = TC_644_657.port_a.T - TC_644_657.port_b.T; TC_644_657.port_a.Q_flow = TC_644_657.Q_flow; TC_644_657.port_b.Q_flow = -TC_644_657.Q_flow; TC_644_871.Q_flow = TC_644_871.G * TC_644_871.dT; TC_644_871.dT = TC_644_871.port_a.T - TC_644_871.port_b.T; TC_644_871.port_a.Q_flow = TC_644_871.Q_flow; TC_644_871.port_b.Q_flow = -TC_644_871.Q_flow; TC_645_646.Q_flow = TC_645_646.G * TC_645_646.dT; TC_645_646.dT = TC_645_646.port_a.T - TC_645_646.port_b.T; TC_645_646.port_a.Q_flow = TC_645_646.Q_flow; TC_645_646.port_b.Q_flow = -TC_645_646.Q_flow; TC_645_658.Q_flow = TC_645_658.G * TC_645_658.dT; TC_645_658.dT = TC_645_658.port_a.T - TC_645_658.port_b.T; TC_645_658.port_a.Q_flow = TC_645_658.Q_flow; TC_645_658.port_b.Q_flow = -TC_645_658.Q_flow; TC_645_872.Q_flow = TC_645_872.G * TC_645_872.dT; TC_645_872.dT = TC_645_872.port_a.T - TC_645_872.port_b.T; TC_645_872.port_a.Q_flow = TC_645_872.Q_flow; TC_645_872.port_b.Q_flow = -TC_645_872.Q_flow; TC_646_647.Q_flow = TC_646_647.G * TC_646_647.dT; TC_646_647.dT = TC_646_647.port_a.T - TC_646_647.port_b.T; TC_646_647.port_a.Q_flow = TC_646_647.Q_flow; TC_646_647.port_b.Q_flow = -TC_646_647.Q_flow; TC_646_659.Q_flow = TC_646_659.G * TC_646_659.dT; TC_646_659.dT = TC_646_659.port_a.T - TC_646_659.port_b.T; TC_646_659.port_a.Q_flow = TC_646_659.Q_flow; TC_646_659.port_b.Q_flow = -TC_646_659.Q_flow; TC_646_873.Q_flow = TC_646_873.G * TC_646_873.dT; TC_646_873.dT = TC_646_873.port_a.T - TC_646_873.port_b.T; TC_646_873.port_a.Q_flow = TC_646_873.Q_flow; TC_646_873.port_b.Q_flow = -TC_646_873.Q_flow; TC_647_648.Q_flow = TC_647_648.G * TC_647_648.dT; TC_647_648.dT = TC_647_648.port_a.T - TC_647_648.port_b.T; TC_647_648.port_a.Q_flow = TC_647_648.Q_flow; TC_647_648.port_b.Q_flow = -TC_647_648.Q_flow; TC_647_660.Q_flow = TC_647_660.G * TC_647_660.dT; TC_647_660.dT = TC_647_660.port_a.T - TC_647_660.port_b.T; TC_647_660.port_a.Q_flow = TC_647_660.Q_flow; TC_647_660.port_b.Q_flow = -TC_647_660.Q_flow; TC_647_874.Q_flow = TC_647_874.G * TC_647_874.dT; TC_647_874.dT = TC_647_874.port_a.T - TC_647_874.port_b.T; TC_647_874.port_a.Q_flow = TC_647_874.Q_flow; TC_647_874.port_b.Q_flow = -TC_647_874.Q_flow; TC_648_649.Q_flow = TC_648_649.G * TC_648_649.dT; TC_648_649.dT = TC_648_649.port_a.T - TC_648_649.port_b.T; TC_648_649.port_a.Q_flow = TC_648_649.Q_flow; TC_648_649.port_b.Q_flow = -TC_648_649.Q_flow; TC_648_661.Q_flow = TC_648_661.G * TC_648_661.dT; TC_648_661.dT = TC_648_661.port_a.T - TC_648_661.port_b.T; TC_648_661.port_a.Q_flow = TC_648_661.Q_flow; TC_648_661.port_b.Q_flow = -TC_648_661.Q_flow; TC_648_875.Q_flow = TC_648_875.G * TC_648_875.dT; TC_648_875.dT = TC_648_875.port_a.T - TC_648_875.port_b.T; TC_648_875.port_a.Q_flow = TC_648_875.Q_flow; TC_648_875.port_b.Q_flow = -TC_648_875.Q_flow; TC_649_662.Q_flow = TC_649_662.G * TC_649_662.dT; TC_649_662.dT = TC_649_662.port_a.T - TC_649_662.port_b.T; TC_649_662.port_a.Q_flow = TC_649_662.Q_flow; TC_649_662.port_b.Q_flow = -TC_649_662.Q_flow; TC_650_651.Q_flow = TC_650_651.G * TC_650_651.dT; TC_650_651.dT = TC_650_651.port_a.T - TC_650_651.port_b.T; TC_650_651.port_a.Q_flow = TC_650_651.Q_flow; TC_650_651.port_b.Q_flow = -TC_650_651.Q_flow; TC_650_663.Q_flow = TC_650_663.G * TC_650_663.dT; TC_650_663.dT = TC_650_663.port_a.T - TC_650_663.port_b.T; TC_650_663.port_a.Q_flow = TC_650_663.Q_flow; TC_650_663.port_b.Q_flow = -TC_650_663.Q_flow; TC_651_652.Q_flow = TC_651_652.G * TC_651_652.dT; TC_651_652.dT = TC_651_652.port_a.T - TC_651_652.port_b.T; TC_651_652.port_a.Q_flow = TC_651_652.Q_flow; TC_651_652.port_b.Q_flow = -TC_651_652.Q_flow; TC_651_664.Q_flow = TC_651_664.G * TC_651_664.dT; TC_651_664.dT = TC_651_664.port_a.T - TC_651_664.port_b.T; TC_651_664.port_a.Q_flow = TC_651_664.Q_flow; TC_651_664.port_b.Q_flow = -TC_651_664.Q_flow; TC_651_876.Q_flow = TC_651_876.G * TC_651_876.dT; TC_651_876.dT = TC_651_876.port_a.T - TC_651_876.port_b.T; TC_651_876.port_a.Q_flow = TC_651_876.Q_flow; TC_651_876.port_b.Q_flow = -TC_651_876.Q_flow; TC_652_653.Q_flow = TC_652_653.G * TC_652_653.dT; TC_652_653.dT = TC_652_653.port_a.T - TC_652_653.port_b.T; TC_652_653.port_a.Q_flow = TC_652_653.Q_flow; TC_652_653.port_b.Q_flow = -TC_652_653.Q_flow; TC_652_665.Q_flow = TC_652_665.G * TC_652_665.dT; TC_652_665.dT = TC_652_665.port_a.T - TC_652_665.port_b.T; TC_652_665.port_a.Q_flow = TC_652_665.Q_flow; TC_652_665.port_b.Q_flow = -TC_652_665.Q_flow; TC_652_877.Q_flow = TC_652_877.G * TC_652_877.dT; TC_652_877.dT = TC_652_877.port_a.T - TC_652_877.port_b.T; TC_652_877.port_a.Q_flow = TC_652_877.Q_flow; TC_652_877.port_b.Q_flow = -TC_652_877.Q_flow; TC_653_654.Q_flow = TC_653_654.G * TC_653_654.dT; TC_653_654.dT = TC_653_654.port_a.T - TC_653_654.port_b.T; TC_653_654.port_a.Q_flow = TC_653_654.Q_flow; TC_653_654.port_b.Q_flow = -TC_653_654.Q_flow; TC_653_666.Q_flow = TC_653_666.G * TC_653_666.dT; TC_653_666.dT = TC_653_666.port_a.T - TC_653_666.port_b.T; TC_653_666.port_a.Q_flow = TC_653_666.Q_flow; TC_653_666.port_b.Q_flow = -TC_653_666.Q_flow; TC_653_878.Q_flow = TC_653_878.G * TC_653_878.dT; TC_653_878.dT = TC_653_878.port_a.T - TC_653_878.port_b.T; TC_653_878.port_a.Q_flow = TC_653_878.Q_flow; TC_653_878.port_b.Q_flow = -TC_653_878.Q_flow; TC_654_655.Q_flow = TC_654_655.G * TC_654_655.dT; TC_654_655.dT = TC_654_655.port_a.T - TC_654_655.port_b.T; TC_654_655.port_a.Q_flow = TC_654_655.Q_flow; TC_654_655.port_b.Q_flow = -TC_654_655.Q_flow; TC_654_667.Q_flow = TC_654_667.G * TC_654_667.dT; TC_654_667.dT = TC_654_667.port_a.T - TC_654_667.port_b.T; TC_654_667.port_a.Q_flow = TC_654_667.Q_flow; TC_654_667.port_b.Q_flow = -TC_654_667.Q_flow; TC_654_879.Q_flow = TC_654_879.G * TC_654_879.dT; TC_654_879.dT = TC_654_879.port_a.T - TC_654_879.port_b.T; TC_654_879.port_a.Q_flow = TC_654_879.Q_flow; TC_654_879.port_b.Q_flow = -TC_654_879.Q_flow; TC_655_656.Q_flow = TC_655_656.G * TC_655_656.dT; TC_655_656.dT = TC_655_656.port_a.T - TC_655_656.port_b.T; TC_655_656.port_a.Q_flow = TC_655_656.Q_flow; TC_655_656.port_b.Q_flow = -TC_655_656.Q_flow; TC_655_668.Q_flow = TC_655_668.G * TC_655_668.dT; TC_655_668.dT = TC_655_668.port_a.T - TC_655_668.port_b.T; TC_655_668.port_a.Q_flow = TC_655_668.Q_flow; TC_655_668.port_b.Q_flow = -TC_655_668.Q_flow; TC_655_880.Q_flow = TC_655_880.G * TC_655_880.dT; TC_655_880.dT = TC_655_880.port_a.T - TC_655_880.port_b.T; TC_655_880.port_a.Q_flow = TC_655_880.Q_flow; TC_655_880.port_b.Q_flow = -TC_655_880.Q_flow; TC_656_657.Q_flow = TC_656_657.G * TC_656_657.dT; TC_656_657.dT = TC_656_657.port_a.T - TC_656_657.port_b.T; TC_656_657.port_a.Q_flow = TC_656_657.Q_flow; TC_656_657.port_b.Q_flow = -TC_656_657.Q_flow; TC_656_669.Q_flow = TC_656_669.G * TC_656_669.dT; TC_656_669.dT = TC_656_669.port_a.T - TC_656_669.port_b.T; TC_656_669.port_a.Q_flow = TC_656_669.Q_flow; TC_656_669.port_b.Q_flow = -TC_656_669.Q_flow; TC_656_881.Q_flow = TC_656_881.G * TC_656_881.dT; TC_656_881.dT = TC_656_881.port_a.T - TC_656_881.port_b.T; TC_656_881.port_a.Q_flow = TC_656_881.Q_flow; TC_656_881.port_b.Q_flow = -TC_656_881.Q_flow; TC_657_658.Q_flow = TC_657_658.G * TC_657_658.dT; TC_657_658.dT = TC_657_658.port_a.T - TC_657_658.port_b.T; TC_657_658.port_a.Q_flow = TC_657_658.Q_flow; TC_657_658.port_b.Q_flow = -TC_657_658.Q_flow; TC_657_670.Q_flow = TC_657_670.G * TC_657_670.dT; TC_657_670.dT = TC_657_670.port_a.T - TC_657_670.port_b.T; TC_657_670.port_a.Q_flow = TC_657_670.Q_flow; TC_657_670.port_b.Q_flow = -TC_657_670.Q_flow; TC_657_882.Q_flow = TC_657_882.G * TC_657_882.dT; TC_657_882.dT = TC_657_882.port_a.T - TC_657_882.port_b.T; TC_657_882.port_a.Q_flow = TC_657_882.Q_flow; TC_657_882.port_b.Q_flow = -TC_657_882.Q_flow; TC_658_659.Q_flow = TC_658_659.G * TC_658_659.dT; TC_658_659.dT = TC_658_659.port_a.T - TC_658_659.port_b.T; TC_658_659.port_a.Q_flow = TC_658_659.Q_flow; TC_658_659.port_b.Q_flow = -TC_658_659.Q_flow; TC_658_671.Q_flow = TC_658_671.G * TC_658_671.dT; TC_658_671.dT = TC_658_671.port_a.T - TC_658_671.port_b.T; TC_658_671.port_a.Q_flow = TC_658_671.Q_flow; TC_658_671.port_b.Q_flow = -TC_658_671.Q_flow; TC_658_883.Q_flow = TC_658_883.G * TC_658_883.dT; TC_658_883.dT = TC_658_883.port_a.T - TC_658_883.port_b.T; TC_658_883.port_a.Q_flow = TC_658_883.Q_flow; TC_658_883.port_b.Q_flow = -TC_658_883.Q_flow; TC_659_660.Q_flow = TC_659_660.G * TC_659_660.dT; TC_659_660.dT = TC_659_660.port_a.T - TC_659_660.port_b.T; TC_659_660.port_a.Q_flow = TC_659_660.Q_flow; TC_659_660.port_b.Q_flow = -TC_659_660.Q_flow; TC_659_672.Q_flow = TC_659_672.G * TC_659_672.dT; TC_659_672.dT = TC_659_672.port_a.T - TC_659_672.port_b.T; TC_659_672.port_a.Q_flow = TC_659_672.Q_flow; TC_659_672.port_b.Q_flow = -TC_659_672.Q_flow; TC_659_884.Q_flow = TC_659_884.G * TC_659_884.dT; TC_659_884.dT = TC_659_884.port_a.T - TC_659_884.port_b.T; TC_659_884.port_a.Q_flow = TC_659_884.Q_flow; TC_659_884.port_b.Q_flow = -TC_659_884.Q_flow; TC_660_661.Q_flow = TC_660_661.G * TC_660_661.dT; TC_660_661.dT = TC_660_661.port_a.T - TC_660_661.port_b.T; TC_660_661.port_a.Q_flow = TC_660_661.Q_flow; TC_660_661.port_b.Q_flow = -TC_660_661.Q_flow; TC_660_673.Q_flow = TC_660_673.G * TC_660_673.dT; TC_660_673.dT = TC_660_673.port_a.T - TC_660_673.port_b.T; TC_660_673.port_a.Q_flow = TC_660_673.Q_flow; TC_660_673.port_b.Q_flow = -TC_660_673.Q_flow; TC_660_885.Q_flow = TC_660_885.G * TC_660_885.dT; TC_660_885.dT = TC_660_885.port_a.T - TC_660_885.port_b.T; TC_660_885.port_a.Q_flow = TC_660_885.Q_flow; TC_660_885.port_b.Q_flow = -TC_660_885.Q_flow; TC_661_662.Q_flow = TC_661_662.G * TC_661_662.dT; TC_661_662.dT = TC_661_662.port_a.T - TC_661_662.port_b.T; TC_661_662.port_a.Q_flow = TC_661_662.Q_flow; TC_661_662.port_b.Q_flow = -TC_661_662.Q_flow; TC_661_674.Q_flow = TC_661_674.G * TC_661_674.dT; TC_661_674.dT = TC_661_674.port_a.T - TC_661_674.port_b.T; TC_661_674.port_a.Q_flow = TC_661_674.Q_flow; TC_661_674.port_b.Q_flow = -TC_661_674.Q_flow; TC_661_886.Q_flow = TC_661_886.G * TC_661_886.dT; TC_661_886.dT = TC_661_886.port_a.T - TC_661_886.port_b.T; TC_661_886.port_a.Q_flow = TC_661_886.Q_flow; TC_661_886.port_b.Q_flow = -TC_661_886.Q_flow; TC_662_675.Q_flow = TC_662_675.G * TC_662_675.dT; TC_662_675.dT = TC_662_675.port_a.T - TC_662_675.port_b.T; TC_662_675.port_a.Q_flow = TC_662_675.Q_flow; TC_662_675.port_b.Q_flow = -TC_662_675.Q_flow; TC_663_664.Q_flow = TC_663_664.G * TC_663_664.dT; TC_663_664.dT = TC_663_664.port_a.T - TC_663_664.port_b.T; TC_663_664.port_a.Q_flow = TC_663_664.Q_flow; TC_663_664.port_b.Q_flow = -TC_663_664.Q_flow; TC_663_676.Q_flow = TC_663_676.G * TC_663_676.dT; TC_663_676.dT = TC_663_676.port_a.T - TC_663_676.port_b.T; TC_663_676.port_a.Q_flow = TC_663_676.Q_flow; TC_663_676.port_b.Q_flow = -TC_663_676.Q_flow; TC_664_665.Q_flow = TC_664_665.G * TC_664_665.dT; TC_664_665.dT = TC_664_665.port_a.T - TC_664_665.port_b.T; TC_664_665.port_a.Q_flow = TC_664_665.Q_flow; TC_664_665.port_b.Q_flow = -TC_664_665.Q_flow; TC_664_677.Q_flow = TC_664_677.G * TC_664_677.dT; TC_664_677.dT = TC_664_677.port_a.T - TC_664_677.port_b.T; TC_664_677.port_a.Q_flow = TC_664_677.Q_flow; TC_664_677.port_b.Q_flow = -TC_664_677.Q_flow; TC_664_887.Q_flow = TC_664_887.G * TC_664_887.dT; TC_664_887.dT = TC_664_887.port_a.T - TC_664_887.port_b.T; TC_664_887.port_a.Q_flow = TC_664_887.Q_flow; TC_664_887.port_b.Q_flow = -TC_664_887.Q_flow; TC_665_666.Q_flow = TC_665_666.G * TC_665_666.dT; TC_665_666.dT = TC_665_666.port_a.T - TC_665_666.port_b.T; TC_665_666.port_a.Q_flow = TC_665_666.Q_flow; TC_665_666.port_b.Q_flow = -TC_665_666.Q_flow; TC_665_678.Q_flow = TC_665_678.G * TC_665_678.dT; TC_665_678.dT = TC_665_678.port_a.T - TC_665_678.port_b.T; TC_665_678.port_a.Q_flow = TC_665_678.Q_flow; TC_665_678.port_b.Q_flow = -TC_665_678.Q_flow; TC_665_888.Q_flow = TC_665_888.G * TC_665_888.dT; TC_665_888.dT = TC_665_888.port_a.T - TC_665_888.port_b.T; TC_665_888.port_a.Q_flow = TC_665_888.Q_flow; TC_665_888.port_b.Q_flow = -TC_665_888.Q_flow; TC_666_667.Q_flow = TC_666_667.G * TC_666_667.dT; TC_666_667.dT = TC_666_667.port_a.T - TC_666_667.port_b.T; TC_666_667.port_a.Q_flow = TC_666_667.Q_flow; TC_666_667.port_b.Q_flow = -TC_666_667.Q_flow; TC_666_679.Q_flow = TC_666_679.G * TC_666_679.dT; TC_666_679.dT = TC_666_679.port_a.T - TC_666_679.port_b.T; TC_666_679.port_a.Q_flow = TC_666_679.Q_flow; TC_666_679.port_b.Q_flow = -TC_666_679.Q_flow; TC_666_889.Q_flow = TC_666_889.G * TC_666_889.dT; TC_666_889.dT = TC_666_889.port_a.T - TC_666_889.port_b.T; TC_666_889.port_a.Q_flow = TC_666_889.Q_flow; TC_666_889.port_b.Q_flow = -TC_666_889.Q_flow; TC_667_668.Q_flow = TC_667_668.G * TC_667_668.dT; TC_667_668.dT = TC_667_668.port_a.T - TC_667_668.port_b.T; TC_667_668.port_a.Q_flow = TC_667_668.Q_flow; TC_667_668.port_b.Q_flow = -TC_667_668.Q_flow; TC_667_680.Q_flow = TC_667_680.G * TC_667_680.dT; TC_667_680.dT = TC_667_680.port_a.T - TC_667_680.port_b.T; TC_667_680.port_a.Q_flow = TC_667_680.Q_flow; TC_667_680.port_b.Q_flow = -TC_667_680.Q_flow; TC_667_890.Q_flow = TC_667_890.G * TC_667_890.dT; TC_667_890.dT = TC_667_890.port_a.T - TC_667_890.port_b.T; TC_667_890.port_a.Q_flow = TC_667_890.Q_flow; TC_667_890.port_b.Q_flow = -TC_667_890.Q_flow; TC_668_669.Q_flow = TC_668_669.G * TC_668_669.dT; TC_668_669.dT = TC_668_669.port_a.T - TC_668_669.port_b.T; TC_668_669.port_a.Q_flow = TC_668_669.Q_flow; TC_668_669.port_b.Q_flow = -TC_668_669.Q_flow; TC_668_681.Q_flow = TC_668_681.G * TC_668_681.dT; TC_668_681.dT = TC_668_681.port_a.T - TC_668_681.port_b.T; TC_668_681.port_a.Q_flow = TC_668_681.Q_flow; TC_668_681.port_b.Q_flow = -TC_668_681.Q_flow; TC_668_891.Q_flow = TC_668_891.G * TC_668_891.dT; TC_668_891.dT = TC_668_891.port_a.T - TC_668_891.port_b.T; TC_668_891.port_a.Q_flow = TC_668_891.Q_flow; TC_668_891.port_b.Q_flow = -TC_668_891.Q_flow; TC_669_670.Q_flow = TC_669_670.G * TC_669_670.dT; TC_669_670.dT = TC_669_670.port_a.T - TC_669_670.port_b.T; TC_669_670.port_a.Q_flow = TC_669_670.Q_flow; TC_669_670.port_b.Q_flow = -TC_669_670.Q_flow; TC_669_682.Q_flow = TC_669_682.G * TC_669_682.dT; TC_669_682.dT = TC_669_682.port_a.T - TC_669_682.port_b.T; TC_669_682.port_a.Q_flow = TC_669_682.Q_flow; TC_669_682.port_b.Q_flow = -TC_669_682.Q_flow; TC_669_892.Q_flow = TC_669_892.G * TC_669_892.dT; TC_669_892.dT = TC_669_892.port_a.T - TC_669_892.port_b.T; TC_669_892.port_a.Q_flow = TC_669_892.Q_flow; TC_669_892.port_b.Q_flow = -TC_669_892.Q_flow; TC_670_671.Q_flow = TC_670_671.G * TC_670_671.dT; TC_670_671.dT = TC_670_671.port_a.T - TC_670_671.port_b.T; TC_670_671.port_a.Q_flow = TC_670_671.Q_flow; TC_670_671.port_b.Q_flow = -TC_670_671.Q_flow; TC_670_683.Q_flow = TC_670_683.G * TC_670_683.dT; TC_670_683.dT = TC_670_683.port_a.T - TC_670_683.port_b.T; TC_670_683.port_a.Q_flow = TC_670_683.Q_flow; TC_670_683.port_b.Q_flow = -TC_670_683.Q_flow; TC_670_893.Q_flow = TC_670_893.G * TC_670_893.dT; TC_670_893.dT = TC_670_893.port_a.T - TC_670_893.port_b.T; TC_670_893.port_a.Q_flow = TC_670_893.Q_flow; TC_670_893.port_b.Q_flow = -TC_670_893.Q_flow; TC_671_672.Q_flow = TC_671_672.G * TC_671_672.dT; TC_671_672.dT = TC_671_672.port_a.T - TC_671_672.port_b.T; TC_671_672.port_a.Q_flow = TC_671_672.Q_flow; TC_671_672.port_b.Q_flow = -TC_671_672.Q_flow; TC_671_684.Q_flow = TC_671_684.G * TC_671_684.dT; TC_671_684.dT = TC_671_684.port_a.T - TC_671_684.port_b.T; TC_671_684.port_a.Q_flow = TC_671_684.Q_flow; TC_671_684.port_b.Q_flow = -TC_671_684.Q_flow; TC_671_894.Q_flow = TC_671_894.G * TC_671_894.dT; TC_671_894.dT = TC_671_894.port_a.T - TC_671_894.port_b.T; TC_671_894.port_a.Q_flow = TC_671_894.Q_flow; TC_671_894.port_b.Q_flow = -TC_671_894.Q_flow; TC_672_673.Q_flow = TC_672_673.G * TC_672_673.dT; TC_672_673.dT = TC_672_673.port_a.T - TC_672_673.port_b.T; TC_672_673.port_a.Q_flow = TC_672_673.Q_flow; TC_672_673.port_b.Q_flow = -TC_672_673.Q_flow; TC_672_685.Q_flow = TC_672_685.G * TC_672_685.dT; TC_672_685.dT = TC_672_685.port_a.T - TC_672_685.port_b.T; TC_672_685.port_a.Q_flow = TC_672_685.Q_flow; TC_672_685.port_b.Q_flow = -TC_672_685.Q_flow; TC_672_895.Q_flow = TC_672_895.G * TC_672_895.dT; TC_672_895.dT = TC_672_895.port_a.T - TC_672_895.port_b.T; TC_672_895.port_a.Q_flow = TC_672_895.Q_flow; TC_672_895.port_b.Q_flow = -TC_672_895.Q_flow; TC_673_674.Q_flow = TC_673_674.G * TC_673_674.dT; TC_673_674.dT = TC_673_674.port_a.T - TC_673_674.port_b.T; TC_673_674.port_a.Q_flow = TC_673_674.Q_flow; TC_673_674.port_b.Q_flow = -TC_673_674.Q_flow; TC_673_686.Q_flow = TC_673_686.G * TC_673_686.dT; TC_673_686.dT = TC_673_686.port_a.T - TC_673_686.port_b.T; TC_673_686.port_a.Q_flow = TC_673_686.Q_flow; TC_673_686.port_b.Q_flow = -TC_673_686.Q_flow; TC_673_896.Q_flow = TC_673_896.G * TC_673_896.dT; TC_673_896.dT = TC_673_896.port_a.T - TC_673_896.port_b.T; TC_673_896.port_a.Q_flow = TC_673_896.Q_flow; TC_673_896.port_b.Q_flow = -TC_673_896.Q_flow; TC_674_675.Q_flow = TC_674_675.G * TC_674_675.dT; TC_674_675.dT = TC_674_675.port_a.T - TC_674_675.port_b.T; TC_674_675.port_a.Q_flow = TC_674_675.Q_flow; TC_674_675.port_b.Q_flow = -TC_674_675.Q_flow; TC_674_687.Q_flow = TC_674_687.G * TC_674_687.dT; TC_674_687.dT = TC_674_687.port_a.T - TC_674_687.port_b.T; TC_674_687.port_a.Q_flow = TC_674_687.Q_flow; TC_674_687.port_b.Q_flow = -TC_674_687.Q_flow; TC_674_897.Q_flow = TC_674_897.G * TC_674_897.dT; TC_674_897.dT = TC_674_897.port_a.T - TC_674_897.port_b.T; TC_674_897.port_a.Q_flow = TC_674_897.Q_flow; TC_674_897.port_b.Q_flow = -TC_674_897.Q_flow; TC_675_688.Q_flow = TC_675_688.G * TC_675_688.dT; TC_675_688.dT = TC_675_688.port_a.T - TC_675_688.port_b.T; TC_675_688.port_a.Q_flow = TC_675_688.Q_flow; TC_675_688.port_b.Q_flow = -TC_675_688.Q_flow; TC_676_677.Q_flow = TC_676_677.G * TC_676_677.dT; TC_676_677.dT = TC_676_677.port_a.T - TC_676_677.port_b.T; TC_676_677.port_a.Q_flow = TC_676_677.Q_flow; TC_676_677.port_b.Q_flow = -TC_676_677.Q_flow; TC_676_689.Q_flow = TC_676_689.G * TC_676_689.dT; TC_676_689.dT = TC_676_689.port_a.T - TC_676_689.port_b.T; TC_676_689.port_a.Q_flow = TC_676_689.Q_flow; TC_676_689.port_b.Q_flow = -TC_676_689.Q_flow; TC_677_678.Q_flow = TC_677_678.G * TC_677_678.dT; TC_677_678.dT = TC_677_678.port_a.T - TC_677_678.port_b.T; TC_677_678.port_a.Q_flow = TC_677_678.Q_flow; TC_677_678.port_b.Q_flow = -TC_677_678.Q_flow; TC_677_690.Q_flow = TC_677_690.G * TC_677_690.dT; TC_677_690.dT = TC_677_690.port_a.T - TC_677_690.port_b.T; TC_677_690.port_a.Q_flow = TC_677_690.Q_flow; TC_677_690.port_b.Q_flow = -TC_677_690.Q_flow; TC_677_898.Q_flow = TC_677_898.G * TC_677_898.dT; TC_677_898.dT = TC_677_898.port_a.T - TC_677_898.port_b.T; TC_677_898.port_a.Q_flow = TC_677_898.Q_flow; TC_677_898.port_b.Q_flow = -TC_677_898.Q_flow; TC_678_679.Q_flow = TC_678_679.G * TC_678_679.dT; TC_678_679.dT = TC_678_679.port_a.T - TC_678_679.port_b.T; TC_678_679.port_a.Q_flow = TC_678_679.Q_flow; TC_678_679.port_b.Q_flow = -TC_678_679.Q_flow; TC_678_691.Q_flow = TC_678_691.G * TC_678_691.dT; TC_678_691.dT = TC_678_691.port_a.T - TC_678_691.port_b.T; TC_678_691.port_a.Q_flow = TC_678_691.Q_flow; TC_678_691.port_b.Q_flow = -TC_678_691.Q_flow; TC_678_899.Q_flow = TC_678_899.G * TC_678_899.dT; TC_678_899.dT = TC_678_899.port_a.T - TC_678_899.port_b.T; TC_678_899.port_a.Q_flow = TC_678_899.Q_flow; TC_678_899.port_b.Q_flow = -TC_678_899.Q_flow; TC_679_680.Q_flow = TC_679_680.G * TC_679_680.dT; TC_679_680.dT = TC_679_680.port_a.T - TC_679_680.port_b.T; TC_679_680.port_a.Q_flow = TC_679_680.Q_flow; TC_679_680.port_b.Q_flow = -TC_679_680.Q_flow; TC_679_692.Q_flow = TC_679_692.G * TC_679_692.dT; TC_679_692.dT = TC_679_692.port_a.T - TC_679_692.port_b.T; TC_679_692.port_a.Q_flow = TC_679_692.Q_flow; TC_679_692.port_b.Q_flow = -TC_679_692.Q_flow; TC_679_900.Q_flow = TC_679_900.G * TC_679_900.dT; TC_679_900.dT = TC_679_900.port_a.T - TC_679_900.port_b.T; TC_679_900.port_a.Q_flow = TC_679_900.Q_flow; TC_679_900.port_b.Q_flow = -TC_679_900.Q_flow; TC_680_681.Q_flow = TC_680_681.G * TC_680_681.dT; TC_680_681.dT = TC_680_681.port_a.T - TC_680_681.port_b.T; TC_680_681.port_a.Q_flow = TC_680_681.Q_flow; TC_680_681.port_b.Q_flow = -TC_680_681.Q_flow; TC_680_693.Q_flow = TC_680_693.G * TC_680_693.dT; TC_680_693.dT = TC_680_693.port_a.T - TC_680_693.port_b.T; TC_680_693.port_a.Q_flow = TC_680_693.Q_flow; TC_680_693.port_b.Q_flow = -TC_680_693.Q_flow; TC_680_901.Q_flow = TC_680_901.G * TC_680_901.dT; TC_680_901.dT = TC_680_901.port_a.T - TC_680_901.port_b.T; TC_680_901.port_a.Q_flow = TC_680_901.Q_flow; TC_680_901.port_b.Q_flow = -TC_680_901.Q_flow; TC_681_682.Q_flow = TC_681_682.G * TC_681_682.dT; TC_681_682.dT = TC_681_682.port_a.T - TC_681_682.port_b.T; TC_681_682.port_a.Q_flow = TC_681_682.Q_flow; TC_681_682.port_b.Q_flow = -TC_681_682.Q_flow; TC_681_694.Q_flow = TC_681_694.G * TC_681_694.dT; TC_681_694.dT = TC_681_694.port_a.T - TC_681_694.port_b.T; TC_681_694.port_a.Q_flow = TC_681_694.Q_flow; TC_681_694.port_b.Q_flow = -TC_681_694.Q_flow; TC_681_902.Q_flow = TC_681_902.G * TC_681_902.dT; TC_681_902.dT = TC_681_902.port_a.T - TC_681_902.port_b.T; TC_681_902.port_a.Q_flow = TC_681_902.Q_flow; TC_681_902.port_b.Q_flow = -TC_681_902.Q_flow; TC_682_683.Q_flow = TC_682_683.G * TC_682_683.dT; TC_682_683.dT = TC_682_683.port_a.T - TC_682_683.port_b.T; TC_682_683.port_a.Q_flow = TC_682_683.Q_flow; TC_682_683.port_b.Q_flow = -TC_682_683.Q_flow; TC_682_695.Q_flow = TC_682_695.G * TC_682_695.dT; TC_682_695.dT = TC_682_695.port_a.T - TC_682_695.port_b.T; TC_682_695.port_a.Q_flow = TC_682_695.Q_flow; TC_682_695.port_b.Q_flow = -TC_682_695.Q_flow; TC_682_903.Q_flow = TC_682_903.G * TC_682_903.dT; TC_682_903.dT = TC_682_903.port_a.T - TC_682_903.port_b.T; TC_682_903.port_a.Q_flow = TC_682_903.Q_flow; TC_682_903.port_b.Q_flow = -TC_682_903.Q_flow; TC_683_684.Q_flow = TC_683_684.G * TC_683_684.dT; TC_683_684.dT = TC_683_684.port_a.T - TC_683_684.port_b.T; TC_683_684.port_a.Q_flow = TC_683_684.Q_flow; TC_683_684.port_b.Q_flow = -TC_683_684.Q_flow; TC_683_696.Q_flow = TC_683_696.G * TC_683_696.dT; TC_683_696.dT = TC_683_696.port_a.T - TC_683_696.port_b.T; TC_683_696.port_a.Q_flow = TC_683_696.Q_flow; TC_683_696.port_b.Q_flow = -TC_683_696.Q_flow; TC_683_904.Q_flow = TC_683_904.G * TC_683_904.dT; TC_683_904.dT = TC_683_904.port_a.T - TC_683_904.port_b.T; TC_683_904.port_a.Q_flow = TC_683_904.Q_flow; TC_683_904.port_b.Q_flow = -TC_683_904.Q_flow; TC_684_685.Q_flow = TC_684_685.G * TC_684_685.dT; TC_684_685.dT = TC_684_685.port_a.T - TC_684_685.port_b.T; TC_684_685.port_a.Q_flow = TC_684_685.Q_flow; TC_684_685.port_b.Q_flow = -TC_684_685.Q_flow; TC_684_697.Q_flow = TC_684_697.G * TC_684_697.dT; TC_684_697.dT = TC_684_697.port_a.T - TC_684_697.port_b.T; TC_684_697.port_a.Q_flow = TC_684_697.Q_flow; TC_684_697.port_b.Q_flow = -TC_684_697.Q_flow; TC_684_905.Q_flow = TC_684_905.G * TC_684_905.dT; TC_684_905.dT = TC_684_905.port_a.T - TC_684_905.port_b.T; TC_684_905.port_a.Q_flow = TC_684_905.Q_flow; TC_684_905.port_b.Q_flow = -TC_684_905.Q_flow; TC_685_686.Q_flow = TC_685_686.G * TC_685_686.dT; TC_685_686.dT = TC_685_686.port_a.T - TC_685_686.port_b.T; TC_685_686.port_a.Q_flow = TC_685_686.Q_flow; TC_685_686.port_b.Q_flow = -TC_685_686.Q_flow; TC_685_698.Q_flow = TC_685_698.G * TC_685_698.dT; TC_685_698.dT = TC_685_698.port_a.T - TC_685_698.port_b.T; TC_685_698.port_a.Q_flow = TC_685_698.Q_flow; TC_685_698.port_b.Q_flow = -TC_685_698.Q_flow; TC_685_906.Q_flow = TC_685_906.G * TC_685_906.dT; TC_685_906.dT = TC_685_906.port_a.T - TC_685_906.port_b.T; TC_685_906.port_a.Q_flow = TC_685_906.Q_flow; TC_685_906.port_b.Q_flow = -TC_685_906.Q_flow; TC_686_687.Q_flow = TC_686_687.G * TC_686_687.dT; TC_686_687.dT = TC_686_687.port_a.T - TC_686_687.port_b.T; TC_686_687.port_a.Q_flow = TC_686_687.Q_flow; TC_686_687.port_b.Q_flow = -TC_686_687.Q_flow; TC_686_699.Q_flow = TC_686_699.G * TC_686_699.dT; TC_686_699.dT = TC_686_699.port_a.T - TC_686_699.port_b.T; TC_686_699.port_a.Q_flow = TC_686_699.Q_flow; TC_686_699.port_b.Q_flow = -TC_686_699.Q_flow; TC_686_907.Q_flow = TC_686_907.G * TC_686_907.dT; TC_686_907.dT = TC_686_907.port_a.T - TC_686_907.port_b.T; TC_686_907.port_a.Q_flow = TC_686_907.Q_flow; TC_686_907.port_b.Q_flow = -TC_686_907.Q_flow; TC_687_688.Q_flow = TC_687_688.G * TC_687_688.dT; TC_687_688.dT = TC_687_688.port_a.T - TC_687_688.port_b.T; TC_687_688.port_a.Q_flow = TC_687_688.Q_flow; TC_687_688.port_b.Q_flow = -TC_687_688.Q_flow; TC_687_700.Q_flow = TC_687_700.G * TC_687_700.dT; TC_687_700.dT = TC_687_700.port_a.T - TC_687_700.port_b.T; TC_687_700.port_a.Q_flow = TC_687_700.Q_flow; TC_687_700.port_b.Q_flow = -TC_687_700.Q_flow; TC_687_908.Q_flow = TC_687_908.G * TC_687_908.dT; TC_687_908.dT = TC_687_908.port_a.T - TC_687_908.port_b.T; TC_687_908.port_a.Q_flow = TC_687_908.Q_flow; TC_687_908.port_b.Q_flow = -TC_687_908.Q_flow; TC_688_701.Q_flow = TC_688_701.G * TC_688_701.dT; TC_688_701.dT = TC_688_701.port_a.T - TC_688_701.port_b.T; TC_688_701.port_a.Q_flow = TC_688_701.Q_flow; TC_688_701.port_b.Q_flow = -TC_688_701.Q_flow; TC_689_690.Q_flow = TC_689_690.G * TC_689_690.dT; TC_689_690.dT = TC_689_690.port_a.T - TC_689_690.port_b.T; TC_689_690.port_a.Q_flow = TC_689_690.Q_flow; TC_689_690.port_b.Q_flow = -TC_689_690.Q_flow; TC_689_702.Q_flow = TC_689_702.G * TC_689_702.dT; TC_689_702.dT = TC_689_702.port_a.T - TC_689_702.port_b.T; TC_689_702.port_a.Q_flow = TC_689_702.Q_flow; TC_689_702.port_b.Q_flow = -TC_689_702.Q_flow; TC_690_691.Q_flow = TC_690_691.G * TC_690_691.dT; TC_690_691.dT = TC_690_691.port_a.T - TC_690_691.port_b.T; TC_690_691.port_a.Q_flow = TC_690_691.Q_flow; TC_690_691.port_b.Q_flow = -TC_690_691.Q_flow; TC_690_703.Q_flow = TC_690_703.G * TC_690_703.dT; TC_690_703.dT = TC_690_703.port_a.T - TC_690_703.port_b.T; TC_690_703.port_a.Q_flow = TC_690_703.Q_flow; TC_690_703.port_b.Q_flow = -TC_690_703.Q_flow; TC_690_909.Q_flow = TC_690_909.G * TC_690_909.dT; TC_690_909.dT = TC_690_909.port_a.T - TC_690_909.port_b.T; TC_690_909.port_a.Q_flow = TC_690_909.Q_flow; TC_690_909.port_b.Q_flow = -TC_690_909.Q_flow; TC_691_692.Q_flow = TC_691_692.G * TC_691_692.dT; TC_691_692.dT = TC_691_692.port_a.T - TC_691_692.port_b.T; TC_691_692.port_a.Q_flow = TC_691_692.Q_flow; TC_691_692.port_b.Q_flow = -TC_691_692.Q_flow; TC_691_704.Q_flow = TC_691_704.G * TC_691_704.dT; TC_691_704.dT = TC_691_704.port_a.T - TC_691_704.port_b.T; TC_691_704.port_a.Q_flow = TC_691_704.Q_flow; TC_691_704.port_b.Q_flow = -TC_691_704.Q_flow; TC_691_910.Q_flow = TC_691_910.G * TC_691_910.dT; TC_691_910.dT = TC_691_910.port_a.T - TC_691_910.port_b.T; TC_691_910.port_a.Q_flow = TC_691_910.Q_flow; TC_691_910.port_b.Q_flow = -TC_691_910.Q_flow; TC_692_693.Q_flow = TC_692_693.G * TC_692_693.dT; TC_692_693.dT = TC_692_693.port_a.T - TC_692_693.port_b.T; TC_692_693.port_a.Q_flow = TC_692_693.Q_flow; TC_692_693.port_b.Q_flow = -TC_692_693.Q_flow; TC_692_705.Q_flow = TC_692_705.G * TC_692_705.dT; TC_692_705.dT = TC_692_705.port_a.T - TC_692_705.port_b.T; TC_692_705.port_a.Q_flow = TC_692_705.Q_flow; TC_692_705.port_b.Q_flow = -TC_692_705.Q_flow; TC_692_911.Q_flow = TC_692_911.G * TC_692_911.dT; TC_692_911.dT = TC_692_911.port_a.T - TC_692_911.port_b.T; TC_692_911.port_a.Q_flow = TC_692_911.Q_flow; TC_692_911.port_b.Q_flow = -TC_692_911.Q_flow; TC_693_694.Q_flow = TC_693_694.G * TC_693_694.dT; TC_693_694.dT = TC_693_694.port_a.T - TC_693_694.port_b.T; TC_693_694.port_a.Q_flow = TC_693_694.Q_flow; TC_693_694.port_b.Q_flow = -TC_693_694.Q_flow; TC_693_706.Q_flow = TC_693_706.G * TC_693_706.dT; TC_693_706.dT = TC_693_706.port_a.T - TC_693_706.port_b.T; TC_693_706.port_a.Q_flow = TC_693_706.Q_flow; TC_693_706.port_b.Q_flow = -TC_693_706.Q_flow; TC_693_912.Q_flow = TC_693_912.G * TC_693_912.dT; TC_693_912.dT = TC_693_912.port_a.T - TC_693_912.port_b.T; TC_693_912.port_a.Q_flow = TC_693_912.Q_flow; TC_693_912.port_b.Q_flow = -TC_693_912.Q_flow; TC_694_695.Q_flow = TC_694_695.G * TC_694_695.dT; TC_694_695.dT = TC_694_695.port_a.T - TC_694_695.port_b.T; TC_694_695.port_a.Q_flow = TC_694_695.Q_flow; TC_694_695.port_b.Q_flow = -TC_694_695.Q_flow; TC_694_707.Q_flow = TC_694_707.G * TC_694_707.dT; TC_694_707.dT = TC_694_707.port_a.T - TC_694_707.port_b.T; TC_694_707.port_a.Q_flow = TC_694_707.Q_flow; TC_694_707.port_b.Q_flow = -TC_694_707.Q_flow; TC_694_913.Q_flow = TC_694_913.G * TC_694_913.dT; TC_694_913.dT = TC_694_913.port_a.T - TC_694_913.port_b.T; TC_694_913.port_a.Q_flow = TC_694_913.Q_flow; TC_694_913.port_b.Q_flow = -TC_694_913.Q_flow; TC_695_696.Q_flow = TC_695_696.G * TC_695_696.dT; TC_695_696.dT = TC_695_696.port_a.T - TC_695_696.port_b.T; TC_695_696.port_a.Q_flow = TC_695_696.Q_flow; TC_695_696.port_b.Q_flow = -TC_695_696.Q_flow; TC_695_708.Q_flow = TC_695_708.G * TC_695_708.dT; TC_695_708.dT = TC_695_708.port_a.T - TC_695_708.port_b.T; TC_695_708.port_a.Q_flow = TC_695_708.Q_flow; TC_695_708.port_b.Q_flow = -TC_695_708.Q_flow; TC_695_914.Q_flow = TC_695_914.G * TC_695_914.dT; TC_695_914.dT = TC_695_914.port_a.T - TC_695_914.port_b.T; TC_695_914.port_a.Q_flow = TC_695_914.Q_flow; TC_695_914.port_b.Q_flow = -TC_695_914.Q_flow; TC_696_697.Q_flow = TC_696_697.G * TC_696_697.dT; TC_696_697.dT = TC_696_697.port_a.T - TC_696_697.port_b.T; TC_696_697.port_a.Q_flow = TC_696_697.Q_flow; TC_696_697.port_b.Q_flow = -TC_696_697.Q_flow; TC_696_709.Q_flow = TC_696_709.G * TC_696_709.dT; TC_696_709.dT = TC_696_709.port_a.T - TC_696_709.port_b.T; TC_696_709.port_a.Q_flow = TC_696_709.Q_flow; TC_696_709.port_b.Q_flow = -TC_696_709.Q_flow; TC_696_915.Q_flow = TC_696_915.G * TC_696_915.dT; TC_696_915.dT = TC_696_915.port_a.T - TC_696_915.port_b.T; TC_696_915.port_a.Q_flow = TC_696_915.Q_flow; TC_696_915.port_b.Q_flow = -TC_696_915.Q_flow; TC_697_698.Q_flow = TC_697_698.G * TC_697_698.dT; TC_697_698.dT = TC_697_698.port_a.T - TC_697_698.port_b.T; TC_697_698.port_a.Q_flow = TC_697_698.Q_flow; TC_697_698.port_b.Q_flow = -TC_697_698.Q_flow; TC_697_710.Q_flow = TC_697_710.G * TC_697_710.dT; TC_697_710.dT = TC_697_710.port_a.T - TC_697_710.port_b.T; TC_697_710.port_a.Q_flow = TC_697_710.Q_flow; TC_697_710.port_b.Q_flow = -TC_697_710.Q_flow; TC_697_916.Q_flow = TC_697_916.G * TC_697_916.dT; TC_697_916.dT = TC_697_916.port_a.T - TC_697_916.port_b.T; TC_697_916.port_a.Q_flow = TC_697_916.Q_flow; TC_697_916.port_b.Q_flow = -TC_697_916.Q_flow; TC_698_699.Q_flow = TC_698_699.G * TC_698_699.dT; TC_698_699.dT = TC_698_699.port_a.T - TC_698_699.port_b.T; TC_698_699.port_a.Q_flow = TC_698_699.Q_flow; TC_698_699.port_b.Q_flow = -TC_698_699.Q_flow; TC_698_711.Q_flow = TC_698_711.G * TC_698_711.dT; TC_698_711.dT = TC_698_711.port_a.T - TC_698_711.port_b.T; TC_698_711.port_a.Q_flow = TC_698_711.Q_flow; TC_698_711.port_b.Q_flow = -TC_698_711.Q_flow; TC_698_917.Q_flow = TC_698_917.G * TC_698_917.dT; TC_698_917.dT = TC_698_917.port_a.T - TC_698_917.port_b.T; TC_698_917.port_a.Q_flow = TC_698_917.Q_flow; TC_698_917.port_b.Q_flow = -TC_698_917.Q_flow; TC_699_700.Q_flow = TC_699_700.G * TC_699_700.dT; TC_699_700.dT = TC_699_700.port_a.T - TC_699_700.port_b.T; TC_699_700.port_a.Q_flow = TC_699_700.Q_flow; TC_699_700.port_b.Q_flow = -TC_699_700.Q_flow; TC_699_712.Q_flow = TC_699_712.G * TC_699_712.dT; TC_699_712.dT = TC_699_712.port_a.T - TC_699_712.port_b.T; TC_699_712.port_a.Q_flow = TC_699_712.Q_flow; TC_699_712.port_b.Q_flow = -TC_699_712.Q_flow; TC_699_918.Q_flow = TC_699_918.G * TC_699_918.dT; TC_699_918.dT = TC_699_918.port_a.T - TC_699_918.port_b.T; TC_699_918.port_a.Q_flow = TC_699_918.Q_flow; TC_699_918.port_b.Q_flow = -TC_699_918.Q_flow; TC_700_701.Q_flow = TC_700_701.G * TC_700_701.dT; TC_700_701.dT = TC_700_701.port_a.T - TC_700_701.port_b.T; TC_700_701.port_a.Q_flow = TC_700_701.Q_flow; TC_700_701.port_b.Q_flow = -TC_700_701.Q_flow; TC_700_713.Q_flow = TC_700_713.G * TC_700_713.dT; TC_700_713.dT = TC_700_713.port_a.T - TC_700_713.port_b.T; TC_700_713.port_a.Q_flow = TC_700_713.Q_flow; TC_700_713.port_b.Q_flow = -TC_700_713.Q_flow; TC_700_919.Q_flow = TC_700_919.G * TC_700_919.dT; TC_700_919.dT = TC_700_919.port_a.T - TC_700_919.port_b.T; TC_700_919.port_a.Q_flow = TC_700_919.Q_flow; TC_700_919.port_b.Q_flow = -TC_700_919.Q_flow; TC_701_714.Q_flow = TC_701_714.G * TC_701_714.dT; TC_701_714.dT = TC_701_714.port_a.T - TC_701_714.port_b.T; TC_701_714.port_a.Q_flow = TC_701_714.Q_flow; TC_701_714.port_b.Q_flow = -TC_701_714.Q_flow; TC_702_703.Q_flow = TC_702_703.G * TC_702_703.dT; TC_702_703.dT = TC_702_703.port_a.T - TC_702_703.port_b.T; TC_702_703.port_a.Q_flow = TC_702_703.Q_flow; TC_702_703.port_b.Q_flow = -TC_702_703.Q_flow; TC_702_715.Q_flow = TC_702_715.G * TC_702_715.dT; TC_702_715.dT = TC_702_715.port_a.T - TC_702_715.port_b.T; TC_702_715.port_a.Q_flow = TC_702_715.Q_flow; TC_702_715.port_b.Q_flow = -TC_702_715.Q_flow; TC_703_704.Q_flow = TC_703_704.G * TC_703_704.dT; TC_703_704.dT = TC_703_704.port_a.T - TC_703_704.port_b.T; TC_703_704.port_a.Q_flow = TC_703_704.Q_flow; TC_703_704.port_b.Q_flow = -TC_703_704.Q_flow; TC_703_716.Q_flow = TC_703_716.G * TC_703_716.dT; TC_703_716.dT = TC_703_716.port_a.T - TC_703_716.port_b.T; TC_703_716.port_a.Q_flow = TC_703_716.Q_flow; TC_703_716.port_b.Q_flow = -TC_703_716.Q_flow; TC_703_832.Q_flow = TC_703_832.G * TC_703_832.dT; TC_703_832.dT = TC_703_832.port_a.T - TC_703_832.port_b.T; TC_703_832.port_a.Q_flow = TC_703_832.Q_flow; TC_703_832.port_b.Q_flow = -TC_703_832.Q_flow; TC_704_705.Q_flow = TC_704_705.G * TC_704_705.dT; TC_704_705.dT = TC_704_705.port_a.T - TC_704_705.port_b.T; TC_704_705.port_a.Q_flow = TC_704_705.Q_flow; TC_704_705.port_b.Q_flow = -TC_704_705.Q_flow; TC_704_717.Q_flow = TC_704_717.G * TC_704_717.dT; TC_704_717.dT = TC_704_717.port_a.T - TC_704_717.port_b.T; TC_704_717.port_a.Q_flow = TC_704_717.Q_flow; TC_704_717.port_b.Q_flow = -TC_704_717.Q_flow; TC_704_833.Q_flow = TC_704_833.G * TC_704_833.dT; TC_704_833.dT = TC_704_833.port_a.T - TC_704_833.port_b.T; TC_704_833.port_a.Q_flow = TC_704_833.Q_flow; TC_704_833.port_b.Q_flow = -TC_704_833.Q_flow; TC_705_706.Q_flow = TC_705_706.G * TC_705_706.dT; TC_705_706.dT = TC_705_706.port_a.T - TC_705_706.port_b.T; TC_705_706.port_a.Q_flow = TC_705_706.Q_flow; TC_705_706.port_b.Q_flow = -TC_705_706.Q_flow; TC_705_718.Q_flow = TC_705_718.G * TC_705_718.dT; TC_705_718.dT = TC_705_718.port_a.T - TC_705_718.port_b.T; TC_705_718.port_a.Q_flow = TC_705_718.Q_flow; TC_705_718.port_b.Q_flow = -TC_705_718.Q_flow; TC_705_834.Q_flow = TC_705_834.G * TC_705_834.dT; TC_705_834.dT = TC_705_834.port_a.T - TC_705_834.port_b.T; TC_705_834.port_a.Q_flow = TC_705_834.Q_flow; TC_705_834.port_b.Q_flow = -TC_705_834.Q_flow; TC_706_707.Q_flow = TC_706_707.G * TC_706_707.dT; TC_706_707.dT = TC_706_707.port_a.T - TC_706_707.port_b.T; TC_706_707.port_a.Q_flow = TC_706_707.Q_flow; TC_706_707.port_b.Q_flow = -TC_706_707.Q_flow; TC_706_719.Q_flow = TC_706_719.G * TC_706_719.dT; TC_706_719.dT = TC_706_719.port_a.T - TC_706_719.port_b.T; TC_706_719.port_a.Q_flow = TC_706_719.Q_flow; TC_706_719.port_b.Q_flow = -TC_706_719.Q_flow; TC_706_835.Q_flow = TC_706_835.G * TC_706_835.dT; TC_706_835.dT = TC_706_835.port_a.T - TC_706_835.port_b.T; TC_706_835.port_a.Q_flow = TC_706_835.Q_flow; TC_706_835.port_b.Q_flow = -TC_706_835.Q_flow; TC_707_708.Q_flow = TC_707_708.G * TC_707_708.dT; TC_707_708.dT = TC_707_708.port_a.T - TC_707_708.port_b.T; TC_707_708.port_a.Q_flow = TC_707_708.Q_flow; TC_707_708.port_b.Q_flow = -TC_707_708.Q_flow; TC_707_720.Q_flow = TC_707_720.G * TC_707_720.dT; TC_707_720.dT = TC_707_720.port_a.T - TC_707_720.port_b.T; TC_707_720.port_a.Q_flow = TC_707_720.Q_flow; TC_707_720.port_b.Q_flow = -TC_707_720.Q_flow; TC_707_836.Q_flow = TC_707_836.G * TC_707_836.dT; TC_707_836.dT = TC_707_836.port_a.T - TC_707_836.port_b.T; TC_707_836.port_a.Q_flow = TC_707_836.Q_flow; TC_707_836.port_b.Q_flow = -TC_707_836.Q_flow; TC_708_709.Q_flow = TC_708_709.G * TC_708_709.dT; TC_708_709.dT = TC_708_709.port_a.T - TC_708_709.port_b.T; TC_708_709.port_a.Q_flow = TC_708_709.Q_flow; TC_708_709.port_b.Q_flow = -TC_708_709.Q_flow; TC_708_721.Q_flow = TC_708_721.G * TC_708_721.dT; TC_708_721.dT = TC_708_721.port_a.T - TC_708_721.port_b.T; TC_708_721.port_a.Q_flow = TC_708_721.Q_flow; TC_708_721.port_b.Q_flow = -TC_708_721.Q_flow; TC_708_837.Q_flow = TC_708_837.G * TC_708_837.dT; TC_708_837.dT = TC_708_837.port_a.T - TC_708_837.port_b.T; TC_708_837.port_a.Q_flow = TC_708_837.Q_flow; TC_708_837.port_b.Q_flow = -TC_708_837.Q_flow; TC_709_710.Q_flow = TC_709_710.G * TC_709_710.dT; TC_709_710.dT = TC_709_710.port_a.T - TC_709_710.port_b.T; TC_709_710.port_a.Q_flow = TC_709_710.Q_flow; TC_709_710.port_b.Q_flow = -TC_709_710.Q_flow; TC_709_722.Q_flow = TC_709_722.G * TC_709_722.dT; TC_709_722.dT = TC_709_722.port_a.T - TC_709_722.port_b.T; TC_709_722.port_a.Q_flow = TC_709_722.Q_flow; TC_709_722.port_b.Q_flow = -TC_709_722.Q_flow; TC_709_838.Q_flow = TC_709_838.G * TC_709_838.dT; TC_709_838.dT = TC_709_838.port_a.T - TC_709_838.port_b.T; TC_709_838.port_a.Q_flow = TC_709_838.Q_flow; TC_709_838.port_b.Q_flow = -TC_709_838.Q_flow; TC_710_711.Q_flow = TC_710_711.G * TC_710_711.dT; TC_710_711.dT = TC_710_711.port_a.T - TC_710_711.port_b.T; TC_710_711.port_a.Q_flow = TC_710_711.Q_flow; TC_710_711.port_b.Q_flow = -TC_710_711.Q_flow; TC_710_723.Q_flow = TC_710_723.G * TC_710_723.dT; TC_710_723.dT = TC_710_723.port_a.T - TC_710_723.port_b.T; TC_710_723.port_a.Q_flow = TC_710_723.Q_flow; TC_710_723.port_b.Q_flow = -TC_710_723.Q_flow; TC_710_839.Q_flow = TC_710_839.G * TC_710_839.dT; TC_710_839.dT = TC_710_839.port_a.T - TC_710_839.port_b.T; TC_710_839.port_a.Q_flow = TC_710_839.Q_flow; TC_710_839.port_b.Q_flow = -TC_710_839.Q_flow; TC_711_712.Q_flow = TC_711_712.G * TC_711_712.dT; TC_711_712.dT = TC_711_712.port_a.T - TC_711_712.port_b.T; TC_711_712.port_a.Q_flow = TC_711_712.Q_flow; TC_711_712.port_b.Q_flow = -TC_711_712.Q_flow; TC_711_724.Q_flow = TC_711_724.G * TC_711_724.dT; TC_711_724.dT = TC_711_724.port_a.T - TC_711_724.port_b.T; TC_711_724.port_a.Q_flow = TC_711_724.Q_flow; TC_711_724.port_b.Q_flow = -TC_711_724.Q_flow; TC_711_840.Q_flow = TC_711_840.G * TC_711_840.dT; TC_711_840.dT = TC_711_840.port_a.T - TC_711_840.port_b.T; TC_711_840.port_a.Q_flow = TC_711_840.Q_flow; TC_711_840.port_b.Q_flow = -TC_711_840.Q_flow; TC_712_713.Q_flow = TC_712_713.G * TC_712_713.dT; TC_712_713.dT = TC_712_713.port_a.T - TC_712_713.port_b.T; TC_712_713.port_a.Q_flow = TC_712_713.Q_flow; TC_712_713.port_b.Q_flow = -TC_712_713.Q_flow; TC_712_725.Q_flow = TC_712_725.G * TC_712_725.dT; TC_712_725.dT = TC_712_725.port_a.T - TC_712_725.port_b.T; TC_712_725.port_a.Q_flow = TC_712_725.Q_flow; TC_712_725.port_b.Q_flow = -TC_712_725.Q_flow; TC_712_841.Q_flow = TC_712_841.G * TC_712_841.dT; TC_712_841.dT = TC_712_841.port_a.T - TC_712_841.port_b.T; TC_712_841.port_a.Q_flow = TC_712_841.Q_flow; TC_712_841.port_b.Q_flow = -TC_712_841.Q_flow; TC_713_714.Q_flow = TC_713_714.G * TC_713_714.dT; TC_713_714.dT = TC_713_714.port_a.T - TC_713_714.port_b.T; TC_713_714.port_a.Q_flow = TC_713_714.Q_flow; TC_713_714.port_b.Q_flow = -TC_713_714.Q_flow; TC_713_726.Q_flow = TC_713_726.G * TC_713_726.dT; TC_713_726.dT = TC_713_726.port_a.T - TC_713_726.port_b.T; TC_713_726.port_a.Q_flow = TC_713_726.Q_flow; TC_713_726.port_b.Q_flow = -TC_713_726.Q_flow; TC_713_842.Q_flow = TC_713_842.G * TC_713_842.dT; TC_713_842.dT = TC_713_842.port_a.T - TC_713_842.port_b.T; TC_713_842.port_a.Q_flow = TC_713_842.Q_flow; TC_713_842.port_b.Q_flow = -TC_713_842.Q_flow; TC_714_727.Q_flow = TC_714_727.G * TC_714_727.dT; TC_714_727.dT = TC_714_727.port_a.T - TC_714_727.port_b.T; TC_714_727.port_a.Q_flow = TC_714_727.Q_flow; TC_714_727.port_b.Q_flow = -TC_714_727.Q_flow; TC_715_716.Q_flow = TC_715_716.G * TC_715_716.dT; TC_715_716.dT = TC_715_716.port_a.T - TC_715_716.port_b.T; TC_715_716.port_a.Q_flow = TC_715_716.Q_flow; TC_715_716.port_b.Q_flow = -TC_715_716.Q_flow; TC_715_728.Q_flow = TC_715_728.G * TC_715_728.dT; TC_715_728.dT = TC_715_728.port_a.T - TC_715_728.port_b.T; TC_715_728.port_a.Q_flow = TC_715_728.Q_flow; TC_715_728.port_b.Q_flow = -TC_715_728.Q_flow; TC_716_717.Q_flow = TC_716_717.G * TC_716_717.dT; TC_716_717.dT = TC_716_717.port_a.T - TC_716_717.port_b.T; TC_716_717.port_a.Q_flow = TC_716_717.Q_flow; TC_716_717.port_b.Q_flow = -TC_716_717.Q_flow; TC_716_729.Q_flow = TC_716_729.G * TC_716_729.dT; TC_716_729.dT = TC_716_729.port_a.T - TC_716_729.port_b.T; TC_716_729.port_a.Q_flow = TC_716_729.Q_flow; TC_716_729.port_b.Q_flow = -TC_716_729.Q_flow; TC_716_821.Q_flow = TC_716_821.G * TC_716_821.dT; TC_716_821.dT = TC_716_821.port_a.T - TC_716_821.port_b.T; TC_716_821.port_a.Q_flow = TC_716_821.Q_flow; TC_716_821.port_b.Q_flow = -TC_716_821.Q_flow; TC_717_718.Q_flow = TC_717_718.G * TC_717_718.dT; TC_717_718.dT = TC_717_718.port_a.T - TC_717_718.port_b.T; TC_717_718.port_a.Q_flow = TC_717_718.Q_flow; TC_717_718.port_b.Q_flow = -TC_717_718.Q_flow; TC_717_730.Q_flow = TC_717_730.G * TC_717_730.dT; TC_717_730.dT = TC_717_730.port_a.T - TC_717_730.port_b.T; TC_717_730.port_a.Q_flow = TC_717_730.Q_flow; TC_717_730.port_b.Q_flow = -TC_717_730.Q_flow; TC_717_822.Q_flow = TC_717_822.G * TC_717_822.dT; TC_717_822.dT = TC_717_822.port_a.T - TC_717_822.port_b.T; TC_717_822.port_a.Q_flow = TC_717_822.Q_flow; TC_717_822.port_b.Q_flow = -TC_717_822.Q_flow; TC_718_719.Q_flow = TC_718_719.G * TC_718_719.dT; TC_718_719.dT = TC_718_719.port_a.T - TC_718_719.port_b.T; TC_718_719.port_a.Q_flow = TC_718_719.Q_flow; TC_718_719.port_b.Q_flow = -TC_718_719.Q_flow; TC_718_731.Q_flow = TC_718_731.G * TC_718_731.dT; TC_718_731.dT = TC_718_731.port_a.T - TC_718_731.port_b.T; TC_718_731.port_a.Q_flow = TC_718_731.Q_flow; TC_718_731.port_b.Q_flow = -TC_718_731.Q_flow; TC_718_823.Q_flow = TC_718_823.G * TC_718_823.dT; TC_718_823.dT = TC_718_823.port_a.T - TC_718_823.port_b.T; TC_718_823.port_a.Q_flow = TC_718_823.Q_flow; TC_718_823.port_b.Q_flow = -TC_718_823.Q_flow; TC_719_720.Q_flow = TC_719_720.G * TC_719_720.dT; TC_719_720.dT = TC_719_720.port_a.T - TC_719_720.port_b.T; TC_719_720.port_a.Q_flow = TC_719_720.Q_flow; TC_719_720.port_b.Q_flow = -TC_719_720.Q_flow; TC_719_732.Q_flow = TC_719_732.G * TC_719_732.dT; TC_719_732.dT = TC_719_732.port_a.T - TC_719_732.port_b.T; TC_719_732.port_a.Q_flow = TC_719_732.Q_flow; TC_719_732.port_b.Q_flow = -TC_719_732.Q_flow; TC_719_824.Q_flow = TC_719_824.G * TC_719_824.dT; TC_719_824.dT = TC_719_824.port_a.T - TC_719_824.port_b.T; TC_719_824.port_a.Q_flow = TC_719_824.Q_flow; TC_719_824.port_b.Q_flow = -TC_719_824.Q_flow; TC_720_721.Q_flow = TC_720_721.G * TC_720_721.dT; TC_720_721.dT = TC_720_721.port_a.T - TC_720_721.port_b.T; TC_720_721.port_a.Q_flow = TC_720_721.Q_flow; TC_720_721.port_b.Q_flow = -TC_720_721.Q_flow; TC_720_733.Q_flow = TC_720_733.G * TC_720_733.dT; TC_720_733.dT = TC_720_733.port_a.T - TC_720_733.port_b.T; TC_720_733.port_a.Q_flow = TC_720_733.Q_flow; TC_720_733.port_b.Q_flow = -TC_720_733.Q_flow; TC_720_825.Q_flow = TC_720_825.G * TC_720_825.dT; TC_720_825.dT = TC_720_825.port_a.T - TC_720_825.port_b.T; TC_720_825.port_a.Q_flow = TC_720_825.Q_flow; TC_720_825.port_b.Q_flow = -TC_720_825.Q_flow; TC_721_722.Q_flow = TC_721_722.G * TC_721_722.dT; TC_721_722.dT = TC_721_722.port_a.T - TC_721_722.port_b.T; TC_721_722.port_a.Q_flow = TC_721_722.Q_flow; TC_721_722.port_b.Q_flow = -TC_721_722.Q_flow; TC_721_734.Q_flow = TC_721_734.G * TC_721_734.dT; TC_721_734.dT = TC_721_734.port_a.T - TC_721_734.port_b.T; TC_721_734.port_a.Q_flow = TC_721_734.Q_flow; TC_721_734.port_b.Q_flow = -TC_721_734.Q_flow; TC_721_826.Q_flow = TC_721_826.G * TC_721_826.dT; TC_721_826.dT = TC_721_826.port_a.T - TC_721_826.port_b.T; TC_721_826.port_a.Q_flow = TC_721_826.Q_flow; TC_721_826.port_b.Q_flow = -TC_721_826.Q_flow; TC_722_723.Q_flow = TC_722_723.G * TC_722_723.dT; TC_722_723.dT = TC_722_723.port_a.T - TC_722_723.port_b.T; TC_722_723.port_a.Q_flow = TC_722_723.Q_flow; TC_722_723.port_b.Q_flow = -TC_722_723.Q_flow; TC_722_735.Q_flow = TC_722_735.G * TC_722_735.dT; TC_722_735.dT = TC_722_735.port_a.T - TC_722_735.port_b.T; TC_722_735.port_a.Q_flow = TC_722_735.Q_flow; TC_722_735.port_b.Q_flow = -TC_722_735.Q_flow; TC_722_827.Q_flow = TC_722_827.G * TC_722_827.dT; TC_722_827.dT = TC_722_827.port_a.T - TC_722_827.port_b.T; TC_722_827.port_a.Q_flow = TC_722_827.Q_flow; TC_722_827.port_b.Q_flow = -TC_722_827.Q_flow; TC_723_724.Q_flow = TC_723_724.G * TC_723_724.dT; TC_723_724.dT = TC_723_724.port_a.T - TC_723_724.port_b.T; TC_723_724.port_a.Q_flow = TC_723_724.Q_flow; TC_723_724.port_b.Q_flow = -TC_723_724.Q_flow; TC_723_736.Q_flow = TC_723_736.G * TC_723_736.dT; TC_723_736.dT = TC_723_736.port_a.T - TC_723_736.port_b.T; TC_723_736.port_a.Q_flow = TC_723_736.Q_flow; TC_723_736.port_b.Q_flow = -TC_723_736.Q_flow; TC_723_828.Q_flow = TC_723_828.G * TC_723_828.dT; TC_723_828.dT = TC_723_828.port_a.T - TC_723_828.port_b.T; TC_723_828.port_a.Q_flow = TC_723_828.Q_flow; TC_723_828.port_b.Q_flow = -TC_723_828.Q_flow; TC_724_725.Q_flow = TC_724_725.G * TC_724_725.dT; TC_724_725.dT = TC_724_725.port_a.T - TC_724_725.port_b.T; TC_724_725.port_a.Q_flow = TC_724_725.Q_flow; TC_724_725.port_b.Q_flow = -TC_724_725.Q_flow; TC_724_737.Q_flow = TC_724_737.G * TC_724_737.dT; TC_724_737.dT = TC_724_737.port_a.T - TC_724_737.port_b.T; TC_724_737.port_a.Q_flow = TC_724_737.Q_flow; TC_724_737.port_b.Q_flow = -TC_724_737.Q_flow; TC_724_829.Q_flow = TC_724_829.G * TC_724_829.dT; TC_724_829.dT = TC_724_829.port_a.T - TC_724_829.port_b.T; TC_724_829.port_a.Q_flow = TC_724_829.Q_flow; TC_724_829.port_b.Q_flow = -TC_724_829.Q_flow; TC_725_726.Q_flow = TC_725_726.G * TC_725_726.dT; TC_725_726.dT = TC_725_726.port_a.T - TC_725_726.port_b.T; TC_725_726.port_a.Q_flow = TC_725_726.Q_flow; TC_725_726.port_b.Q_flow = -TC_725_726.Q_flow; TC_725_738.Q_flow = TC_725_738.G * TC_725_738.dT; TC_725_738.dT = TC_725_738.port_a.T - TC_725_738.port_b.T; TC_725_738.port_a.Q_flow = TC_725_738.Q_flow; TC_725_738.port_b.Q_flow = -TC_725_738.Q_flow; TC_725_830.Q_flow = TC_725_830.G * TC_725_830.dT; TC_725_830.dT = TC_725_830.port_a.T - TC_725_830.port_b.T; TC_725_830.port_a.Q_flow = TC_725_830.Q_flow; TC_725_830.port_b.Q_flow = -TC_725_830.Q_flow; TC_726_727.Q_flow = TC_726_727.G * TC_726_727.dT; TC_726_727.dT = TC_726_727.port_a.T - TC_726_727.port_b.T; TC_726_727.port_a.Q_flow = TC_726_727.Q_flow; TC_726_727.port_b.Q_flow = -TC_726_727.Q_flow; TC_726_739.Q_flow = TC_726_739.G * TC_726_739.dT; TC_726_739.dT = TC_726_739.port_a.T - TC_726_739.port_b.T; TC_726_739.port_a.Q_flow = TC_726_739.Q_flow; TC_726_739.port_b.Q_flow = -TC_726_739.Q_flow; TC_726_831.Q_flow = TC_726_831.G * TC_726_831.dT; TC_726_831.dT = TC_726_831.port_a.T - TC_726_831.port_b.T; TC_726_831.port_a.Q_flow = TC_726_831.Q_flow; TC_726_831.port_b.Q_flow = -TC_726_831.Q_flow; TC_727_740.Q_flow = TC_727_740.G * TC_727_740.dT; TC_727_740.dT = TC_727_740.port_a.T - TC_727_740.port_b.T; TC_727_740.port_a.Q_flow = TC_727_740.Q_flow; TC_727_740.port_b.Q_flow = -TC_727_740.Q_flow; TC_728_729.Q_flow = TC_728_729.G * TC_728_729.dT; TC_728_729.dT = TC_728_729.port_a.T - TC_728_729.port_b.T; TC_728_729.port_a.Q_flow = TC_728_729.Q_flow; TC_728_729.port_b.Q_flow = -TC_728_729.Q_flow; TC_729_730.Q_flow = TC_729_730.G * TC_729_730.dT; TC_729_730.dT = TC_729_730.port_a.T - TC_729_730.port_b.T; TC_729_730.port_a.Q_flow = TC_729_730.Q_flow; TC_729_730.port_b.Q_flow = -TC_729_730.Q_flow; TC_730_731.Q_flow = TC_730_731.G * TC_730_731.dT; TC_730_731.dT = TC_730_731.port_a.T - TC_730_731.port_b.T; TC_730_731.port_a.Q_flow = TC_730_731.Q_flow; TC_730_731.port_b.Q_flow = -TC_730_731.Q_flow; TC_731_732.Q_flow = TC_731_732.G * TC_731_732.dT; TC_731_732.dT = TC_731_732.port_a.T - TC_731_732.port_b.T; TC_731_732.port_a.Q_flow = TC_731_732.Q_flow; TC_731_732.port_b.Q_flow = -TC_731_732.Q_flow; TC_732_733.Q_flow = TC_732_733.G * TC_732_733.dT; TC_732_733.dT = TC_732_733.port_a.T - TC_732_733.port_b.T; TC_732_733.port_a.Q_flow = TC_732_733.Q_flow; TC_732_733.port_b.Q_flow = -TC_732_733.Q_flow; TC_733_734.Q_flow = TC_733_734.G * TC_733_734.dT; TC_733_734.dT = TC_733_734.port_a.T - TC_733_734.port_b.T; TC_733_734.port_a.Q_flow = TC_733_734.Q_flow; TC_733_734.port_b.Q_flow = -TC_733_734.Q_flow; TC_734_735.Q_flow = TC_734_735.G * TC_734_735.dT; TC_734_735.dT = TC_734_735.port_a.T - TC_734_735.port_b.T; TC_734_735.port_a.Q_flow = TC_734_735.Q_flow; TC_734_735.port_b.Q_flow = -TC_734_735.Q_flow; TC_735_736.Q_flow = TC_735_736.G * TC_735_736.dT; TC_735_736.dT = TC_735_736.port_a.T - TC_735_736.port_b.T; TC_735_736.port_a.Q_flow = TC_735_736.Q_flow; TC_735_736.port_b.Q_flow = -TC_735_736.Q_flow; TC_736_737.Q_flow = TC_736_737.G * TC_736_737.dT; TC_736_737.dT = TC_736_737.port_a.T - TC_736_737.port_b.T; TC_736_737.port_a.Q_flow = TC_736_737.Q_flow; TC_736_737.port_b.Q_flow = -TC_736_737.Q_flow; TC_737_738.Q_flow = TC_737_738.G * TC_737_738.dT; TC_737_738.dT = TC_737_738.port_a.T - TC_737_738.port_b.T; TC_737_738.port_a.Q_flow = TC_737_738.Q_flow; TC_737_738.port_b.Q_flow = -TC_737_738.Q_flow; TC_738_739.Q_flow = TC_738_739.G * TC_738_739.dT; TC_738_739.dT = TC_738_739.port_a.T - TC_738_739.port_b.T; TC_738_739.port_a.Q_flow = TC_738_739.Q_flow; TC_738_739.port_b.Q_flow = -TC_738_739.Q_flow; TC_739_740.Q_flow = TC_739_740.G * TC_739_740.dT; TC_739_740.dT = TC_739_740.port_a.T - TC_739_740.port_b.T; TC_739_740.port_a.Q_flow = TC_739_740.Q_flow; TC_739_740.port_b.Q_flow = -TC_739_740.Q_flow; TC_741_742.Q_flow = TC_741_742.G * TC_741_742.dT; TC_741_742.dT = TC_741_742.port_a.T - TC_741_742.port_b.T; TC_741_742.port_a.Q_flow = TC_741_742.Q_flow; TC_741_742.port_b.Q_flow = -TC_741_742.Q_flow; TC_741_749.Q_flow = TC_741_749.G * TC_741_749.dT; TC_741_749.dT = TC_741_749.port_a.T - TC_741_749.port_b.T; TC_741_749.port_a.Q_flow = TC_741_749.Q_flow; TC_741_749.port_b.Q_flow = -TC_741_749.Q_flow; TC_741_813.Q_flow = TC_741_813.G * TC_741_813.dT; TC_741_813.dT = TC_741_813.port_a.T - TC_741_813.port_b.T; TC_741_813.port_a.Q_flow = TC_741_813.Q_flow; TC_741_813.port_b.Q_flow = -TC_741_813.Q_flow; TC_741_1304.Q_flow = TC_741_1304.G * TC_741_1304.dT; TC_741_1304.dT = TC_741_1304.port_a.T - TC_741_1304.port_b.T; TC_741_1304.port_a.Q_flow = TC_741_1304.Q_flow; TC_741_1304.port_b.Q_flow = -TC_741_1304.Q_flow; TC_741_1465.Q_flow = TC_741_1465.G * TC_741_1465.dT; TC_741_1465.dT = TC_741_1465.port_a.T - TC_741_1465.port_b.T; TC_741_1465.port_a.Q_flow = TC_741_1465.Q_flow; TC_741_1465.port_b.Q_flow = -TC_741_1465.Q_flow; TC_742_743.Q_flow = TC_742_743.G * TC_742_743.dT; TC_742_743.dT = TC_742_743.port_a.T - TC_742_743.port_b.T; TC_742_743.port_a.Q_flow = TC_742_743.Q_flow; TC_742_743.port_b.Q_flow = -TC_742_743.Q_flow; TC_742_750.Q_flow = TC_742_750.G * TC_742_750.dT; TC_742_750.dT = TC_742_750.port_a.T - TC_742_750.port_b.T; TC_742_750.port_a.Q_flow = TC_742_750.Q_flow; TC_742_750.port_b.Q_flow = -TC_742_750.Q_flow; TC_742_814.Q_flow = TC_742_814.G * TC_742_814.dT; TC_742_814.dT = TC_742_814.port_a.T - TC_742_814.port_b.T; TC_742_814.port_a.Q_flow = TC_742_814.Q_flow; TC_742_814.port_b.Q_flow = -TC_742_814.Q_flow; TC_742_1305.Q_flow = TC_742_1305.G * TC_742_1305.dT; TC_742_1305.dT = TC_742_1305.port_a.T - TC_742_1305.port_b.T; TC_742_1305.port_a.Q_flow = TC_742_1305.Q_flow; TC_742_1305.port_b.Q_flow = -TC_742_1305.Q_flow; TC_743_744.Q_flow = TC_743_744.G * TC_743_744.dT; TC_743_744.dT = TC_743_744.port_a.T - TC_743_744.port_b.T; TC_743_744.port_a.Q_flow = TC_743_744.Q_flow; TC_743_744.port_b.Q_flow = -TC_743_744.Q_flow; TC_743_751.Q_flow = TC_743_751.G * TC_743_751.dT; TC_743_751.dT = TC_743_751.port_a.T - TC_743_751.port_b.T; TC_743_751.port_a.Q_flow = TC_743_751.Q_flow; TC_743_751.port_b.Q_flow = -TC_743_751.Q_flow; TC_743_815.Q_flow = TC_743_815.G * TC_743_815.dT; TC_743_815.dT = TC_743_815.port_a.T - TC_743_815.port_b.T; TC_743_815.port_a.Q_flow = TC_743_815.Q_flow; TC_743_815.port_b.Q_flow = -TC_743_815.Q_flow; TC_743_1306.Q_flow = TC_743_1306.G * TC_743_1306.dT; TC_743_1306.dT = TC_743_1306.port_a.T - TC_743_1306.port_b.T; TC_743_1306.port_a.Q_flow = TC_743_1306.Q_flow; TC_743_1306.port_b.Q_flow = -TC_743_1306.Q_flow; TC_744_745.Q_flow = TC_744_745.G * TC_744_745.dT; TC_744_745.dT = TC_744_745.port_a.T - TC_744_745.port_b.T; TC_744_745.port_a.Q_flow = TC_744_745.Q_flow; TC_744_745.port_b.Q_flow = -TC_744_745.Q_flow; TC_744_752.Q_flow = TC_744_752.G * TC_744_752.dT; TC_744_752.dT = TC_744_752.port_a.T - TC_744_752.port_b.T; TC_744_752.port_a.Q_flow = TC_744_752.Q_flow; TC_744_752.port_b.Q_flow = -TC_744_752.Q_flow; TC_744_816.Q_flow = TC_744_816.G * TC_744_816.dT; TC_744_816.dT = TC_744_816.port_a.T - TC_744_816.port_b.T; TC_744_816.port_a.Q_flow = TC_744_816.Q_flow; TC_744_816.port_b.Q_flow = -TC_744_816.Q_flow; TC_744_1307.Q_flow = TC_744_1307.G * TC_744_1307.dT; TC_744_1307.dT = TC_744_1307.port_a.T - TC_744_1307.port_b.T; TC_744_1307.port_a.Q_flow = TC_744_1307.Q_flow; TC_744_1307.port_b.Q_flow = -TC_744_1307.Q_flow; TC_745_746.Q_flow = TC_745_746.G * TC_745_746.dT; TC_745_746.dT = TC_745_746.port_a.T - TC_745_746.port_b.T; TC_745_746.port_a.Q_flow = TC_745_746.Q_flow; TC_745_746.port_b.Q_flow = -TC_745_746.Q_flow; TC_745_753.Q_flow = TC_745_753.G * TC_745_753.dT; TC_745_753.dT = TC_745_753.port_a.T - TC_745_753.port_b.T; TC_745_753.port_a.Q_flow = TC_745_753.Q_flow; TC_745_753.port_b.Q_flow = -TC_745_753.Q_flow; TC_745_817.Q_flow = TC_745_817.G * TC_745_817.dT; TC_745_817.dT = TC_745_817.port_a.T - TC_745_817.port_b.T; TC_745_817.port_a.Q_flow = TC_745_817.Q_flow; TC_745_817.port_b.Q_flow = -TC_745_817.Q_flow; TC_745_1308.Q_flow = TC_745_1308.G * TC_745_1308.dT; TC_745_1308.dT = TC_745_1308.port_a.T - TC_745_1308.port_b.T; TC_745_1308.port_a.Q_flow = TC_745_1308.Q_flow; TC_745_1308.port_b.Q_flow = -TC_745_1308.Q_flow; TC_746_747.Q_flow = TC_746_747.G * TC_746_747.dT; TC_746_747.dT = TC_746_747.port_a.T - TC_746_747.port_b.T; TC_746_747.port_a.Q_flow = TC_746_747.Q_flow; TC_746_747.port_b.Q_flow = -TC_746_747.Q_flow; TC_746_754.Q_flow = TC_746_754.G * TC_746_754.dT; TC_746_754.dT = TC_746_754.port_a.T - TC_746_754.port_b.T; TC_746_754.port_a.Q_flow = TC_746_754.Q_flow; TC_746_754.port_b.Q_flow = -TC_746_754.Q_flow; TC_746_818.Q_flow = TC_746_818.G * TC_746_818.dT; TC_746_818.dT = TC_746_818.port_a.T - TC_746_818.port_b.T; TC_746_818.port_a.Q_flow = TC_746_818.Q_flow; TC_746_818.port_b.Q_flow = -TC_746_818.Q_flow; TC_746_1309.Q_flow = TC_746_1309.G * TC_746_1309.dT; TC_746_1309.dT = TC_746_1309.port_a.T - TC_746_1309.port_b.T; TC_746_1309.port_a.Q_flow = TC_746_1309.Q_flow; TC_746_1309.port_b.Q_flow = -TC_746_1309.Q_flow; TC_747_748.Q_flow = TC_747_748.G * TC_747_748.dT; TC_747_748.dT = TC_747_748.port_a.T - TC_747_748.port_b.T; TC_747_748.port_a.Q_flow = TC_747_748.Q_flow; TC_747_748.port_b.Q_flow = -TC_747_748.Q_flow; TC_747_755.Q_flow = TC_747_755.G * TC_747_755.dT; TC_747_755.dT = TC_747_755.port_a.T - TC_747_755.port_b.T; TC_747_755.port_a.Q_flow = TC_747_755.Q_flow; TC_747_755.port_b.Q_flow = -TC_747_755.Q_flow; TC_747_819.Q_flow = TC_747_819.G * TC_747_819.dT; TC_747_819.dT = TC_747_819.port_a.T - TC_747_819.port_b.T; TC_747_819.port_a.Q_flow = TC_747_819.Q_flow; TC_747_819.port_b.Q_flow = -TC_747_819.Q_flow; TC_747_1310.Q_flow = TC_747_1310.G * TC_747_1310.dT; TC_747_1310.dT = TC_747_1310.port_a.T - TC_747_1310.port_b.T; TC_747_1310.port_a.Q_flow = TC_747_1310.Q_flow; TC_747_1310.port_b.Q_flow = -TC_747_1310.Q_flow; TC_748_756.Q_flow = TC_748_756.G * TC_748_756.dT; TC_748_756.dT = TC_748_756.port_a.T - TC_748_756.port_b.T; TC_748_756.port_a.Q_flow = TC_748_756.Q_flow; TC_748_756.port_b.Q_flow = -TC_748_756.Q_flow; TC_748_820.Q_flow = TC_748_820.G * TC_748_820.dT; TC_748_820.dT = TC_748_820.port_a.T - TC_748_820.port_b.T; TC_748_820.port_a.Q_flow = TC_748_820.Q_flow; TC_748_820.port_b.Q_flow = -TC_748_820.Q_flow; TC_748_1311.Q_flow = TC_748_1311.G * TC_748_1311.dT; TC_748_1311.dT = TC_748_1311.port_a.T - TC_748_1311.port_b.T; TC_748_1311.port_a.Q_flow = TC_748_1311.Q_flow; TC_748_1311.port_b.Q_flow = -TC_748_1311.Q_flow; TC_748_1414.Q_flow = TC_748_1414.G * TC_748_1414.dT; TC_748_1414.dT = TC_748_1414.port_a.T - TC_748_1414.port_b.T; TC_748_1414.port_a.Q_flow = TC_748_1414.Q_flow; TC_748_1414.port_b.Q_flow = -TC_748_1414.Q_flow; TC_749_750.Q_flow = TC_749_750.G * TC_749_750.dT; TC_749_750.dT = TC_749_750.port_a.T - TC_749_750.port_b.T; TC_749_750.port_a.Q_flow = TC_749_750.Q_flow; TC_749_750.port_b.Q_flow = -TC_749_750.Q_flow; TC_749_757.Q_flow = TC_749_757.G * TC_749_757.dT; TC_749_757.dT = TC_749_757.port_a.T - TC_749_757.port_b.T; TC_749_757.port_a.Q_flow = TC_749_757.Q_flow; TC_749_757.port_b.Q_flow = -TC_749_757.Q_flow; TC_749_1315.Q_flow = TC_749_1315.G * TC_749_1315.dT; TC_749_1315.dT = TC_749_1315.port_a.T - TC_749_1315.port_b.T; TC_749_1315.port_a.Q_flow = TC_749_1315.Q_flow; TC_749_1315.port_b.Q_flow = -TC_749_1315.Q_flow; TC_749_1416.Q_flow = TC_749_1416.G * TC_749_1416.dT; TC_749_1416.dT = TC_749_1416.port_a.T - TC_749_1416.port_b.T; TC_749_1416.port_a.Q_flow = TC_749_1416.Q_flow; TC_749_1416.port_b.Q_flow = -TC_749_1416.Q_flow; TC_750_751.Q_flow = TC_750_751.G * TC_750_751.dT; TC_750_751.dT = TC_750_751.port_a.T - TC_750_751.port_b.T; TC_750_751.port_a.Q_flow = TC_750_751.Q_flow; TC_750_751.port_b.Q_flow = -TC_750_751.Q_flow; TC_750_758.Q_flow = TC_750_758.G * TC_750_758.dT; TC_750_758.dT = TC_750_758.port_a.T - TC_750_758.port_b.T; TC_750_758.port_a.Q_flow = TC_750_758.Q_flow; TC_750_758.port_b.Q_flow = -TC_750_758.Q_flow; TC_750_1316.Q_flow = TC_750_1316.G * TC_750_1316.dT; TC_750_1316.dT = TC_750_1316.port_a.T - TC_750_1316.port_b.T; TC_750_1316.port_a.Q_flow = TC_750_1316.Q_flow; TC_750_1316.port_b.Q_flow = -TC_750_1316.Q_flow; TC_751_752.Q_flow = TC_751_752.G * TC_751_752.dT; TC_751_752.dT = TC_751_752.port_a.T - TC_751_752.port_b.T; TC_751_752.port_a.Q_flow = TC_751_752.Q_flow; TC_751_752.port_b.Q_flow = -TC_751_752.Q_flow; TC_751_759.Q_flow = TC_751_759.G * TC_751_759.dT; TC_751_759.dT = TC_751_759.port_a.T - TC_751_759.port_b.T; TC_751_759.port_a.Q_flow = TC_751_759.Q_flow; TC_751_759.port_b.Q_flow = -TC_751_759.Q_flow; TC_751_1317.Q_flow = TC_751_1317.G * TC_751_1317.dT; TC_751_1317.dT = TC_751_1317.port_a.T - TC_751_1317.port_b.T; TC_751_1317.port_a.Q_flow = TC_751_1317.Q_flow; TC_751_1317.port_b.Q_flow = -TC_751_1317.Q_flow; TC_752_753.Q_flow = TC_752_753.G * TC_752_753.dT; TC_752_753.dT = TC_752_753.port_a.T - TC_752_753.port_b.T; TC_752_753.port_a.Q_flow = TC_752_753.Q_flow; TC_752_753.port_b.Q_flow = -TC_752_753.Q_flow; TC_752_760.Q_flow = TC_752_760.G * TC_752_760.dT; TC_752_760.dT = TC_752_760.port_a.T - TC_752_760.port_b.T; TC_752_760.port_a.Q_flow = TC_752_760.Q_flow; TC_752_760.port_b.Q_flow = -TC_752_760.Q_flow; TC_752_1318.Q_flow = TC_752_1318.G * TC_752_1318.dT; TC_752_1318.dT = TC_752_1318.port_a.T - TC_752_1318.port_b.T; TC_752_1318.port_a.Q_flow = TC_752_1318.Q_flow; TC_752_1318.port_b.Q_flow = -TC_752_1318.Q_flow; TC_753_754.Q_flow = TC_753_754.G * TC_753_754.dT; TC_753_754.dT = TC_753_754.port_a.T - TC_753_754.port_b.T; TC_753_754.port_a.Q_flow = TC_753_754.Q_flow; TC_753_754.port_b.Q_flow = -TC_753_754.Q_flow; TC_753_761.Q_flow = TC_753_761.G * TC_753_761.dT; TC_753_761.dT = TC_753_761.port_a.T - TC_753_761.port_b.T; TC_753_761.port_a.Q_flow = TC_753_761.Q_flow; TC_753_761.port_b.Q_flow = -TC_753_761.Q_flow; TC_753_1319.Q_flow = TC_753_1319.G * TC_753_1319.dT; TC_753_1319.dT = TC_753_1319.port_a.T - TC_753_1319.port_b.T; TC_753_1319.port_a.Q_flow = TC_753_1319.Q_flow; TC_753_1319.port_b.Q_flow = -TC_753_1319.Q_flow; TC_754_755.Q_flow = TC_754_755.G * TC_754_755.dT; TC_754_755.dT = TC_754_755.port_a.T - TC_754_755.port_b.T; TC_754_755.port_a.Q_flow = TC_754_755.Q_flow; TC_754_755.port_b.Q_flow = -TC_754_755.Q_flow; TC_754_762.Q_flow = TC_754_762.G * TC_754_762.dT; TC_754_762.dT = TC_754_762.port_a.T - TC_754_762.port_b.T; TC_754_762.port_a.Q_flow = TC_754_762.Q_flow; TC_754_762.port_b.Q_flow = -TC_754_762.Q_flow; TC_754_1320.Q_flow = TC_754_1320.G * TC_754_1320.dT; TC_754_1320.dT = TC_754_1320.port_a.T - TC_754_1320.port_b.T; TC_754_1320.port_a.Q_flow = TC_754_1320.Q_flow; TC_754_1320.port_b.Q_flow = -TC_754_1320.Q_flow; TC_755_756.Q_flow = TC_755_756.G * TC_755_756.dT; TC_755_756.dT = TC_755_756.port_a.T - TC_755_756.port_b.T; TC_755_756.port_a.Q_flow = TC_755_756.Q_flow; TC_755_756.port_b.Q_flow = -TC_755_756.Q_flow; TC_755_763.Q_flow = TC_755_763.G * TC_755_763.dT; TC_755_763.dT = TC_755_763.port_a.T - TC_755_763.port_b.T; TC_755_763.port_a.Q_flow = TC_755_763.Q_flow; TC_755_763.port_b.Q_flow = -TC_755_763.Q_flow; TC_755_1321.Q_flow = TC_755_1321.G * TC_755_1321.dT; TC_755_1321.dT = TC_755_1321.port_a.T - TC_755_1321.port_b.T; TC_755_1321.port_a.Q_flow = TC_755_1321.Q_flow; TC_755_1321.port_b.Q_flow = -TC_755_1321.Q_flow; TC_756_764.Q_flow = TC_756_764.G * TC_756_764.dT; TC_756_764.dT = TC_756_764.port_a.T - TC_756_764.port_b.T; TC_756_764.port_a.Q_flow = TC_756_764.Q_flow; TC_756_764.port_b.Q_flow = -TC_756_764.Q_flow; TC_756_1322.Q_flow = TC_756_1322.G * TC_756_1322.dT; TC_756_1322.dT = TC_756_1322.port_a.T - TC_756_1322.port_b.T; TC_756_1322.port_a.Q_flow = TC_756_1322.Q_flow; TC_756_1322.port_b.Q_flow = -TC_756_1322.Q_flow; TC_756_1417.Q_flow = TC_756_1417.G * TC_756_1417.dT; TC_756_1417.dT = TC_756_1417.port_a.T - TC_756_1417.port_b.T; TC_756_1417.port_a.Q_flow = TC_756_1417.Q_flow; TC_756_1417.port_b.Q_flow = -TC_756_1417.Q_flow; TC_757_758.Q_flow = TC_757_758.G * TC_757_758.dT; TC_757_758.dT = TC_757_758.port_a.T - TC_757_758.port_b.T; TC_757_758.port_a.Q_flow = TC_757_758.Q_flow; TC_757_758.port_b.Q_flow = -TC_757_758.Q_flow; TC_757_765.Q_flow = TC_757_765.G * TC_757_765.dT; TC_757_765.dT = TC_757_765.port_a.T - TC_757_765.port_b.T; TC_757_765.port_a.Q_flow = TC_757_765.Q_flow; TC_757_765.port_b.Q_flow = -TC_757_765.Q_flow; TC_757_1326.Q_flow = TC_757_1326.G * TC_757_1326.dT; TC_757_1326.dT = TC_757_1326.port_a.T - TC_757_1326.port_b.T; TC_757_1326.port_a.Q_flow = TC_757_1326.Q_flow; TC_757_1326.port_b.Q_flow = -TC_757_1326.Q_flow; TC_757_1419.Q_flow = TC_757_1419.G * TC_757_1419.dT; TC_757_1419.dT = TC_757_1419.port_a.T - TC_757_1419.port_b.T; TC_757_1419.port_a.Q_flow = TC_757_1419.Q_flow; TC_757_1419.port_b.Q_flow = -TC_757_1419.Q_flow; TC_758_759.Q_flow = TC_758_759.G * TC_758_759.dT; TC_758_759.dT = TC_758_759.port_a.T - TC_758_759.port_b.T; TC_758_759.port_a.Q_flow = TC_758_759.Q_flow; TC_758_759.port_b.Q_flow = -TC_758_759.Q_flow; TC_758_766.Q_flow = TC_758_766.G * TC_758_766.dT; TC_758_766.dT = TC_758_766.port_a.T - TC_758_766.port_b.T; TC_758_766.port_a.Q_flow = TC_758_766.Q_flow; TC_758_766.port_b.Q_flow = -TC_758_766.Q_flow; TC_758_1327.Q_flow = TC_758_1327.G * TC_758_1327.dT; TC_758_1327.dT = TC_758_1327.port_a.T - TC_758_1327.port_b.T; TC_758_1327.port_a.Q_flow = TC_758_1327.Q_flow; TC_758_1327.port_b.Q_flow = -TC_758_1327.Q_flow; TC_759_760.Q_flow = TC_759_760.G * TC_759_760.dT; TC_759_760.dT = TC_759_760.port_a.T - TC_759_760.port_b.T; TC_759_760.port_a.Q_flow = TC_759_760.Q_flow; TC_759_760.port_b.Q_flow = -TC_759_760.Q_flow; TC_759_767.Q_flow = TC_759_767.G * TC_759_767.dT; TC_759_767.dT = TC_759_767.port_a.T - TC_759_767.port_b.T; TC_759_767.port_a.Q_flow = TC_759_767.Q_flow; TC_759_767.port_b.Q_flow = -TC_759_767.Q_flow; TC_759_1328.Q_flow = TC_759_1328.G * TC_759_1328.dT; TC_759_1328.dT = TC_759_1328.port_a.T - TC_759_1328.port_b.T; TC_759_1328.port_a.Q_flow = TC_759_1328.Q_flow; TC_759_1328.port_b.Q_flow = -TC_759_1328.Q_flow; TC_760_761.Q_flow = TC_760_761.G * TC_760_761.dT; TC_760_761.dT = TC_760_761.port_a.T - TC_760_761.port_b.T; TC_760_761.port_a.Q_flow = TC_760_761.Q_flow; TC_760_761.port_b.Q_flow = -TC_760_761.Q_flow; TC_760_768.Q_flow = TC_760_768.G * TC_760_768.dT; TC_760_768.dT = TC_760_768.port_a.T - TC_760_768.port_b.T; TC_760_768.port_a.Q_flow = TC_760_768.Q_flow; TC_760_768.port_b.Q_flow = -TC_760_768.Q_flow; TC_760_1329.Q_flow = TC_760_1329.G * TC_760_1329.dT; TC_760_1329.dT = TC_760_1329.port_a.T - TC_760_1329.port_b.T; TC_760_1329.port_a.Q_flow = TC_760_1329.Q_flow; TC_760_1329.port_b.Q_flow = -TC_760_1329.Q_flow; TC_761_762.Q_flow = TC_761_762.G * TC_761_762.dT; TC_761_762.dT = TC_761_762.port_a.T - TC_761_762.port_b.T; TC_761_762.port_a.Q_flow = TC_761_762.Q_flow; TC_761_762.port_b.Q_flow = -TC_761_762.Q_flow; TC_761_769.Q_flow = TC_761_769.G * TC_761_769.dT; TC_761_769.dT = TC_761_769.port_a.T - TC_761_769.port_b.T; TC_761_769.port_a.Q_flow = TC_761_769.Q_flow; TC_761_769.port_b.Q_flow = -TC_761_769.Q_flow; TC_761_1330.Q_flow = TC_761_1330.G * TC_761_1330.dT; TC_761_1330.dT = TC_761_1330.port_a.T - TC_761_1330.port_b.T; TC_761_1330.port_a.Q_flow = TC_761_1330.Q_flow; TC_761_1330.port_b.Q_flow = -TC_761_1330.Q_flow; TC_762_763.Q_flow = TC_762_763.G * TC_762_763.dT; TC_762_763.dT = TC_762_763.port_a.T - TC_762_763.port_b.T; TC_762_763.port_a.Q_flow = TC_762_763.Q_flow; TC_762_763.port_b.Q_flow = -TC_762_763.Q_flow; TC_762_770.Q_flow = TC_762_770.G * TC_762_770.dT; TC_762_770.dT = TC_762_770.port_a.T - TC_762_770.port_b.T; TC_762_770.port_a.Q_flow = TC_762_770.Q_flow; TC_762_770.port_b.Q_flow = -TC_762_770.Q_flow; TC_762_1331.Q_flow = TC_762_1331.G * TC_762_1331.dT; TC_762_1331.dT = TC_762_1331.port_a.T - TC_762_1331.port_b.T; TC_762_1331.port_a.Q_flow = TC_762_1331.Q_flow; TC_762_1331.port_b.Q_flow = -TC_762_1331.Q_flow; TC_763_764.Q_flow = TC_763_764.G * TC_763_764.dT; TC_763_764.dT = TC_763_764.port_a.T - TC_763_764.port_b.T; TC_763_764.port_a.Q_flow = TC_763_764.Q_flow; TC_763_764.port_b.Q_flow = -TC_763_764.Q_flow; TC_763_771.Q_flow = TC_763_771.G * TC_763_771.dT; TC_763_771.dT = TC_763_771.port_a.T - TC_763_771.port_b.T; TC_763_771.port_a.Q_flow = TC_763_771.Q_flow; TC_763_771.port_b.Q_flow = -TC_763_771.Q_flow; TC_763_1332.Q_flow = TC_763_1332.G * TC_763_1332.dT; TC_763_1332.dT = TC_763_1332.port_a.T - TC_763_1332.port_b.T; TC_763_1332.port_a.Q_flow = TC_763_1332.Q_flow; TC_763_1332.port_b.Q_flow = -TC_763_1332.Q_flow; TC_764_772.Q_flow = TC_764_772.G * TC_764_772.dT; TC_764_772.dT = TC_764_772.port_a.T - TC_764_772.port_b.T; TC_764_772.port_a.Q_flow = TC_764_772.Q_flow; TC_764_772.port_b.Q_flow = -TC_764_772.Q_flow; TC_764_1333.Q_flow = TC_764_1333.G * TC_764_1333.dT; TC_764_1333.dT = TC_764_1333.port_a.T - TC_764_1333.port_b.T; TC_764_1333.port_a.Q_flow = TC_764_1333.Q_flow; TC_764_1333.port_b.Q_flow = -TC_764_1333.Q_flow; TC_764_1420.Q_flow = TC_764_1420.G * TC_764_1420.dT; TC_764_1420.dT = TC_764_1420.port_a.T - TC_764_1420.port_b.T; TC_764_1420.port_a.Q_flow = TC_764_1420.Q_flow; TC_764_1420.port_b.Q_flow = -TC_764_1420.Q_flow; TC_765_766.Q_flow = TC_765_766.G * TC_765_766.dT; TC_765_766.dT = TC_765_766.port_a.T - TC_765_766.port_b.T; TC_765_766.port_a.Q_flow = TC_765_766.Q_flow; TC_765_766.port_b.Q_flow = -TC_765_766.Q_flow; TC_765_773.Q_flow = TC_765_773.G * TC_765_773.dT; TC_765_773.dT = TC_765_773.port_a.T - TC_765_773.port_b.T; TC_765_773.port_a.Q_flow = TC_765_773.Q_flow; TC_765_773.port_b.Q_flow = -TC_765_773.Q_flow; TC_765_1337.Q_flow = TC_765_1337.G * TC_765_1337.dT; TC_765_1337.dT = TC_765_1337.port_a.T - TC_765_1337.port_b.T; TC_765_1337.port_a.Q_flow = TC_765_1337.Q_flow; TC_765_1337.port_b.Q_flow = -TC_765_1337.Q_flow; TC_765_1422.Q_flow = TC_765_1422.G * TC_765_1422.dT; TC_765_1422.dT = TC_765_1422.port_a.T - TC_765_1422.port_b.T; TC_765_1422.port_a.Q_flow = TC_765_1422.Q_flow; TC_765_1422.port_b.Q_flow = -TC_765_1422.Q_flow; TC_766_767.Q_flow = TC_766_767.G * TC_766_767.dT; TC_766_767.dT = TC_766_767.port_a.T - TC_766_767.port_b.T; TC_766_767.port_a.Q_flow = TC_766_767.Q_flow; TC_766_767.port_b.Q_flow = -TC_766_767.Q_flow; TC_766_774.Q_flow = TC_766_774.G * TC_766_774.dT; TC_766_774.dT = TC_766_774.port_a.T - TC_766_774.port_b.T; TC_766_774.port_a.Q_flow = TC_766_774.Q_flow; TC_766_774.port_b.Q_flow = -TC_766_774.Q_flow; TC_766_1338.Q_flow = TC_766_1338.G * TC_766_1338.dT; TC_766_1338.dT = TC_766_1338.port_a.T - TC_766_1338.port_b.T; TC_766_1338.port_a.Q_flow = TC_766_1338.Q_flow; TC_766_1338.port_b.Q_flow = -TC_766_1338.Q_flow; TC_767_768.Q_flow = TC_767_768.G * TC_767_768.dT; TC_767_768.dT = TC_767_768.port_a.T - TC_767_768.port_b.T; TC_767_768.port_a.Q_flow = TC_767_768.Q_flow; TC_767_768.port_b.Q_flow = -TC_767_768.Q_flow; TC_767_775.Q_flow = TC_767_775.G * TC_767_775.dT; TC_767_775.dT = TC_767_775.port_a.T - TC_767_775.port_b.T; TC_767_775.port_a.Q_flow = TC_767_775.Q_flow; TC_767_775.port_b.Q_flow = -TC_767_775.Q_flow; TC_767_1339.Q_flow = TC_767_1339.G * TC_767_1339.dT; TC_767_1339.dT = TC_767_1339.port_a.T - TC_767_1339.port_b.T; TC_767_1339.port_a.Q_flow = TC_767_1339.Q_flow; TC_767_1339.port_b.Q_flow = -TC_767_1339.Q_flow; TC_768_769.Q_flow = TC_768_769.G * TC_768_769.dT; TC_768_769.dT = TC_768_769.port_a.T - TC_768_769.port_b.T; TC_768_769.port_a.Q_flow = TC_768_769.Q_flow; TC_768_769.port_b.Q_flow = -TC_768_769.Q_flow; TC_768_776.Q_flow = TC_768_776.G * TC_768_776.dT; TC_768_776.dT = TC_768_776.port_a.T - TC_768_776.port_b.T; TC_768_776.port_a.Q_flow = TC_768_776.Q_flow; TC_768_776.port_b.Q_flow = -TC_768_776.Q_flow; TC_768_1340.Q_flow = TC_768_1340.G * TC_768_1340.dT; TC_768_1340.dT = TC_768_1340.port_a.T - TC_768_1340.port_b.T; TC_768_1340.port_a.Q_flow = TC_768_1340.Q_flow; TC_768_1340.port_b.Q_flow = -TC_768_1340.Q_flow; TC_769_770.Q_flow = TC_769_770.G * TC_769_770.dT; TC_769_770.dT = TC_769_770.port_a.T - TC_769_770.port_b.T; TC_769_770.port_a.Q_flow = TC_769_770.Q_flow; TC_769_770.port_b.Q_flow = -TC_769_770.Q_flow; TC_769_777.Q_flow = TC_769_777.G * TC_769_777.dT; TC_769_777.dT = TC_769_777.port_a.T - TC_769_777.port_b.T; TC_769_777.port_a.Q_flow = TC_769_777.Q_flow; TC_769_777.port_b.Q_flow = -TC_769_777.Q_flow; TC_769_1488.Q_flow = TC_769_1488.G * TC_769_1488.dT; TC_769_1488.dT = TC_769_1488.port_a.T - TC_769_1488.port_b.T; TC_769_1488.port_a.Q_flow = TC_769_1488.Q_flow; TC_769_1488.port_b.Q_flow = -TC_769_1488.Q_flow; TC_770_771.Q_flow = TC_770_771.G * TC_770_771.dT; TC_770_771.dT = TC_770_771.port_a.T - TC_770_771.port_b.T; TC_770_771.port_a.Q_flow = TC_770_771.Q_flow; TC_770_771.port_b.Q_flow = -TC_770_771.Q_flow; TC_770_778.Q_flow = TC_770_778.G * TC_770_778.dT; TC_770_778.dT = TC_770_778.port_a.T - TC_770_778.port_b.T; TC_770_778.port_a.Q_flow = TC_770_778.Q_flow; TC_770_778.port_b.Q_flow = -TC_770_778.Q_flow; TC_770_1489.Q_flow = TC_770_1489.G * TC_770_1489.dT; TC_770_1489.dT = TC_770_1489.port_a.T - TC_770_1489.port_b.T; TC_770_1489.port_a.Q_flow = TC_770_1489.Q_flow; TC_770_1489.port_b.Q_flow = -TC_770_1489.Q_flow; TC_771_772.Q_flow = TC_771_772.G * TC_771_772.dT; TC_771_772.dT = TC_771_772.port_a.T - TC_771_772.port_b.T; TC_771_772.port_a.Q_flow = TC_771_772.Q_flow; TC_771_772.port_b.Q_flow = -TC_771_772.Q_flow; TC_771_779.Q_flow = TC_771_779.G * TC_771_779.dT; TC_771_779.dT = TC_771_779.port_a.T - TC_771_779.port_b.T; TC_771_779.port_a.Q_flow = TC_771_779.Q_flow; TC_771_779.port_b.Q_flow = -TC_771_779.Q_flow; TC_771_1490.Q_flow = TC_771_1490.G * TC_771_1490.dT; TC_771_1490.dT = TC_771_1490.port_a.T - TC_771_1490.port_b.T; TC_771_1490.port_a.Q_flow = TC_771_1490.Q_flow; TC_771_1490.port_b.Q_flow = -TC_771_1490.Q_flow; TC_772_780.Q_flow = TC_772_780.G * TC_772_780.dT; TC_772_780.dT = TC_772_780.port_a.T - TC_772_780.port_b.T; TC_772_780.port_a.Q_flow = TC_772_780.Q_flow; TC_772_780.port_b.Q_flow = -TC_772_780.Q_flow; TC_772_1341.Q_flow = TC_772_1341.G * TC_772_1341.dT; TC_772_1341.dT = TC_772_1341.port_a.T - TC_772_1341.port_b.T; TC_772_1341.port_a.Q_flow = TC_772_1341.Q_flow; TC_772_1341.port_b.Q_flow = -TC_772_1341.Q_flow; TC_772_1423.Q_flow = TC_772_1423.G * TC_772_1423.dT; TC_772_1423.dT = TC_772_1423.port_a.T - TC_772_1423.port_b.T; TC_772_1423.port_a.Q_flow = TC_772_1423.Q_flow; TC_772_1423.port_b.Q_flow = -TC_772_1423.Q_flow; TC_773_774.Q_flow = TC_773_774.G * TC_773_774.dT; TC_773_774.dT = TC_773_774.port_a.T - TC_773_774.port_b.T; TC_773_774.port_a.Q_flow = TC_773_774.Q_flow; TC_773_774.port_b.Q_flow = -TC_773_774.Q_flow; TC_773_781.Q_flow = TC_773_781.G * TC_773_781.dT; TC_773_781.dT = TC_773_781.port_a.T - TC_773_781.port_b.T; TC_773_781.port_a.Q_flow = TC_773_781.Q_flow; TC_773_781.port_b.Q_flow = -TC_773_781.Q_flow; TC_773_1345.Q_flow = TC_773_1345.G * TC_773_1345.dT; TC_773_1345.dT = TC_773_1345.port_a.T - TC_773_1345.port_b.T; TC_773_1345.port_a.Q_flow = TC_773_1345.Q_flow; TC_773_1345.port_b.Q_flow = -TC_773_1345.Q_flow; TC_773_1425.Q_flow = TC_773_1425.G * TC_773_1425.dT; TC_773_1425.dT = TC_773_1425.port_a.T - TC_773_1425.port_b.T; TC_773_1425.port_a.Q_flow = TC_773_1425.Q_flow; TC_773_1425.port_b.Q_flow = -TC_773_1425.Q_flow; TC_774_775.Q_flow = TC_774_775.G * TC_774_775.dT; TC_774_775.dT = TC_774_775.port_a.T - TC_774_775.port_b.T; TC_774_775.port_a.Q_flow = TC_774_775.Q_flow; TC_774_775.port_b.Q_flow = -TC_774_775.Q_flow; TC_774_782.Q_flow = TC_774_782.G * TC_774_782.dT; TC_774_782.dT = TC_774_782.port_a.T - TC_774_782.port_b.T; TC_774_782.port_a.Q_flow = TC_774_782.Q_flow; TC_774_782.port_b.Q_flow = -TC_774_782.Q_flow; TC_774_1346.Q_flow = TC_774_1346.G * TC_774_1346.dT; TC_774_1346.dT = TC_774_1346.port_a.T - TC_774_1346.port_b.T; TC_774_1346.port_a.Q_flow = TC_774_1346.Q_flow; TC_774_1346.port_b.Q_flow = -TC_774_1346.Q_flow; TC_775_776.Q_flow = TC_775_776.G * TC_775_776.dT; TC_775_776.dT = TC_775_776.port_a.T - TC_775_776.port_b.T; TC_775_776.port_a.Q_flow = TC_775_776.Q_flow; TC_775_776.port_b.Q_flow = -TC_775_776.Q_flow; TC_775_783.Q_flow = TC_775_783.G * TC_775_783.dT; TC_775_783.dT = TC_775_783.port_a.T - TC_775_783.port_b.T; TC_775_783.port_a.Q_flow = TC_775_783.Q_flow; TC_775_783.port_b.Q_flow = -TC_775_783.Q_flow; TC_775_1347.Q_flow = TC_775_1347.G * TC_775_1347.dT; TC_775_1347.dT = TC_775_1347.port_a.T - TC_775_1347.port_b.T; TC_775_1347.port_a.Q_flow = TC_775_1347.Q_flow; TC_775_1347.port_b.Q_flow = -TC_775_1347.Q_flow; TC_776_777.Q_flow = TC_776_777.G * TC_776_777.dT; TC_776_777.dT = TC_776_777.port_a.T - TC_776_777.port_b.T; TC_776_777.port_a.Q_flow = TC_776_777.Q_flow; TC_776_777.port_b.Q_flow = -TC_776_777.Q_flow; TC_776_784.Q_flow = TC_776_784.G * TC_776_784.dT; TC_776_784.dT = TC_776_784.port_a.T - TC_776_784.port_b.T; TC_776_784.port_a.Q_flow = TC_776_784.Q_flow; TC_776_784.port_b.Q_flow = -TC_776_784.Q_flow; TC_776_1348.Q_flow = TC_776_1348.G * TC_776_1348.dT; TC_776_1348.dT = TC_776_1348.port_a.T - TC_776_1348.port_b.T; TC_776_1348.port_a.Q_flow = TC_776_1348.Q_flow; TC_776_1348.port_b.Q_flow = -TC_776_1348.Q_flow; TC_777_778.Q_flow = TC_777_778.G * TC_777_778.dT; TC_777_778.dT = TC_777_778.port_a.T - TC_777_778.port_b.T; TC_777_778.port_a.Q_flow = TC_777_778.Q_flow; TC_777_778.port_b.Q_flow = -TC_777_778.Q_flow; TC_777_785.Q_flow = TC_777_785.G * TC_777_785.dT; TC_777_785.dT = TC_777_785.port_a.T - TC_777_785.port_b.T; TC_777_785.port_a.Q_flow = TC_777_785.Q_flow; TC_777_785.port_b.Q_flow = -TC_777_785.Q_flow; TC_777_1491.Q_flow = TC_777_1491.G * TC_777_1491.dT; TC_777_1491.dT = TC_777_1491.port_a.T - TC_777_1491.port_b.T; TC_777_1491.port_a.Q_flow = TC_777_1491.Q_flow; TC_777_1491.port_b.Q_flow = -TC_777_1491.Q_flow; TC_778_779.Q_flow = TC_778_779.G * TC_778_779.dT; TC_778_779.dT = TC_778_779.port_a.T - TC_778_779.port_b.T; TC_778_779.port_a.Q_flow = TC_778_779.Q_flow; TC_778_779.port_b.Q_flow = -TC_778_779.Q_flow; TC_778_786.Q_flow = TC_778_786.G * TC_778_786.dT; TC_778_786.dT = TC_778_786.port_a.T - TC_778_786.port_b.T; TC_778_786.port_a.Q_flow = TC_778_786.Q_flow; TC_778_786.port_b.Q_flow = -TC_778_786.Q_flow; TC_778_1492.Q_flow = TC_778_1492.G * TC_778_1492.dT; TC_778_1492.dT = TC_778_1492.port_a.T - TC_778_1492.port_b.T; TC_778_1492.port_a.Q_flow = TC_778_1492.Q_flow; TC_778_1492.port_b.Q_flow = -TC_778_1492.Q_flow; TC_779_780.Q_flow = TC_779_780.G * TC_779_780.dT; TC_779_780.dT = TC_779_780.port_a.T - TC_779_780.port_b.T; TC_779_780.port_a.Q_flow = TC_779_780.Q_flow; TC_779_780.port_b.Q_flow = -TC_779_780.Q_flow; TC_779_787.Q_flow = TC_779_787.G * TC_779_787.dT; TC_779_787.dT = TC_779_787.port_a.T - TC_779_787.port_b.T; TC_779_787.port_a.Q_flow = TC_779_787.Q_flow; TC_779_787.port_b.Q_flow = -TC_779_787.Q_flow; TC_779_1493.Q_flow = TC_779_1493.G * TC_779_1493.dT; TC_779_1493.dT = TC_779_1493.port_a.T - TC_779_1493.port_b.T; TC_779_1493.port_a.Q_flow = TC_779_1493.Q_flow; TC_779_1493.port_b.Q_flow = -TC_779_1493.Q_flow; TC_780_788.Q_flow = TC_780_788.G * TC_780_788.dT; TC_780_788.dT = TC_780_788.port_a.T - TC_780_788.port_b.T; TC_780_788.port_a.Q_flow = TC_780_788.Q_flow; TC_780_788.port_b.Q_flow = -TC_780_788.Q_flow; TC_780_1349.Q_flow = TC_780_1349.G * TC_780_1349.dT; TC_780_1349.dT = TC_780_1349.port_a.T - TC_780_1349.port_b.T; TC_780_1349.port_a.Q_flow = TC_780_1349.Q_flow; TC_780_1349.port_b.Q_flow = -TC_780_1349.Q_flow; TC_780_1426.Q_flow = TC_780_1426.G * TC_780_1426.dT; TC_780_1426.dT = TC_780_1426.port_a.T - TC_780_1426.port_b.T; TC_780_1426.port_a.Q_flow = TC_780_1426.Q_flow; TC_780_1426.port_b.Q_flow = -TC_780_1426.Q_flow; TC_781_782.Q_flow = TC_781_782.G * TC_781_782.dT; TC_781_782.dT = TC_781_782.port_a.T - TC_781_782.port_b.T; TC_781_782.port_a.Q_flow = TC_781_782.Q_flow; TC_781_782.port_b.Q_flow = -TC_781_782.Q_flow; TC_781_789.Q_flow = TC_781_789.G * TC_781_789.dT; TC_781_789.dT = TC_781_789.port_a.T - TC_781_789.port_b.T; TC_781_789.port_a.Q_flow = TC_781_789.Q_flow; TC_781_789.port_b.Q_flow = -TC_781_789.Q_flow; TC_781_1353.Q_flow = TC_781_1353.G * TC_781_1353.dT; TC_781_1353.dT = TC_781_1353.port_a.T - TC_781_1353.port_b.T; TC_781_1353.port_a.Q_flow = TC_781_1353.Q_flow; TC_781_1353.port_b.Q_flow = -TC_781_1353.Q_flow; TC_781_1428.Q_flow = TC_781_1428.G * TC_781_1428.dT; TC_781_1428.dT = TC_781_1428.port_a.T - TC_781_1428.port_b.T; TC_781_1428.port_a.Q_flow = TC_781_1428.Q_flow; TC_781_1428.port_b.Q_flow = -TC_781_1428.Q_flow; TC_782_783.Q_flow = TC_782_783.G * TC_782_783.dT; TC_782_783.dT = TC_782_783.port_a.T - TC_782_783.port_b.T; TC_782_783.port_a.Q_flow = TC_782_783.Q_flow; TC_782_783.port_b.Q_flow = -TC_782_783.Q_flow; TC_782_790.Q_flow = TC_782_790.G * TC_782_790.dT; TC_782_790.dT = TC_782_790.port_a.T - TC_782_790.port_b.T; TC_782_790.port_a.Q_flow = TC_782_790.Q_flow; TC_782_790.port_b.Q_flow = -TC_782_790.Q_flow; TC_782_1354.Q_flow = TC_782_1354.G * TC_782_1354.dT; TC_782_1354.dT = TC_782_1354.port_a.T - TC_782_1354.port_b.T; TC_782_1354.port_a.Q_flow = TC_782_1354.Q_flow; TC_782_1354.port_b.Q_flow = -TC_782_1354.Q_flow; TC_783_784.Q_flow = TC_783_784.G * TC_783_784.dT; TC_783_784.dT = TC_783_784.port_a.T - TC_783_784.port_b.T; TC_783_784.port_a.Q_flow = TC_783_784.Q_flow; TC_783_784.port_b.Q_flow = -TC_783_784.Q_flow; TC_783_791.Q_flow = TC_783_791.G * TC_783_791.dT; TC_783_791.dT = TC_783_791.port_a.T - TC_783_791.port_b.T; TC_783_791.port_a.Q_flow = TC_783_791.Q_flow; TC_783_791.port_b.Q_flow = -TC_783_791.Q_flow; TC_783_1355.Q_flow = TC_783_1355.G * TC_783_1355.dT; TC_783_1355.dT = TC_783_1355.port_a.T - TC_783_1355.port_b.T; TC_783_1355.port_a.Q_flow = TC_783_1355.Q_flow; TC_783_1355.port_b.Q_flow = -TC_783_1355.Q_flow; TC_784_785.Q_flow = TC_784_785.G * TC_784_785.dT; TC_784_785.dT = TC_784_785.port_a.T - TC_784_785.port_b.T; TC_784_785.port_a.Q_flow = TC_784_785.Q_flow; TC_784_785.port_b.Q_flow = -TC_784_785.Q_flow; TC_784_792.Q_flow = TC_784_792.G * TC_784_792.dT; TC_784_792.dT = TC_784_792.port_a.T - TC_784_792.port_b.T; TC_784_792.port_a.Q_flow = TC_784_792.Q_flow; TC_784_792.port_b.Q_flow = -TC_784_792.Q_flow; TC_784_1356.Q_flow = TC_784_1356.G * TC_784_1356.dT; TC_784_1356.dT = TC_784_1356.port_a.T - TC_784_1356.port_b.T; TC_784_1356.port_a.Q_flow = TC_784_1356.Q_flow; TC_784_1356.port_b.Q_flow = -TC_784_1356.Q_flow; TC_785_786.Q_flow = TC_785_786.G * TC_785_786.dT; TC_785_786.dT = TC_785_786.port_a.T - TC_785_786.port_b.T; TC_785_786.port_a.Q_flow = TC_785_786.Q_flow; TC_785_786.port_b.Q_flow = -TC_785_786.Q_flow; TC_785_793.Q_flow = TC_785_793.G * TC_785_793.dT; TC_785_793.dT = TC_785_793.port_a.T - TC_785_793.port_b.T; TC_785_793.port_a.Q_flow = TC_785_793.Q_flow; TC_785_793.port_b.Q_flow = -TC_785_793.Q_flow; TC_785_1494.Q_flow = TC_785_1494.G * TC_785_1494.dT; TC_785_1494.dT = TC_785_1494.port_a.T - TC_785_1494.port_b.T; TC_785_1494.port_a.Q_flow = TC_785_1494.Q_flow; TC_785_1494.port_b.Q_flow = -TC_785_1494.Q_flow; TC_786_787.Q_flow = TC_786_787.G * TC_786_787.dT; TC_786_787.dT = TC_786_787.port_a.T - TC_786_787.port_b.T; TC_786_787.port_a.Q_flow = TC_786_787.Q_flow; TC_786_787.port_b.Q_flow = -TC_786_787.Q_flow; TC_786_794.Q_flow = TC_786_794.G * TC_786_794.dT; TC_786_794.dT = TC_786_794.port_a.T - TC_786_794.port_b.T; TC_786_794.port_a.Q_flow = TC_786_794.Q_flow; TC_786_794.port_b.Q_flow = -TC_786_794.Q_flow; TC_786_1495.Q_flow = TC_786_1495.G * TC_786_1495.dT; TC_786_1495.dT = TC_786_1495.port_a.T - TC_786_1495.port_b.T; TC_786_1495.port_a.Q_flow = TC_786_1495.Q_flow; TC_786_1495.port_b.Q_flow = -TC_786_1495.Q_flow; TC_787_788.Q_flow = TC_787_788.G * TC_787_788.dT; TC_787_788.dT = TC_787_788.port_a.T - TC_787_788.port_b.T; TC_787_788.port_a.Q_flow = TC_787_788.Q_flow; TC_787_788.port_b.Q_flow = -TC_787_788.Q_flow; TC_787_795.Q_flow = TC_787_795.G * TC_787_795.dT; TC_787_795.dT = TC_787_795.port_a.T - TC_787_795.port_b.T; TC_787_795.port_a.Q_flow = TC_787_795.Q_flow; TC_787_795.port_b.Q_flow = -TC_787_795.Q_flow; TC_787_1496.Q_flow = TC_787_1496.G * TC_787_1496.dT; TC_787_1496.dT = TC_787_1496.port_a.T - TC_787_1496.port_b.T; TC_787_1496.port_a.Q_flow = TC_787_1496.Q_flow; TC_787_1496.port_b.Q_flow = -TC_787_1496.Q_flow; TC_788_796.Q_flow = TC_788_796.G * TC_788_796.dT; TC_788_796.dT = TC_788_796.port_a.T - TC_788_796.port_b.T; TC_788_796.port_a.Q_flow = TC_788_796.Q_flow; TC_788_796.port_b.Q_flow = -TC_788_796.Q_flow; TC_788_1357.Q_flow = TC_788_1357.G * TC_788_1357.dT; TC_788_1357.dT = TC_788_1357.port_a.T - TC_788_1357.port_b.T; TC_788_1357.port_a.Q_flow = TC_788_1357.Q_flow; TC_788_1357.port_b.Q_flow = -TC_788_1357.Q_flow; TC_788_1429.Q_flow = TC_788_1429.G * TC_788_1429.dT; TC_788_1429.dT = TC_788_1429.port_a.T - TC_788_1429.port_b.T; TC_788_1429.port_a.Q_flow = TC_788_1429.Q_flow; TC_788_1429.port_b.Q_flow = -TC_788_1429.Q_flow; TC_789_790.Q_flow = TC_789_790.G * TC_789_790.dT; TC_789_790.dT = TC_789_790.port_a.T - TC_789_790.port_b.T; TC_789_790.port_a.Q_flow = TC_789_790.Q_flow; TC_789_790.port_b.Q_flow = -TC_789_790.Q_flow; TC_789_797.Q_flow = TC_789_797.G * TC_789_797.dT; TC_789_797.dT = TC_789_797.port_a.T - TC_789_797.port_b.T; TC_789_797.port_a.Q_flow = TC_789_797.Q_flow; TC_789_797.port_b.Q_flow = -TC_789_797.Q_flow; TC_789_1361.Q_flow = TC_789_1361.G * TC_789_1361.dT; TC_789_1361.dT = TC_789_1361.port_a.T - TC_789_1361.port_b.T; TC_789_1361.port_a.Q_flow = TC_789_1361.Q_flow; TC_789_1361.port_b.Q_flow = -TC_789_1361.Q_flow; TC_789_1431.Q_flow = TC_789_1431.G * TC_789_1431.dT; TC_789_1431.dT = TC_789_1431.port_a.T - TC_789_1431.port_b.T; TC_789_1431.port_a.Q_flow = TC_789_1431.Q_flow; TC_789_1431.port_b.Q_flow = -TC_789_1431.Q_flow; TC_790_791.Q_flow = TC_790_791.G * TC_790_791.dT; TC_790_791.dT = TC_790_791.port_a.T - TC_790_791.port_b.T; TC_790_791.port_a.Q_flow = TC_790_791.Q_flow; TC_790_791.port_b.Q_flow = -TC_790_791.Q_flow; TC_790_798.Q_flow = TC_790_798.G * TC_790_798.dT; TC_790_798.dT = TC_790_798.port_a.T - TC_790_798.port_b.T; TC_790_798.port_a.Q_flow = TC_790_798.Q_flow; TC_790_798.port_b.Q_flow = -TC_790_798.Q_flow; TC_790_1362.Q_flow = TC_790_1362.G * TC_790_1362.dT; TC_790_1362.dT = TC_790_1362.port_a.T - TC_790_1362.port_b.T; TC_790_1362.port_a.Q_flow = TC_790_1362.Q_flow; TC_790_1362.port_b.Q_flow = -TC_790_1362.Q_flow; TC_791_792.Q_flow = TC_791_792.G * TC_791_792.dT; TC_791_792.dT = TC_791_792.port_a.T - TC_791_792.port_b.T; TC_791_792.port_a.Q_flow = TC_791_792.Q_flow; TC_791_792.port_b.Q_flow = -TC_791_792.Q_flow; TC_791_799.Q_flow = TC_791_799.G * TC_791_799.dT; TC_791_799.dT = TC_791_799.port_a.T - TC_791_799.port_b.T; TC_791_799.port_a.Q_flow = TC_791_799.Q_flow; TC_791_799.port_b.Q_flow = -TC_791_799.Q_flow; TC_791_1363.Q_flow = TC_791_1363.G * TC_791_1363.dT; TC_791_1363.dT = TC_791_1363.port_a.T - TC_791_1363.port_b.T; TC_791_1363.port_a.Q_flow = TC_791_1363.Q_flow; TC_791_1363.port_b.Q_flow = -TC_791_1363.Q_flow; TC_792_793.Q_flow = TC_792_793.G * TC_792_793.dT; TC_792_793.dT = TC_792_793.port_a.T - TC_792_793.port_b.T; TC_792_793.port_a.Q_flow = TC_792_793.Q_flow; TC_792_793.port_b.Q_flow = -TC_792_793.Q_flow; TC_792_800.Q_flow = TC_792_800.G * TC_792_800.dT; TC_792_800.dT = TC_792_800.port_a.T - TC_792_800.port_b.T; TC_792_800.port_a.Q_flow = TC_792_800.Q_flow; TC_792_800.port_b.Q_flow = -TC_792_800.Q_flow; TC_792_1364.Q_flow = TC_792_1364.G * TC_792_1364.dT; TC_792_1364.dT = TC_792_1364.port_a.T - TC_792_1364.port_b.T; TC_792_1364.port_a.Q_flow = TC_792_1364.Q_flow; TC_792_1364.port_b.Q_flow = -TC_792_1364.Q_flow; TC_793_794.Q_flow = TC_793_794.G * TC_793_794.dT; TC_793_794.dT = TC_793_794.port_a.T - TC_793_794.port_b.T; TC_793_794.port_a.Q_flow = TC_793_794.Q_flow; TC_793_794.port_b.Q_flow = -TC_793_794.Q_flow; TC_793_801.Q_flow = TC_793_801.G * TC_793_801.dT; TC_793_801.dT = TC_793_801.port_a.T - TC_793_801.port_b.T; TC_793_801.port_a.Q_flow = TC_793_801.Q_flow; TC_793_801.port_b.Q_flow = -TC_793_801.Q_flow; TC_793_1365.Q_flow = TC_793_1365.G * TC_793_1365.dT; TC_793_1365.dT = TC_793_1365.port_a.T - TC_793_1365.port_b.T; TC_793_1365.port_a.Q_flow = TC_793_1365.Q_flow; TC_793_1365.port_b.Q_flow = -TC_793_1365.Q_flow; TC_794_795.Q_flow = TC_794_795.G * TC_794_795.dT; TC_794_795.dT = TC_794_795.port_a.T - TC_794_795.port_b.T; TC_794_795.port_a.Q_flow = TC_794_795.Q_flow; TC_794_795.port_b.Q_flow = -TC_794_795.Q_flow; TC_794_802.Q_flow = TC_794_802.G * TC_794_802.dT; TC_794_802.dT = TC_794_802.port_a.T - TC_794_802.port_b.T; TC_794_802.port_a.Q_flow = TC_794_802.Q_flow; TC_794_802.port_b.Q_flow = -TC_794_802.Q_flow; TC_794_1366.Q_flow = TC_794_1366.G * TC_794_1366.dT; TC_794_1366.dT = TC_794_1366.port_a.T - TC_794_1366.port_b.T; TC_794_1366.port_a.Q_flow = TC_794_1366.Q_flow; TC_794_1366.port_b.Q_flow = -TC_794_1366.Q_flow; TC_795_796.Q_flow = TC_795_796.G * TC_795_796.dT; TC_795_796.dT = TC_795_796.port_a.T - TC_795_796.port_b.T; TC_795_796.port_a.Q_flow = TC_795_796.Q_flow; TC_795_796.port_b.Q_flow = -TC_795_796.Q_flow; TC_795_803.Q_flow = TC_795_803.G * TC_795_803.dT; TC_795_803.dT = TC_795_803.port_a.T - TC_795_803.port_b.T; TC_795_803.port_a.Q_flow = TC_795_803.Q_flow; TC_795_803.port_b.Q_flow = -TC_795_803.Q_flow; TC_795_1367.Q_flow = TC_795_1367.G * TC_795_1367.dT; TC_795_1367.dT = TC_795_1367.port_a.T - TC_795_1367.port_b.T; TC_795_1367.port_a.Q_flow = TC_795_1367.Q_flow; TC_795_1367.port_b.Q_flow = -TC_795_1367.Q_flow; TC_796_804.Q_flow = TC_796_804.G * TC_796_804.dT; TC_796_804.dT = TC_796_804.port_a.T - TC_796_804.port_b.T; TC_796_804.port_a.Q_flow = TC_796_804.Q_flow; TC_796_804.port_b.Q_flow = -TC_796_804.Q_flow; TC_796_1368.Q_flow = TC_796_1368.G * TC_796_1368.dT; TC_796_1368.dT = TC_796_1368.port_a.T - TC_796_1368.port_b.T; TC_796_1368.port_a.Q_flow = TC_796_1368.Q_flow; TC_796_1368.port_b.Q_flow = -TC_796_1368.Q_flow; TC_796_1432.Q_flow = TC_796_1432.G * TC_796_1432.dT; TC_796_1432.dT = TC_796_1432.port_a.T - TC_796_1432.port_b.T; TC_796_1432.port_a.Q_flow = TC_796_1432.Q_flow; TC_796_1432.port_b.Q_flow = -TC_796_1432.Q_flow; TC_797_798.Q_flow = TC_797_798.G * TC_797_798.dT; TC_797_798.dT = TC_797_798.port_a.T - TC_797_798.port_b.T; TC_797_798.port_a.Q_flow = TC_797_798.Q_flow; TC_797_798.port_b.Q_flow = -TC_797_798.Q_flow; TC_797_805.Q_flow = TC_797_805.G * TC_797_805.dT; TC_797_805.dT = TC_797_805.port_a.T - TC_797_805.port_b.T; TC_797_805.port_a.Q_flow = TC_797_805.Q_flow; TC_797_805.port_b.Q_flow = -TC_797_805.Q_flow; TC_797_1372.Q_flow = TC_797_1372.G * TC_797_1372.dT; TC_797_1372.dT = TC_797_1372.port_a.T - TC_797_1372.port_b.T; TC_797_1372.port_a.Q_flow = TC_797_1372.Q_flow; TC_797_1372.port_b.Q_flow = -TC_797_1372.Q_flow; TC_797_1434.Q_flow = TC_797_1434.G * TC_797_1434.dT; TC_797_1434.dT = TC_797_1434.port_a.T - TC_797_1434.port_b.T; TC_797_1434.port_a.Q_flow = TC_797_1434.Q_flow; TC_797_1434.port_b.Q_flow = -TC_797_1434.Q_flow; TC_798_799.Q_flow = TC_798_799.G * TC_798_799.dT; TC_798_799.dT = TC_798_799.port_a.T - TC_798_799.port_b.T; TC_798_799.port_a.Q_flow = TC_798_799.Q_flow; TC_798_799.port_b.Q_flow = -TC_798_799.Q_flow; TC_798_806.Q_flow = TC_798_806.G * TC_798_806.dT; TC_798_806.dT = TC_798_806.port_a.T - TC_798_806.port_b.T; TC_798_806.port_a.Q_flow = TC_798_806.Q_flow; TC_798_806.port_b.Q_flow = -TC_798_806.Q_flow; TC_798_1373.Q_flow = TC_798_1373.G * TC_798_1373.dT; TC_798_1373.dT = TC_798_1373.port_a.T - TC_798_1373.port_b.T; TC_798_1373.port_a.Q_flow = TC_798_1373.Q_flow; TC_798_1373.port_b.Q_flow = -TC_798_1373.Q_flow; TC_799_800.Q_flow = TC_799_800.G * TC_799_800.dT; TC_799_800.dT = TC_799_800.port_a.T - TC_799_800.port_b.T; TC_799_800.port_a.Q_flow = TC_799_800.Q_flow; TC_799_800.port_b.Q_flow = -TC_799_800.Q_flow; TC_799_807.Q_flow = TC_799_807.G * TC_799_807.dT; TC_799_807.dT = TC_799_807.port_a.T - TC_799_807.port_b.T; TC_799_807.port_a.Q_flow = TC_799_807.Q_flow; TC_799_807.port_b.Q_flow = -TC_799_807.Q_flow; TC_799_1374.Q_flow = TC_799_1374.G * TC_799_1374.dT; TC_799_1374.dT = TC_799_1374.port_a.T - TC_799_1374.port_b.T; TC_799_1374.port_a.Q_flow = TC_799_1374.Q_flow; TC_799_1374.port_b.Q_flow = -TC_799_1374.Q_flow; TC_800_801.Q_flow = TC_800_801.G * TC_800_801.dT; TC_800_801.dT = TC_800_801.port_a.T - TC_800_801.port_b.T; TC_800_801.port_a.Q_flow = TC_800_801.Q_flow; TC_800_801.port_b.Q_flow = -TC_800_801.Q_flow; TC_800_808.Q_flow = TC_800_808.G * TC_800_808.dT; TC_800_808.dT = TC_800_808.port_a.T - TC_800_808.port_b.T; TC_800_808.port_a.Q_flow = TC_800_808.Q_flow; TC_800_808.port_b.Q_flow = -TC_800_808.Q_flow; TC_800_1375.Q_flow = TC_800_1375.G * TC_800_1375.dT; TC_800_1375.dT = TC_800_1375.port_a.T - TC_800_1375.port_b.T; TC_800_1375.port_a.Q_flow = TC_800_1375.Q_flow; TC_800_1375.port_b.Q_flow = -TC_800_1375.Q_flow; TC_801_802.Q_flow = TC_801_802.G * TC_801_802.dT; TC_801_802.dT = TC_801_802.port_a.T - TC_801_802.port_b.T; TC_801_802.port_a.Q_flow = TC_801_802.Q_flow; TC_801_802.port_b.Q_flow = -TC_801_802.Q_flow; TC_801_809.Q_flow = TC_801_809.G * TC_801_809.dT; TC_801_809.dT = TC_801_809.port_a.T - TC_801_809.port_b.T; TC_801_809.port_a.Q_flow = TC_801_809.Q_flow; TC_801_809.port_b.Q_flow = -TC_801_809.Q_flow; TC_801_1376.Q_flow = TC_801_1376.G * TC_801_1376.dT; TC_801_1376.dT = TC_801_1376.port_a.T - TC_801_1376.port_b.T; TC_801_1376.port_a.Q_flow = TC_801_1376.Q_flow; TC_801_1376.port_b.Q_flow = -TC_801_1376.Q_flow; TC_802_803.Q_flow = TC_802_803.G * TC_802_803.dT; TC_802_803.dT = TC_802_803.port_a.T - TC_802_803.port_b.T; TC_802_803.port_a.Q_flow = TC_802_803.Q_flow; TC_802_803.port_b.Q_flow = -TC_802_803.Q_flow; TC_802_810.Q_flow = TC_802_810.G * TC_802_810.dT; TC_802_810.dT = TC_802_810.port_a.T - TC_802_810.port_b.T; TC_802_810.port_a.Q_flow = TC_802_810.Q_flow; TC_802_810.port_b.Q_flow = -TC_802_810.Q_flow; TC_802_1377.Q_flow = TC_802_1377.G * TC_802_1377.dT; TC_802_1377.dT = TC_802_1377.port_a.T - TC_802_1377.port_b.T; TC_802_1377.port_a.Q_flow = TC_802_1377.Q_flow; TC_802_1377.port_b.Q_flow = -TC_802_1377.Q_flow; TC_803_804.Q_flow = TC_803_804.G * TC_803_804.dT; TC_803_804.dT = TC_803_804.port_a.T - TC_803_804.port_b.T; TC_803_804.port_a.Q_flow = TC_803_804.Q_flow; TC_803_804.port_b.Q_flow = -TC_803_804.Q_flow; TC_803_811.Q_flow = TC_803_811.G * TC_803_811.dT; TC_803_811.dT = TC_803_811.port_a.T - TC_803_811.port_b.T; TC_803_811.port_a.Q_flow = TC_803_811.Q_flow; TC_803_811.port_b.Q_flow = -TC_803_811.Q_flow; TC_803_1378.Q_flow = TC_803_1378.G * TC_803_1378.dT; TC_803_1378.dT = TC_803_1378.port_a.T - TC_803_1378.port_b.T; TC_803_1378.port_a.Q_flow = TC_803_1378.Q_flow; TC_803_1378.port_b.Q_flow = -TC_803_1378.Q_flow; TC_804_812.Q_flow = TC_804_812.G * TC_804_812.dT; TC_804_812.dT = TC_804_812.port_a.T - TC_804_812.port_b.T; TC_804_812.port_a.Q_flow = TC_804_812.Q_flow; TC_804_812.port_b.Q_flow = -TC_804_812.Q_flow; TC_804_1379.Q_flow = TC_804_1379.G * TC_804_1379.dT; TC_804_1379.dT = TC_804_1379.port_a.T - TC_804_1379.port_b.T; TC_804_1379.port_a.Q_flow = TC_804_1379.Q_flow; TC_804_1379.port_b.Q_flow = -TC_804_1379.Q_flow; TC_804_1435.Q_flow = TC_804_1435.G * TC_804_1435.dT; TC_804_1435.dT = TC_804_1435.port_a.T - TC_804_1435.port_b.T; TC_804_1435.port_a.Q_flow = TC_804_1435.Q_flow; TC_804_1435.port_b.Q_flow = -TC_804_1435.Q_flow; TC_805_806.Q_flow = TC_805_806.G * TC_805_806.dT; TC_805_806.dT = TC_805_806.port_a.T - TC_805_806.port_b.T; TC_805_806.port_a.Q_flow = TC_805_806.Q_flow; TC_805_806.port_b.Q_flow = -TC_805_806.Q_flow; TC_805_1383.Q_flow = TC_805_1383.G * TC_805_1383.dT; TC_805_1383.dT = TC_805_1383.port_a.T - TC_805_1383.port_b.T; TC_805_1383.port_a.Q_flow = TC_805_1383.Q_flow; TC_805_1383.port_b.Q_flow = -TC_805_1383.Q_flow; TC_805_1437.Q_flow = TC_805_1437.G * TC_805_1437.dT; TC_805_1437.dT = TC_805_1437.port_a.T - TC_805_1437.port_b.T; TC_805_1437.port_a.Q_flow = TC_805_1437.Q_flow; TC_805_1437.port_b.Q_flow = -TC_805_1437.Q_flow; TC_805_1441.Q_flow = TC_805_1441.G * TC_805_1441.dT; TC_805_1441.dT = TC_805_1441.port_a.T - TC_805_1441.port_b.T; TC_805_1441.port_a.Q_flow = TC_805_1441.Q_flow; TC_805_1441.port_b.Q_flow = -TC_805_1441.Q_flow; TC_806_807.Q_flow = TC_806_807.G * TC_806_807.dT; TC_806_807.dT = TC_806_807.port_a.T - TC_806_807.port_b.T; TC_806_807.port_a.Q_flow = TC_806_807.Q_flow; TC_806_807.port_b.Q_flow = -TC_806_807.Q_flow; TC_806_1384.Q_flow = TC_806_1384.G * TC_806_1384.dT; TC_806_1384.dT = TC_806_1384.port_a.T - TC_806_1384.port_b.T; TC_806_1384.port_a.Q_flow = TC_806_1384.Q_flow; TC_806_1384.port_b.Q_flow = -TC_806_1384.Q_flow; TC_806_1442.Q_flow = TC_806_1442.G * TC_806_1442.dT; TC_806_1442.dT = TC_806_1442.port_a.T - TC_806_1442.port_b.T; TC_806_1442.port_a.Q_flow = TC_806_1442.Q_flow; TC_806_1442.port_b.Q_flow = -TC_806_1442.Q_flow; TC_807_808.Q_flow = TC_807_808.G * TC_807_808.dT; TC_807_808.dT = TC_807_808.port_a.T - TC_807_808.port_b.T; TC_807_808.port_a.Q_flow = TC_807_808.Q_flow; TC_807_808.port_b.Q_flow = -TC_807_808.Q_flow; TC_807_1385.Q_flow = TC_807_1385.G * TC_807_1385.dT; TC_807_1385.dT = TC_807_1385.port_a.T - TC_807_1385.port_b.T; TC_807_1385.port_a.Q_flow = TC_807_1385.Q_flow; TC_807_1385.port_b.Q_flow = -TC_807_1385.Q_flow; TC_807_1443.Q_flow = TC_807_1443.G * TC_807_1443.dT; TC_807_1443.dT = TC_807_1443.port_a.T - TC_807_1443.port_b.T; TC_807_1443.port_a.Q_flow = TC_807_1443.Q_flow; TC_807_1443.port_b.Q_flow = -TC_807_1443.Q_flow; TC_808_809.Q_flow = TC_808_809.G * TC_808_809.dT; TC_808_809.dT = TC_808_809.port_a.T - TC_808_809.port_b.T; TC_808_809.port_a.Q_flow = TC_808_809.Q_flow; TC_808_809.port_b.Q_flow = -TC_808_809.Q_flow; TC_808_1386.Q_flow = TC_808_1386.G * TC_808_1386.dT; TC_808_1386.dT = TC_808_1386.port_a.T - TC_808_1386.port_b.T; TC_808_1386.port_a.Q_flow = TC_808_1386.Q_flow; TC_808_1386.port_b.Q_flow = -TC_808_1386.Q_flow; TC_808_1444.Q_flow = TC_808_1444.G * TC_808_1444.dT; TC_808_1444.dT = TC_808_1444.port_a.T - TC_808_1444.port_b.T; TC_808_1444.port_a.Q_flow = TC_808_1444.Q_flow; TC_808_1444.port_b.Q_flow = -TC_808_1444.Q_flow; TC_809_810.Q_flow = TC_809_810.G * TC_809_810.dT; TC_809_810.dT = TC_809_810.port_a.T - TC_809_810.port_b.T; TC_809_810.port_a.Q_flow = TC_809_810.Q_flow; TC_809_810.port_b.Q_flow = -TC_809_810.Q_flow; TC_809_1387.Q_flow = TC_809_1387.G * TC_809_1387.dT; TC_809_1387.dT = TC_809_1387.port_a.T - TC_809_1387.port_b.T; TC_809_1387.port_a.Q_flow = TC_809_1387.Q_flow; TC_809_1387.port_b.Q_flow = -TC_809_1387.Q_flow; TC_809_1445.Q_flow = TC_809_1445.G * TC_809_1445.dT; TC_809_1445.dT = TC_809_1445.port_a.T - TC_809_1445.port_b.T; TC_809_1445.port_a.Q_flow = TC_809_1445.Q_flow; TC_809_1445.port_b.Q_flow = -TC_809_1445.Q_flow; TC_810_811.Q_flow = TC_810_811.G * TC_810_811.dT; TC_810_811.dT = TC_810_811.port_a.T - TC_810_811.port_b.T; TC_810_811.port_a.Q_flow = TC_810_811.Q_flow; TC_810_811.port_b.Q_flow = -TC_810_811.Q_flow; TC_810_1388.Q_flow = TC_810_1388.G * TC_810_1388.dT; TC_810_1388.dT = TC_810_1388.port_a.T - TC_810_1388.port_b.T; TC_810_1388.port_a.Q_flow = TC_810_1388.Q_flow; TC_810_1388.port_b.Q_flow = -TC_810_1388.Q_flow; TC_810_1446.Q_flow = TC_810_1446.G * TC_810_1446.dT; TC_810_1446.dT = TC_810_1446.port_a.T - TC_810_1446.port_b.T; TC_810_1446.port_a.Q_flow = TC_810_1446.Q_flow; TC_810_1446.port_b.Q_flow = -TC_810_1446.Q_flow; TC_811_812.Q_flow = TC_811_812.G * TC_811_812.dT; TC_811_812.dT = TC_811_812.port_a.T - TC_811_812.port_b.T; TC_811_812.port_a.Q_flow = TC_811_812.Q_flow; TC_811_812.port_b.Q_flow = -TC_811_812.Q_flow; TC_811_1389.Q_flow = TC_811_1389.G * TC_811_1389.dT; TC_811_1389.dT = TC_811_1389.port_a.T - TC_811_1389.port_b.T; TC_811_1389.port_a.Q_flow = TC_811_1389.Q_flow; TC_811_1389.port_b.Q_flow = -TC_811_1389.Q_flow; TC_811_1447.Q_flow = TC_811_1447.G * TC_811_1447.dT; TC_811_1447.dT = TC_811_1447.port_a.T - TC_811_1447.port_b.T; TC_811_1447.port_a.Q_flow = TC_811_1447.Q_flow; TC_811_1447.port_b.Q_flow = -TC_811_1447.Q_flow; TC_812_1390.Q_flow = TC_812_1390.G * TC_812_1390.dT; TC_812_1390.dT = TC_812_1390.port_a.T - TC_812_1390.port_b.T; TC_812_1390.port_a.Q_flow = TC_812_1390.Q_flow; TC_812_1390.port_b.Q_flow = -TC_812_1390.Q_flow; TC_812_1438.Q_flow = TC_812_1438.G * TC_812_1438.dT; TC_812_1438.dT = TC_812_1438.port_a.T - TC_812_1438.port_b.T; TC_812_1438.port_a.Q_flow = TC_812_1438.Q_flow; TC_812_1438.port_b.Q_flow = -TC_812_1438.Q_flow; TC_812_1448.Q_flow = TC_812_1448.G * TC_812_1448.dT; TC_812_1448.dT = TC_812_1448.port_a.T - TC_812_1448.port_b.T; TC_812_1448.port_a.Q_flow = TC_812_1448.Q_flow; TC_812_1448.port_b.Q_flow = -TC_812_1448.Q_flow; TC_813_814.Q_flow = TC_813_814.G * TC_813_814.dT; TC_813_814.dT = TC_813_814.port_a.T - TC_813_814.port_b.T; TC_813_814.port_a.Q_flow = TC_813_814.Q_flow; TC_813_814.port_b.Q_flow = -TC_813_814.Q_flow; TC_813_1293.Q_flow = TC_813_1293.G * TC_813_1293.dT; TC_813_1293.dT = TC_813_1293.port_a.T - TC_813_1293.port_b.T; TC_813_1293.port_a.Q_flow = TC_813_1293.Q_flow; TC_813_1293.port_b.Q_flow = -TC_813_1293.Q_flow; TC_813_1462.Q_flow = TC_813_1462.G * TC_813_1462.dT; TC_813_1462.dT = TC_813_1462.port_a.T - TC_813_1462.port_b.T; TC_813_1462.port_a.Q_flow = TC_813_1462.Q_flow; TC_813_1462.port_b.Q_flow = -TC_813_1462.Q_flow; TC_813_1468.Q_flow = TC_813_1468.G * TC_813_1468.dT; TC_813_1468.dT = TC_813_1468.port_a.T - TC_813_1468.port_b.T; TC_813_1468.port_a.Q_flow = TC_813_1468.Q_flow; TC_813_1468.port_b.Q_flow = -TC_813_1468.Q_flow; TC_814_815.Q_flow = TC_814_815.G * TC_814_815.dT; TC_814_815.dT = TC_814_815.port_a.T - TC_814_815.port_b.T; TC_814_815.port_a.Q_flow = TC_814_815.Q_flow; TC_814_815.port_b.Q_flow = -TC_814_815.Q_flow; TC_814_1294.Q_flow = TC_814_1294.G * TC_814_1294.dT; TC_814_1294.dT = TC_814_1294.port_a.T - TC_814_1294.port_b.T; TC_814_1294.port_a.Q_flow = TC_814_1294.Q_flow; TC_814_1294.port_b.Q_flow = -TC_814_1294.Q_flow; TC_814_1469.Q_flow = TC_814_1469.G * TC_814_1469.dT; TC_814_1469.dT = TC_814_1469.port_a.T - TC_814_1469.port_b.T; TC_814_1469.port_a.Q_flow = TC_814_1469.Q_flow; TC_814_1469.port_b.Q_flow = -TC_814_1469.Q_flow; TC_815_816.Q_flow = TC_815_816.G * TC_815_816.dT; TC_815_816.dT = TC_815_816.port_a.T - TC_815_816.port_b.T; TC_815_816.port_a.Q_flow = TC_815_816.Q_flow; TC_815_816.port_b.Q_flow = -TC_815_816.Q_flow; TC_815_1295.Q_flow = TC_815_1295.G * TC_815_1295.dT; TC_815_1295.dT = TC_815_1295.port_a.T - TC_815_1295.port_b.T; TC_815_1295.port_a.Q_flow = TC_815_1295.Q_flow; TC_815_1295.port_b.Q_flow = -TC_815_1295.Q_flow; TC_815_1470.Q_flow = TC_815_1470.G * TC_815_1470.dT; TC_815_1470.dT = TC_815_1470.port_a.T - TC_815_1470.port_b.T; TC_815_1470.port_a.Q_flow = TC_815_1470.Q_flow; TC_815_1470.port_b.Q_flow = -TC_815_1470.Q_flow; TC_816_817.Q_flow = TC_816_817.G * TC_816_817.dT; TC_816_817.dT = TC_816_817.port_a.T - TC_816_817.port_b.T; TC_816_817.port_a.Q_flow = TC_816_817.Q_flow; TC_816_817.port_b.Q_flow = -TC_816_817.Q_flow; TC_816_1296.Q_flow = TC_816_1296.G * TC_816_1296.dT; TC_816_1296.dT = TC_816_1296.port_a.T - TC_816_1296.port_b.T; TC_816_1296.port_a.Q_flow = TC_816_1296.Q_flow; TC_816_1296.port_b.Q_flow = -TC_816_1296.Q_flow; TC_816_1471.Q_flow = TC_816_1471.G * TC_816_1471.dT; TC_816_1471.dT = TC_816_1471.port_a.T - TC_816_1471.port_b.T; TC_816_1471.port_a.Q_flow = TC_816_1471.Q_flow; TC_816_1471.port_b.Q_flow = -TC_816_1471.Q_flow; TC_817_818.Q_flow = TC_817_818.G * TC_817_818.dT; TC_817_818.dT = TC_817_818.port_a.T - TC_817_818.port_b.T; TC_817_818.port_a.Q_flow = TC_817_818.Q_flow; TC_817_818.port_b.Q_flow = -TC_817_818.Q_flow; TC_817_1297.Q_flow = TC_817_1297.G * TC_817_1297.dT; TC_817_1297.dT = TC_817_1297.port_a.T - TC_817_1297.port_b.T; TC_817_1297.port_a.Q_flow = TC_817_1297.Q_flow; TC_817_1297.port_b.Q_flow = -TC_817_1297.Q_flow; TC_817_1472.Q_flow = TC_817_1472.G * TC_817_1472.dT; TC_817_1472.dT = TC_817_1472.port_a.T - TC_817_1472.port_b.T; TC_817_1472.port_a.Q_flow = TC_817_1472.Q_flow; TC_817_1472.port_b.Q_flow = -TC_817_1472.Q_flow; TC_818_819.Q_flow = TC_818_819.G * TC_818_819.dT; TC_818_819.dT = TC_818_819.port_a.T - TC_818_819.port_b.T; TC_818_819.port_a.Q_flow = TC_818_819.Q_flow; TC_818_819.port_b.Q_flow = -TC_818_819.Q_flow; TC_818_1298.Q_flow = TC_818_1298.G * TC_818_1298.dT; TC_818_1298.dT = TC_818_1298.port_a.T - TC_818_1298.port_b.T; TC_818_1298.port_a.Q_flow = TC_818_1298.Q_flow; TC_818_1298.port_b.Q_flow = -TC_818_1298.Q_flow; TC_818_1473.Q_flow = TC_818_1473.G * TC_818_1473.dT; TC_818_1473.dT = TC_818_1473.port_a.T - TC_818_1473.port_b.T; TC_818_1473.port_a.Q_flow = TC_818_1473.Q_flow; TC_818_1473.port_b.Q_flow = -TC_818_1473.Q_flow; TC_819_820.Q_flow = TC_819_820.G * TC_819_820.dT; TC_819_820.dT = TC_819_820.port_a.T - TC_819_820.port_b.T; TC_819_820.port_a.Q_flow = TC_819_820.Q_flow; TC_819_820.port_b.Q_flow = -TC_819_820.Q_flow; TC_819_1299.Q_flow = TC_819_1299.G * TC_819_1299.dT; TC_819_1299.dT = TC_819_1299.port_a.T - TC_819_1299.port_b.T; TC_819_1299.port_a.Q_flow = TC_819_1299.Q_flow; TC_819_1299.port_b.Q_flow = -TC_819_1299.Q_flow; TC_819_1474.Q_flow = TC_819_1474.G * TC_819_1474.dT; TC_819_1474.dT = TC_819_1474.port_a.T - TC_819_1474.port_b.T; TC_819_1474.port_a.Q_flow = TC_819_1474.Q_flow; TC_819_1474.port_b.Q_flow = -TC_819_1474.Q_flow; TC_820_1300.Q_flow = TC_820_1300.G * TC_820_1300.dT; TC_820_1300.dT = TC_820_1300.port_a.T - TC_820_1300.port_b.T; TC_820_1300.port_a.Q_flow = TC_820_1300.Q_flow; TC_820_1300.port_b.Q_flow = -TC_820_1300.Q_flow; TC_820_1463.Q_flow = TC_820_1463.G * TC_820_1463.dT; TC_820_1463.dT = TC_820_1463.port_a.T - TC_820_1463.port_b.T; TC_820_1463.port_a.Q_flow = TC_820_1463.Q_flow; TC_820_1463.port_b.Q_flow = -TC_820_1463.Q_flow; TC_820_1475.Q_flow = TC_820_1475.G * TC_820_1475.dT; TC_820_1475.dT = TC_820_1475.port_a.T - TC_820_1475.port_b.T; TC_820_1475.port_a.Q_flow = TC_820_1475.Q_flow; TC_820_1475.port_b.Q_flow = -TC_820_1475.Q_flow; TC_821_822.Q_flow = TC_821_822.G * TC_821_822.dT; TC_821_822.dT = TC_821_822.port_a.T - TC_821_822.port_b.T; TC_821_822.port_a.Q_flow = TC_821_822.Q_flow; TC_821_822.port_b.Q_flow = -TC_821_822.Q_flow; TC_821_832.Q_flow = TC_821_832.G * TC_821_832.dT; TC_821_832.dT = TC_821_832.port_a.T - TC_821_832.port_b.T; TC_821_832.port_a.Q_flow = TC_821_832.Q_flow; TC_821_832.port_b.Q_flow = -TC_821_832.Q_flow; TC_821_1017.Q_flow = TC_821_1017.G * TC_821_1017.dT; TC_821_1017.dT = TC_821_1017.port_a.T - TC_821_1017.port_b.T; TC_821_1017.port_a.Q_flow = TC_821_1017.Q_flow; TC_821_1017.port_b.Q_flow = -TC_821_1017.Q_flow; TC_822_823.Q_flow = TC_822_823.G * TC_822_823.dT; TC_822_823.dT = TC_822_823.port_a.T - TC_822_823.port_b.T; TC_822_823.port_a.Q_flow = TC_822_823.Q_flow; TC_822_823.port_b.Q_flow = -TC_822_823.Q_flow; TC_822_833.Q_flow = TC_822_833.G * TC_822_833.dT; TC_822_833.dT = TC_822_833.port_a.T - TC_822_833.port_b.T; TC_822_833.port_a.Q_flow = TC_822_833.Q_flow; TC_822_833.port_b.Q_flow = -TC_822_833.Q_flow; TC_822_1018.Q_flow = TC_822_1018.G * TC_822_1018.dT; TC_822_1018.dT = TC_822_1018.port_a.T - TC_822_1018.port_b.T; TC_822_1018.port_a.Q_flow = TC_822_1018.Q_flow; TC_822_1018.port_b.Q_flow = -TC_822_1018.Q_flow; TC_823_824.Q_flow = TC_823_824.G * TC_823_824.dT; TC_823_824.dT = TC_823_824.port_a.T - TC_823_824.port_b.T; TC_823_824.port_a.Q_flow = TC_823_824.Q_flow; TC_823_824.port_b.Q_flow = -TC_823_824.Q_flow; TC_823_834.Q_flow = TC_823_834.G * TC_823_834.dT; TC_823_834.dT = TC_823_834.port_a.T - TC_823_834.port_b.T; TC_823_834.port_a.Q_flow = TC_823_834.Q_flow; TC_823_834.port_b.Q_flow = -TC_823_834.Q_flow; TC_823_1019.Q_flow = TC_823_1019.G * TC_823_1019.dT; TC_823_1019.dT = TC_823_1019.port_a.T - TC_823_1019.port_b.T; TC_823_1019.port_a.Q_flow = TC_823_1019.Q_flow; TC_823_1019.port_b.Q_flow = -TC_823_1019.Q_flow; TC_824_825.Q_flow = TC_824_825.G * TC_824_825.dT; TC_824_825.dT = TC_824_825.port_a.T - TC_824_825.port_b.T; TC_824_825.port_a.Q_flow = TC_824_825.Q_flow; TC_824_825.port_b.Q_flow = -TC_824_825.Q_flow; TC_824_835.Q_flow = TC_824_835.G * TC_824_835.dT; TC_824_835.dT = TC_824_835.port_a.T - TC_824_835.port_b.T; TC_824_835.port_a.Q_flow = TC_824_835.Q_flow; TC_824_835.port_b.Q_flow = -TC_824_835.Q_flow; TC_824_1020.Q_flow = TC_824_1020.G * TC_824_1020.dT; TC_824_1020.dT = TC_824_1020.port_a.T - TC_824_1020.port_b.T; TC_824_1020.port_a.Q_flow = TC_824_1020.Q_flow; TC_824_1020.port_b.Q_flow = -TC_824_1020.Q_flow; TC_825_826.Q_flow = TC_825_826.G * TC_825_826.dT; TC_825_826.dT = TC_825_826.port_a.T - TC_825_826.port_b.T; TC_825_826.port_a.Q_flow = TC_825_826.Q_flow; TC_825_826.port_b.Q_flow = -TC_825_826.Q_flow; TC_825_836.Q_flow = TC_825_836.G * TC_825_836.dT; TC_825_836.dT = TC_825_836.port_a.T - TC_825_836.port_b.T; TC_825_836.port_a.Q_flow = TC_825_836.Q_flow; TC_825_836.port_b.Q_flow = -TC_825_836.Q_flow; TC_825_1021.Q_flow = TC_825_1021.G * TC_825_1021.dT; TC_825_1021.dT = TC_825_1021.port_a.T - TC_825_1021.port_b.T; TC_825_1021.port_a.Q_flow = TC_825_1021.Q_flow; TC_825_1021.port_b.Q_flow = -TC_825_1021.Q_flow; TC_826_827.Q_flow = TC_826_827.G * TC_826_827.dT; TC_826_827.dT = TC_826_827.port_a.T - TC_826_827.port_b.T; TC_826_827.port_a.Q_flow = TC_826_827.Q_flow; TC_826_827.port_b.Q_flow = -TC_826_827.Q_flow; TC_826_837.Q_flow = TC_826_837.G * TC_826_837.dT; TC_826_837.dT = TC_826_837.port_a.T - TC_826_837.port_b.T; TC_826_837.port_a.Q_flow = TC_826_837.Q_flow; TC_826_837.port_b.Q_flow = -TC_826_837.Q_flow; TC_826_1022.Q_flow = TC_826_1022.G * TC_826_1022.dT; TC_826_1022.dT = TC_826_1022.port_a.T - TC_826_1022.port_b.T; TC_826_1022.port_a.Q_flow = TC_826_1022.Q_flow; TC_826_1022.port_b.Q_flow = -TC_826_1022.Q_flow; TC_827_828.Q_flow = TC_827_828.G * TC_827_828.dT; TC_827_828.dT = TC_827_828.port_a.T - TC_827_828.port_b.T; TC_827_828.port_a.Q_flow = TC_827_828.Q_flow; TC_827_828.port_b.Q_flow = -TC_827_828.Q_flow; TC_827_838.Q_flow = TC_827_838.G * TC_827_838.dT; TC_827_838.dT = TC_827_838.port_a.T - TC_827_838.port_b.T; TC_827_838.port_a.Q_flow = TC_827_838.Q_flow; TC_827_838.port_b.Q_flow = -TC_827_838.Q_flow; TC_827_1023.Q_flow = TC_827_1023.G * TC_827_1023.dT; TC_827_1023.dT = TC_827_1023.port_a.T - TC_827_1023.port_b.T; TC_827_1023.port_a.Q_flow = TC_827_1023.Q_flow; TC_827_1023.port_b.Q_flow = -TC_827_1023.Q_flow; TC_828_829.Q_flow = TC_828_829.G * TC_828_829.dT; TC_828_829.dT = TC_828_829.port_a.T - TC_828_829.port_b.T; TC_828_829.port_a.Q_flow = TC_828_829.Q_flow; TC_828_829.port_b.Q_flow = -TC_828_829.Q_flow; TC_828_839.Q_flow = TC_828_839.G * TC_828_839.dT; TC_828_839.dT = TC_828_839.port_a.T - TC_828_839.port_b.T; TC_828_839.port_a.Q_flow = TC_828_839.Q_flow; TC_828_839.port_b.Q_flow = -TC_828_839.Q_flow; TC_828_1024.Q_flow = TC_828_1024.G * TC_828_1024.dT; TC_828_1024.dT = TC_828_1024.port_a.T - TC_828_1024.port_b.T; TC_828_1024.port_a.Q_flow = TC_828_1024.Q_flow; TC_828_1024.port_b.Q_flow = -TC_828_1024.Q_flow; TC_829_830.Q_flow = TC_829_830.G * TC_829_830.dT; TC_829_830.dT = TC_829_830.port_a.T - TC_829_830.port_b.T; TC_829_830.port_a.Q_flow = TC_829_830.Q_flow; TC_829_830.port_b.Q_flow = -TC_829_830.Q_flow; TC_829_840.Q_flow = TC_829_840.G * TC_829_840.dT; TC_829_840.dT = TC_829_840.port_a.T - TC_829_840.port_b.T; TC_829_840.port_a.Q_flow = TC_829_840.Q_flow; TC_829_840.port_b.Q_flow = -TC_829_840.Q_flow; TC_829_1025.Q_flow = TC_829_1025.G * TC_829_1025.dT; TC_829_1025.dT = TC_829_1025.port_a.T - TC_829_1025.port_b.T; TC_829_1025.port_a.Q_flow = TC_829_1025.Q_flow; TC_829_1025.port_b.Q_flow = -TC_829_1025.Q_flow; TC_830_831.Q_flow = TC_830_831.G * TC_830_831.dT; TC_830_831.dT = TC_830_831.port_a.T - TC_830_831.port_b.T; TC_830_831.port_a.Q_flow = TC_830_831.Q_flow; TC_830_831.port_b.Q_flow = -TC_830_831.Q_flow; TC_830_841.Q_flow = TC_830_841.G * TC_830_841.dT; TC_830_841.dT = TC_830_841.port_a.T - TC_830_841.port_b.T; TC_830_841.port_a.Q_flow = TC_830_841.Q_flow; TC_830_841.port_b.Q_flow = -TC_830_841.Q_flow; TC_830_1026.Q_flow = TC_830_1026.G * TC_830_1026.dT; TC_830_1026.dT = TC_830_1026.port_a.T - TC_830_1026.port_b.T; TC_830_1026.port_a.Q_flow = TC_830_1026.Q_flow; TC_830_1026.port_b.Q_flow = -TC_830_1026.Q_flow; TC_831_842.Q_flow = TC_831_842.G * TC_831_842.dT; TC_831_842.dT = TC_831_842.port_a.T - TC_831_842.port_b.T; TC_831_842.port_a.Q_flow = TC_831_842.Q_flow; TC_831_842.port_b.Q_flow = -TC_831_842.Q_flow; TC_831_1027.Q_flow = TC_831_1027.G * TC_831_1027.dT; TC_831_1027.dT = TC_831_1027.port_a.T - TC_831_1027.port_b.T; TC_831_1027.port_a.Q_flow = TC_831_1027.Q_flow; TC_831_1027.port_b.Q_flow = -TC_831_1027.Q_flow; TC_832_833.Q_flow = TC_832_833.G * TC_832_833.dT; TC_832_833.dT = TC_832_833.port_a.T - TC_832_833.port_b.T; TC_832_833.port_a.Q_flow = TC_832_833.Q_flow; TC_832_833.port_b.Q_flow = -TC_832_833.Q_flow; TC_832_909.Q_flow = TC_832_909.G * TC_832_909.dT; TC_832_909.dT = TC_832_909.port_a.T - TC_832_909.port_b.T; TC_832_909.port_a.Q_flow = TC_832_909.Q_flow; TC_832_909.port_b.Q_flow = -TC_832_909.Q_flow; TC_832_1006.Q_flow = TC_832_1006.G * TC_832_1006.dT; TC_832_1006.dT = TC_832_1006.port_a.T - TC_832_1006.port_b.T; TC_832_1006.port_a.Q_flow = TC_832_1006.Q_flow; TC_832_1006.port_b.Q_flow = -TC_832_1006.Q_flow; TC_833_834.Q_flow = TC_833_834.G * TC_833_834.dT; TC_833_834.dT = TC_833_834.port_a.T - TC_833_834.port_b.T; TC_833_834.port_a.Q_flow = TC_833_834.Q_flow; TC_833_834.port_b.Q_flow = -TC_833_834.Q_flow; TC_833_910.Q_flow = TC_833_910.G * TC_833_910.dT; TC_833_910.dT = TC_833_910.port_a.T - TC_833_910.port_b.T; TC_833_910.port_a.Q_flow = TC_833_910.Q_flow; TC_833_910.port_b.Q_flow = -TC_833_910.Q_flow; TC_833_1007.Q_flow = TC_833_1007.G * TC_833_1007.dT; TC_833_1007.dT = TC_833_1007.port_a.T - TC_833_1007.port_b.T; TC_833_1007.port_a.Q_flow = TC_833_1007.Q_flow; TC_833_1007.port_b.Q_flow = -TC_833_1007.Q_flow; TC_834_835.Q_flow = TC_834_835.G * TC_834_835.dT; TC_834_835.dT = TC_834_835.port_a.T - TC_834_835.port_b.T; TC_834_835.port_a.Q_flow = TC_834_835.Q_flow; TC_834_835.port_b.Q_flow = -TC_834_835.Q_flow; TC_834_911.Q_flow = TC_834_911.G * TC_834_911.dT; TC_834_911.dT = TC_834_911.port_a.T - TC_834_911.port_b.T; TC_834_911.port_a.Q_flow = TC_834_911.Q_flow; TC_834_911.port_b.Q_flow = -TC_834_911.Q_flow; TC_834_1008.Q_flow = TC_834_1008.G * TC_834_1008.dT; TC_834_1008.dT = TC_834_1008.port_a.T - TC_834_1008.port_b.T; TC_834_1008.port_a.Q_flow = TC_834_1008.Q_flow; TC_834_1008.port_b.Q_flow = -TC_834_1008.Q_flow; TC_835_836.Q_flow = TC_835_836.G * TC_835_836.dT; TC_835_836.dT = TC_835_836.port_a.T - TC_835_836.port_b.T; TC_835_836.port_a.Q_flow = TC_835_836.Q_flow; TC_835_836.port_b.Q_flow = -TC_835_836.Q_flow; TC_835_912.Q_flow = TC_835_912.G * TC_835_912.dT; TC_835_912.dT = TC_835_912.port_a.T - TC_835_912.port_b.T; TC_835_912.port_a.Q_flow = TC_835_912.Q_flow; TC_835_912.port_b.Q_flow = -TC_835_912.Q_flow; TC_835_1009.Q_flow = TC_835_1009.G * TC_835_1009.dT; TC_835_1009.dT = TC_835_1009.port_a.T - TC_835_1009.port_b.T; TC_835_1009.port_a.Q_flow = TC_835_1009.Q_flow; TC_835_1009.port_b.Q_flow = -TC_835_1009.Q_flow; TC_836_837.Q_flow = TC_836_837.G * TC_836_837.dT; TC_836_837.dT = TC_836_837.port_a.T - TC_836_837.port_b.T; TC_836_837.port_a.Q_flow = TC_836_837.Q_flow; TC_836_837.port_b.Q_flow = -TC_836_837.Q_flow; TC_836_913.Q_flow = TC_836_913.G * TC_836_913.dT; TC_836_913.dT = TC_836_913.port_a.T - TC_836_913.port_b.T; TC_836_913.port_a.Q_flow = TC_836_913.Q_flow; TC_836_913.port_b.Q_flow = -TC_836_913.Q_flow; TC_836_1010.Q_flow = TC_836_1010.G * TC_836_1010.dT; TC_836_1010.dT = TC_836_1010.port_a.T - TC_836_1010.port_b.T; TC_836_1010.port_a.Q_flow = TC_836_1010.Q_flow; TC_836_1010.port_b.Q_flow = -TC_836_1010.Q_flow; TC_837_838.Q_flow = TC_837_838.G * TC_837_838.dT; TC_837_838.dT = TC_837_838.port_a.T - TC_837_838.port_b.T; TC_837_838.port_a.Q_flow = TC_837_838.Q_flow; TC_837_838.port_b.Q_flow = -TC_837_838.Q_flow; TC_837_914.Q_flow = TC_837_914.G * TC_837_914.dT; TC_837_914.dT = TC_837_914.port_a.T - TC_837_914.port_b.T; TC_837_914.port_a.Q_flow = TC_837_914.Q_flow; TC_837_914.port_b.Q_flow = -TC_837_914.Q_flow; TC_837_1011.Q_flow = TC_837_1011.G * TC_837_1011.dT; TC_837_1011.dT = TC_837_1011.port_a.T - TC_837_1011.port_b.T; TC_837_1011.port_a.Q_flow = TC_837_1011.Q_flow; TC_837_1011.port_b.Q_flow = -TC_837_1011.Q_flow; TC_838_839.Q_flow = TC_838_839.G * TC_838_839.dT; TC_838_839.dT = TC_838_839.port_a.T - TC_838_839.port_b.T; TC_838_839.port_a.Q_flow = TC_838_839.Q_flow; TC_838_839.port_b.Q_flow = -TC_838_839.Q_flow; TC_838_915.Q_flow = TC_838_915.G * TC_838_915.dT; TC_838_915.dT = TC_838_915.port_a.T - TC_838_915.port_b.T; TC_838_915.port_a.Q_flow = TC_838_915.Q_flow; TC_838_915.port_b.Q_flow = -TC_838_915.Q_flow; TC_838_1012.Q_flow = TC_838_1012.G * TC_838_1012.dT; TC_838_1012.dT = TC_838_1012.port_a.T - TC_838_1012.port_b.T; TC_838_1012.port_a.Q_flow = TC_838_1012.Q_flow; TC_838_1012.port_b.Q_flow = -TC_838_1012.Q_flow; TC_839_840.Q_flow = TC_839_840.G * TC_839_840.dT; TC_839_840.dT = TC_839_840.port_a.T - TC_839_840.port_b.T; TC_839_840.port_a.Q_flow = TC_839_840.Q_flow; TC_839_840.port_b.Q_flow = -TC_839_840.Q_flow; TC_839_916.Q_flow = TC_839_916.G * TC_839_916.dT; TC_839_916.dT = TC_839_916.port_a.T - TC_839_916.port_b.T; TC_839_916.port_a.Q_flow = TC_839_916.Q_flow; TC_839_916.port_b.Q_flow = -TC_839_916.Q_flow; TC_839_1013.Q_flow = TC_839_1013.G * TC_839_1013.dT; TC_839_1013.dT = TC_839_1013.port_a.T - TC_839_1013.port_b.T; TC_839_1013.port_a.Q_flow = TC_839_1013.Q_flow; TC_839_1013.port_b.Q_flow = -TC_839_1013.Q_flow; TC_840_841.Q_flow = TC_840_841.G * TC_840_841.dT; TC_840_841.dT = TC_840_841.port_a.T - TC_840_841.port_b.T; TC_840_841.port_a.Q_flow = TC_840_841.Q_flow; TC_840_841.port_b.Q_flow = -TC_840_841.Q_flow; TC_840_917.Q_flow = TC_840_917.G * TC_840_917.dT; TC_840_917.dT = TC_840_917.port_a.T - TC_840_917.port_b.T; TC_840_917.port_a.Q_flow = TC_840_917.Q_flow; TC_840_917.port_b.Q_flow = -TC_840_917.Q_flow; TC_840_1014.Q_flow = TC_840_1014.G * TC_840_1014.dT; TC_840_1014.dT = TC_840_1014.port_a.T - TC_840_1014.port_b.T; TC_840_1014.port_a.Q_flow = TC_840_1014.Q_flow; TC_840_1014.port_b.Q_flow = -TC_840_1014.Q_flow; TC_841_842.Q_flow = TC_841_842.G * TC_841_842.dT; TC_841_842.dT = TC_841_842.port_a.T - TC_841_842.port_b.T; TC_841_842.port_a.Q_flow = TC_841_842.Q_flow; TC_841_842.port_b.Q_flow = -TC_841_842.Q_flow; TC_841_918.Q_flow = TC_841_918.G * TC_841_918.dT; TC_841_918.dT = TC_841_918.port_a.T - TC_841_918.port_b.T; TC_841_918.port_a.Q_flow = TC_841_918.Q_flow; TC_841_918.port_b.Q_flow = -TC_841_918.Q_flow; TC_841_1015.Q_flow = TC_841_1015.G * TC_841_1015.dT; TC_841_1015.dT = TC_841_1015.port_a.T - TC_841_1015.port_b.T; TC_841_1015.port_a.Q_flow = TC_841_1015.Q_flow; TC_841_1015.port_b.Q_flow = -TC_841_1015.Q_flow; TC_842_919.Q_flow = TC_842_919.G * TC_842_919.dT; TC_842_919.dT = TC_842_919.port_a.T - TC_842_919.port_b.T; TC_842_919.port_a.Q_flow = TC_842_919.Q_flow; TC_842_919.port_b.Q_flow = -TC_842_919.Q_flow; TC_842_1016.Q_flow = TC_842_1016.G * TC_842_1016.dT; TC_842_1016.dT = TC_842_1016.port_a.T - TC_842_1016.port_b.T; TC_842_1016.port_a.Q_flow = TC_842_1016.Q_flow; TC_842_1016.port_b.Q_flow = -TC_842_1016.Q_flow; TC_843_844.Q_flow = TC_843_844.G * TC_843_844.dT; TC_843_844.dT = TC_843_844.port_a.T - TC_843_844.port_b.T; TC_843_844.port_a.Q_flow = TC_843_844.Q_flow; TC_843_844.port_b.Q_flow = -TC_843_844.Q_flow; TC_843_854.Q_flow = TC_843_854.G * TC_843_854.dT; TC_843_854.dT = TC_843_854.port_a.T - TC_843_854.port_b.T; TC_843_854.port_a.Q_flow = TC_843_854.Q_flow; TC_843_854.port_b.Q_flow = -TC_843_854.Q_flow; TC_843_964.Q_flow = TC_843_964.G * TC_843_964.dT; TC_843_964.dT = TC_843_964.port_a.T - TC_843_964.port_b.T; TC_843_964.port_a.Q_flow = TC_843_964.Q_flow; TC_843_964.port_b.Q_flow = -TC_843_964.Q_flow; TC_843_1038.Q_flow = TC_843_1038.G * TC_843_1038.dT; TC_843_1038.dT = TC_843_1038.port_a.T - TC_843_1038.port_b.T; TC_843_1038.port_a.Q_flow = TC_843_1038.Q_flow; TC_843_1038.port_b.Q_flow = -TC_843_1038.Q_flow; TC_844_845.Q_flow = TC_844_845.G * TC_844_845.dT; TC_844_845.dT = TC_844_845.port_a.T - TC_844_845.port_b.T; TC_844_845.port_a.Q_flow = TC_844_845.Q_flow; TC_844_845.port_b.Q_flow = -TC_844_845.Q_flow; TC_844_855.Q_flow = TC_844_855.G * TC_844_855.dT; TC_844_855.dT = TC_844_855.port_a.T - TC_844_855.port_b.T; TC_844_855.port_a.Q_flow = TC_844_855.Q_flow; TC_844_855.port_b.Q_flow = -TC_844_855.Q_flow; TC_844_965.Q_flow = TC_844_965.G * TC_844_965.dT; TC_844_965.dT = TC_844_965.port_a.T - TC_844_965.port_b.T; TC_844_965.port_a.Q_flow = TC_844_965.Q_flow; TC_844_965.port_b.Q_flow = -TC_844_965.Q_flow; TC_844_1039.Q_flow = TC_844_1039.G * TC_844_1039.dT; TC_844_1039.dT = TC_844_1039.port_a.T - TC_844_1039.port_b.T; TC_844_1039.port_a.Q_flow = TC_844_1039.Q_flow; TC_844_1039.port_b.Q_flow = -TC_844_1039.Q_flow; TC_845_846.Q_flow = TC_845_846.G * TC_845_846.dT; TC_845_846.dT = TC_845_846.port_a.T - TC_845_846.port_b.T; TC_845_846.port_a.Q_flow = TC_845_846.Q_flow; TC_845_846.port_b.Q_flow = -TC_845_846.Q_flow; TC_845_856.Q_flow = TC_845_856.G * TC_845_856.dT; TC_845_856.dT = TC_845_856.port_a.T - TC_845_856.port_b.T; TC_845_856.port_a.Q_flow = TC_845_856.Q_flow; TC_845_856.port_b.Q_flow = -TC_845_856.Q_flow; TC_845_966.Q_flow = TC_845_966.G * TC_845_966.dT; TC_845_966.dT = TC_845_966.port_a.T - TC_845_966.port_b.T; TC_845_966.port_a.Q_flow = TC_845_966.Q_flow; TC_845_966.port_b.Q_flow = -TC_845_966.Q_flow; TC_845_1040.Q_flow = TC_845_1040.G * TC_845_1040.dT; TC_845_1040.dT = TC_845_1040.port_a.T - TC_845_1040.port_b.T; TC_845_1040.port_a.Q_flow = TC_845_1040.Q_flow; TC_845_1040.port_b.Q_flow = -TC_845_1040.Q_flow; TC_846_847.Q_flow = TC_846_847.G * TC_846_847.dT; TC_846_847.dT = TC_846_847.port_a.T - TC_846_847.port_b.T; TC_846_847.port_a.Q_flow = TC_846_847.Q_flow; TC_846_847.port_b.Q_flow = -TC_846_847.Q_flow; TC_846_857.Q_flow = TC_846_857.G * TC_846_857.dT; TC_846_857.dT = TC_846_857.port_a.T - TC_846_857.port_b.T; TC_846_857.port_a.Q_flow = TC_846_857.Q_flow; TC_846_857.port_b.Q_flow = -TC_846_857.Q_flow; TC_846_967.Q_flow = TC_846_967.G * TC_846_967.dT; TC_846_967.dT = TC_846_967.port_a.T - TC_846_967.port_b.T; TC_846_967.port_a.Q_flow = TC_846_967.Q_flow; TC_846_967.port_b.Q_flow = -TC_846_967.Q_flow; TC_846_1041.Q_flow = TC_846_1041.G * TC_846_1041.dT; TC_846_1041.dT = TC_846_1041.port_a.T - TC_846_1041.port_b.T; TC_846_1041.port_a.Q_flow = TC_846_1041.Q_flow; TC_846_1041.port_b.Q_flow = -TC_846_1041.Q_flow; TC_847_848.Q_flow = TC_847_848.G * TC_847_848.dT; TC_847_848.dT = TC_847_848.port_a.T - TC_847_848.port_b.T; TC_847_848.port_a.Q_flow = TC_847_848.Q_flow; TC_847_848.port_b.Q_flow = -TC_847_848.Q_flow; TC_847_858.Q_flow = TC_847_858.G * TC_847_858.dT; TC_847_858.dT = TC_847_858.port_a.T - TC_847_858.port_b.T; TC_847_858.port_a.Q_flow = TC_847_858.Q_flow; TC_847_858.port_b.Q_flow = -TC_847_858.Q_flow; TC_847_968.Q_flow = TC_847_968.G * TC_847_968.dT; TC_847_968.dT = TC_847_968.port_a.T - TC_847_968.port_b.T; TC_847_968.port_a.Q_flow = TC_847_968.Q_flow; TC_847_968.port_b.Q_flow = -TC_847_968.Q_flow; TC_847_1042.Q_flow = TC_847_1042.G * TC_847_1042.dT; TC_847_1042.dT = TC_847_1042.port_a.T - TC_847_1042.port_b.T; TC_847_1042.port_a.Q_flow = TC_847_1042.Q_flow; TC_847_1042.port_b.Q_flow = -TC_847_1042.Q_flow; TC_848_849.Q_flow = TC_848_849.G * TC_848_849.dT; TC_848_849.dT = TC_848_849.port_a.T - TC_848_849.port_b.T; TC_848_849.port_a.Q_flow = TC_848_849.Q_flow; TC_848_849.port_b.Q_flow = -TC_848_849.Q_flow; TC_848_859.Q_flow = TC_848_859.G * TC_848_859.dT; TC_848_859.dT = TC_848_859.port_a.T - TC_848_859.port_b.T; TC_848_859.port_a.Q_flow = TC_848_859.Q_flow; TC_848_859.port_b.Q_flow = -TC_848_859.Q_flow; TC_848_969.Q_flow = TC_848_969.G * TC_848_969.dT; TC_848_969.dT = TC_848_969.port_a.T - TC_848_969.port_b.T; TC_848_969.port_a.Q_flow = TC_848_969.Q_flow; TC_848_969.port_b.Q_flow = -TC_848_969.Q_flow; TC_848_1043.Q_flow = TC_848_1043.G * TC_848_1043.dT; TC_848_1043.dT = TC_848_1043.port_a.T - TC_848_1043.port_b.T; TC_848_1043.port_a.Q_flow = TC_848_1043.Q_flow; TC_848_1043.port_b.Q_flow = -TC_848_1043.Q_flow; TC_849_850.Q_flow = TC_849_850.G * TC_849_850.dT; TC_849_850.dT = TC_849_850.port_a.T - TC_849_850.port_b.T; TC_849_850.port_a.Q_flow = TC_849_850.Q_flow; TC_849_850.port_b.Q_flow = -TC_849_850.Q_flow; TC_849_860.Q_flow = TC_849_860.G * TC_849_860.dT; TC_849_860.dT = TC_849_860.port_a.T - TC_849_860.port_b.T; TC_849_860.port_a.Q_flow = TC_849_860.Q_flow; TC_849_860.port_b.Q_flow = -TC_849_860.Q_flow; TC_849_970.Q_flow = TC_849_970.G * TC_849_970.dT; TC_849_970.dT = TC_849_970.port_a.T - TC_849_970.port_b.T; TC_849_970.port_a.Q_flow = TC_849_970.Q_flow; TC_849_970.port_b.Q_flow = -TC_849_970.Q_flow; TC_849_1044.Q_flow = TC_849_1044.G * TC_849_1044.dT; TC_849_1044.dT = TC_849_1044.port_a.T - TC_849_1044.port_b.T; TC_849_1044.port_a.Q_flow = TC_849_1044.Q_flow; TC_849_1044.port_b.Q_flow = -TC_849_1044.Q_flow; TC_850_851.Q_flow = TC_850_851.G * TC_850_851.dT; TC_850_851.dT = TC_850_851.port_a.T - TC_850_851.port_b.T; TC_850_851.port_a.Q_flow = TC_850_851.Q_flow; TC_850_851.port_b.Q_flow = -TC_850_851.Q_flow; TC_850_861.Q_flow = TC_850_861.G * TC_850_861.dT; TC_850_861.dT = TC_850_861.port_a.T - TC_850_861.port_b.T; TC_850_861.port_a.Q_flow = TC_850_861.Q_flow; TC_850_861.port_b.Q_flow = -TC_850_861.Q_flow; TC_850_971.Q_flow = TC_850_971.G * TC_850_971.dT; TC_850_971.dT = TC_850_971.port_a.T - TC_850_971.port_b.T; TC_850_971.port_a.Q_flow = TC_850_971.Q_flow; TC_850_971.port_b.Q_flow = -TC_850_971.Q_flow; TC_850_1045.Q_flow = TC_850_1045.G * TC_850_1045.dT; TC_850_1045.dT = TC_850_1045.port_a.T - TC_850_1045.port_b.T; TC_850_1045.port_a.Q_flow = TC_850_1045.Q_flow; TC_850_1045.port_b.Q_flow = -TC_850_1045.Q_flow; TC_851_852.Q_flow = TC_851_852.G * TC_851_852.dT; TC_851_852.dT = TC_851_852.port_a.T - TC_851_852.port_b.T; TC_851_852.port_a.Q_flow = TC_851_852.Q_flow; TC_851_852.port_b.Q_flow = -TC_851_852.Q_flow; TC_851_862.Q_flow = TC_851_862.G * TC_851_862.dT; TC_851_862.dT = TC_851_862.port_a.T - TC_851_862.port_b.T; TC_851_862.port_a.Q_flow = TC_851_862.Q_flow; TC_851_862.port_b.Q_flow = -TC_851_862.Q_flow; TC_851_972.Q_flow = TC_851_972.G * TC_851_972.dT; TC_851_972.dT = TC_851_972.port_a.T - TC_851_972.port_b.T; TC_851_972.port_a.Q_flow = TC_851_972.Q_flow; TC_851_972.port_b.Q_flow = -TC_851_972.Q_flow; TC_851_1046.Q_flow = TC_851_1046.G * TC_851_1046.dT; TC_851_1046.dT = TC_851_1046.port_a.T - TC_851_1046.port_b.T; TC_851_1046.port_a.Q_flow = TC_851_1046.Q_flow; TC_851_1046.port_b.Q_flow = -TC_851_1046.Q_flow; TC_852_853.Q_flow = TC_852_853.G * TC_852_853.dT; TC_852_853.dT = TC_852_853.port_a.T - TC_852_853.port_b.T; TC_852_853.port_a.Q_flow = TC_852_853.Q_flow; TC_852_853.port_b.Q_flow = -TC_852_853.Q_flow; TC_852_863.Q_flow = TC_852_863.G * TC_852_863.dT; TC_852_863.dT = TC_852_863.port_a.T - TC_852_863.port_b.T; TC_852_863.port_a.Q_flow = TC_852_863.Q_flow; TC_852_863.port_b.Q_flow = -TC_852_863.Q_flow; TC_852_973.Q_flow = TC_852_973.G * TC_852_973.dT; TC_852_973.dT = TC_852_973.port_a.T - TC_852_973.port_b.T; TC_852_973.port_a.Q_flow = TC_852_973.Q_flow; TC_852_973.port_b.Q_flow = -TC_852_973.Q_flow; TC_852_1047.Q_flow = TC_852_1047.G * TC_852_1047.dT; TC_852_1047.dT = TC_852_1047.port_a.T - TC_852_1047.port_b.T; TC_852_1047.port_a.Q_flow = TC_852_1047.Q_flow; TC_852_1047.port_b.Q_flow = -TC_852_1047.Q_flow; TC_853_864.Q_flow = TC_853_864.G * TC_853_864.dT; TC_853_864.dT = TC_853_864.port_a.T - TC_853_864.port_b.T; TC_853_864.port_a.Q_flow = TC_853_864.Q_flow; TC_853_864.port_b.Q_flow = -TC_853_864.Q_flow; TC_853_974.Q_flow = TC_853_974.G * TC_853_974.dT; TC_853_974.dT = TC_853_974.port_a.T - TC_853_974.port_b.T; TC_853_974.port_a.Q_flow = TC_853_974.Q_flow; TC_853_974.port_b.Q_flow = -TC_853_974.Q_flow; TC_853_1048.Q_flow = TC_853_1048.G * TC_853_1048.dT; TC_853_1048.dT = TC_853_1048.port_a.T - TC_853_1048.port_b.T; TC_853_1048.port_a.Q_flow = TC_853_1048.Q_flow; TC_853_1048.port_b.Q_flow = -TC_853_1048.Q_flow; TC_854_855.Q_flow = TC_854_855.G * TC_854_855.dT; TC_854_855.dT = TC_854_855.port_a.T - TC_854_855.port_b.T; TC_854_855.port_a.Q_flow = TC_854_855.Q_flow; TC_854_855.port_b.Q_flow = -TC_854_855.Q_flow; TC_854_865.Q_flow = TC_854_865.G * TC_854_865.dT; TC_854_865.dT = TC_854_865.port_a.T - TC_854_865.port_b.T; TC_854_865.port_a.Q_flow = TC_854_865.Q_flow; TC_854_865.port_b.Q_flow = -TC_854_865.Q_flow; TC_854_1049.Q_flow = TC_854_1049.G * TC_854_1049.dT; TC_854_1049.dT = TC_854_1049.port_a.T - TC_854_1049.port_b.T; TC_854_1049.port_a.Q_flow = TC_854_1049.Q_flow; TC_854_1049.port_b.Q_flow = -TC_854_1049.Q_flow; TC_855_856.Q_flow = TC_855_856.G * TC_855_856.dT; TC_855_856.dT = TC_855_856.port_a.T - TC_855_856.port_b.T; TC_855_856.port_a.Q_flow = TC_855_856.Q_flow; TC_855_856.port_b.Q_flow = -TC_855_856.Q_flow; TC_855_866.Q_flow = TC_855_866.G * TC_855_866.dT; TC_855_866.dT = TC_855_866.port_a.T - TC_855_866.port_b.T; TC_855_866.port_a.Q_flow = TC_855_866.Q_flow; TC_855_866.port_b.Q_flow = -TC_855_866.Q_flow; TC_855_1050.Q_flow = TC_855_1050.G * TC_855_1050.dT; TC_855_1050.dT = TC_855_1050.port_a.T - TC_855_1050.port_b.T; TC_855_1050.port_a.Q_flow = TC_855_1050.Q_flow; TC_855_1050.port_b.Q_flow = -TC_855_1050.Q_flow; TC_856_857.Q_flow = TC_856_857.G * TC_856_857.dT; TC_856_857.dT = TC_856_857.port_a.T - TC_856_857.port_b.T; TC_856_857.port_a.Q_flow = TC_856_857.Q_flow; TC_856_857.port_b.Q_flow = -TC_856_857.Q_flow; TC_856_867.Q_flow = TC_856_867.G * TC_856_867.dT; TC_856_867.dT = TC_856_867.port_a.T - TC_856_867.port_b.T; TC_856_867.port_a.Q_flow = TC_856_867.Q_flow; TC_856_867.port_b.Q_flow = -TC_856_867.Q_flow; TC_856_1051.Q_flow = TC_856_1051.G * TC_856_1051.dT; TC_856_1051.dT = TC_856_1051.port_a.T - TC_856_1051.port_b.T; TC_856_1051.port_a.Q_flow = TC_856_1051.Q_flow; TC_856_1051.port_b.Q_flow = -TC_856_1051.Q_flow; TC_857_858.Q_flow = TC_857_858.G * TC_857_858.dT; TC_857_858.dT = TC_857_858.port_a.T - TC_857_858.port_b.T; TC_857_858.port_a.Q_flow = TC_857_858.Q_flow; TC_857_858.port_b.Q_flow = -TC_857_858.Q_flow; TC_857_868.Q_flow = TC_857_868.G * TC_857_868.dT; TC_857_868.dT = TC_857_868.port_a.T - TC_857_868.port_b.T; TC_857_868.port_a.Q_flow = TC_857_868.Q_flow; TC_857_868.port_b.Q_flow = -TC_857_868.Q_flow; TC_857_1052.Q_flow = TC_857_1052.G * TC_857_1052.dT; TC_857_1052.dT = TC_857_1052.port_a.T - TC_857_1052.port_b.T; TC_857_1052.port_a.Q_flow = TC_857_1052.Q_flow; TC_857_1052.port_b.Q_flow = -TC_857_1052.Q_flow; TC_858_859.Q_flow = TC_858_859.G * TC_858_859.dT; TC_858_859.dT = TC_858_859.port_a.T - TC_858_859.port_b.T; TC_858_859.port_a.Q_flow = TC_858_859.Q_flow; TC_858_859.port_b.Q_flow = -TC_858_859.Q_flow; TC_858_869.Q_flow = TC_858_869.G * TC_858_869.dT; TC_858_869.dT = TC_858_869.port_a.T - TC_858_869.port_b.T; TC_858_869.port_a.Q_flow = TC_858_869.Q_flow; TC_858_869.port_b.Q_flow = -TC_858_869.Q_flow; TC_858_1053.Q_flow = TC_858_1053.G * TC_858_1053.dT; TC_858_1053.dT = TC_858_1053.port_a.T - TC_858_1053.port_b.T; TC_858_1053.port_a.Q_flow = TC_858_1053.Q_flow; TC_858_1053.port_b.Q_flow = -TC_858_1053.Q_flow; TC_859_860.Q_flow = TC_859_860.G * TC_859_860.dT; TC_859_860.dT = TC_859_860.port_a.T - TC_859_860.port_b.T; TC_859_860.port_a.Q_flow = TC_859_860.Q_flow; TC_859_860.port_b.Q_flow = -TC_859_860.Q_flow; TC_859_870.Q_flow = TC_859_870.G * TC_859_870.dT; TC_859_870.dT = TC_859_870.port_a.T - TC_859_870.port_b.T; TC_859_870.port_a.Q_flow = TC_859_870.Q_flow; TC_859_870.port_b.Q_flow = -TC_859_870.Q_flow; TC_859_1054.Q_flow = TC_859_1054.G * TC_859_1054.dT; TC_859_1054.dT = TC_859_1054.port_a.T - TC_859_1054.port_b.T; TC_859_1054.port_a.Q_flow = TC_859_1054.Q_flow; TC_859_1054.port_b.Q_flow = -TC_859_1054.Q_flow; TC_860_861.Q_flow = TC_860_861.G * TC_860_861.dT; TC_860_861.dT = TC_860_861.port_a.T - TC_860_861.port_b.T; TC_860_861.port_a.Q_flow = TC_860_861.Q_flow; TC_860_861.port_b.Q_flow = -TC_860_861.Q_flow; TC_860_871.Q_flow = TC_860_871.G * TC_860_871.dT; TC_860_871.dT = TC_860_871.port_a.T - TC_860_871.port_b.T; TC_860_871.port_a.Q_flow = TC_860_871.Q_flow; TC_860_871.port_b.Q_flow = -TC_860_871.Q_flow; TC_860_1055.Q_flow = TC_860_1055.G * TC_860_1055.dT; TC_860_1055.dT = TC_860_1055.port_a.T - TC_860_1055.port_b.T; TC_860_1055.port_a.Q_flow = TC_860_1055.Q_flow; TC_860_1055.port_b.Q_flow = -TC_860_1055.Q_flow; TC_861_862.Q_flow = TC_861_862.G * TC_861_862.dT; TC_861_862.dT = TC_861_862.port_a.T - TC_861_862.port_b.T; TC_861_862.port_a.Q_flow = TC_861_862.Q_flow; TC_861_862.port_b.Q_flow = -TC_861_862.Q_flow; TC_861_872.Q_flow = TC_861_872.G * TC_861_872.dT; TC_861_872.dT = TC_861_872.port_a.T - TC_861_872.port_b.T; TC_861_872.port_a.Q_flow = TC_861_872.Q_flow; TC_861_872.port_b.Q_flow = -TC_861_872.Q_flow; TC_861_1056.Q_flow = TC_861_1056.G * TC_861_1056.dT; TC_861_1056.dT = TC_861_1056.port_a.T - TC_861_1056.port_b.T; TC_861_1056.port_a.Q_flow = TC_861_1056.Q_flow; TC_861_1056.port_b.Q_flow = -TC_861_1056.Q_flow; TC_862_863.Q_flow = TC_862_863.G * TC_862_863.dT; TC_862_863.dT = TC_862_863.port_a.T - TC_862_863.port_b.T; TC_862_863.port_a.Q_flow = TC_862_863.Q_flow; TC_862_863.port_b.Q_flow = -TC_862_863.Q_flow; TC_862_873.Q_flow = TC_862_873.G * TC_862_873.dT; TC_862_873.dT = TC_862_873.port_a.T - TC_862_873.port_b.T; TC_862_873.port_a.Q_flow = TC_862_873.Q_flow; TC_862_873.port_b.Q_flow = -TC_862_873.Q_flow; TC_862_1057.Q_flow = TC_862_1057.G * TC_862_1057.dT; TC_862_1057.dT = TC_862_1057.port_a.T - TC_862_1057.port_b.T; TC_862_1057.port_a.Q_flow = TC_862_1057.Q_flow; TC_862_1057.port_b.Q_flow = -TC_862_1057.Q_flow; TC_863_864.Q_flow = TC_863_864.G * TC_863_864.dT; TC_863_864.dT = TC_863_864.port_a.T - TC_863_864.port_b.T; TC_863_864.port_a.Q_flow = TC_863_864.Q_flow; TC_863_864.port_b.Q_flow = -TC_863_864.Q_flow; TC_863_874.Q_flow = TC_863_874.G * TC_863_874.dT; TC_863_874.dT = TC_863_874.port_a.T - TC_863_874.port_b.T; TC_863_874.port_a.Q_flow = TC_863_874.Q_flow; TC_863_874.port_b.Q_flow = -TC_863_874.Q_flow; TC_863_1058.Q_flow = TC_863_1058.G * TC_863_1058.dT; TC_863_1058.dT = TC_863_1058.port_a.T - TC_863_1058.port_b.T; TC_863_1058.port_a.Q_flow = TC_863_1058.Q_flow; TC_863_1058.port_b.Q_flow = -TC_863_1058.Q_flow; TC_864_875.Q_flow = TC_864_875.G * TC_864_875.dT; TC_864_875.dT = TC_864_875.port_a.T - TC_864_875.port_b.T; TC_864_875.port_a.Q_flow = TC_864_875.Q_flow; TC_864_875.port_b.Q_flow = -TC_864_875.Q_flow; TC_864_1059.Q_flow = TC_864_1059.G * TC_864_1059.dT; TC_864_1059.dT = TC_864_1059.port_a.T - TC_864_1059.port_b.T; TC_864_1059.port_a.Q_flow = TC_864_1059.Q_flow; TC_864_1059.port_b.Q_flow = -TC_864_1059.Q_flow; TC_865_866.Q_flow = TC_865_866.G * TC_865_866.dT; TC_865_866.dT = TC_865_866.port_a.T - TC_865_866.port_b.T; TC_865_866.port_a.Q_flow = TC_865_866.Q_flow; TC_865_866.port_b.Q_flow = -TC_865_866.Q_flow; TC_865_876.Q_flow = TC_865_876.G * TC_865_876.dT; TC_865_876.dT = TC_865_876.port_a.T - TC_865_876.port_b.T; TC_865_876.port_a.Q_flow = TC_865_876.Q_flow; TC_865_876.port_b.Q_flow = -TC_865_876.Q_flow; TC_865_1060.Q_flow = TC_865_1060.G * TC_865_1060.dT; TC_865_1060.dT = TC_865_1060.port_a.T - TC_865_1060.port_b.T; TC_865_1060.port_a.Q_flow = TC_865_1060.Q_flow; TC_865_1060.port_b.Q_flow = -TC_865_1060.Q_flow; TC_866_867.Q_flow = TC_866_867.G * TC_866_867.dT; TC_866_867.dT = TC_866_867.port_a.T - TC_866_867.port_b.T; TC_866_867.port_a.Q_flow = TC_866_867.Q_flow; TC_866_867.port_b.Q_flow = -TC_866_867.Q_flow; TC_866_877.Q_flow = TC_866_877.G * TC_866_877.dT; TC_866_877.dT = TC_866_877.port_a.T - TC_866_877.port_b.T; TC_866_877.port_a.Q_flow = TC_866_877.Q_flow; TC_866_877.port_b.Q_flow = -TC_866_877.Q_flow; TC_866_1061.Q_flow = TC_866_1061.G * TC_866_1061.dT; TC_866_1061.dT = TC_866_1061.port_a.T - TC_866_1061.port_b.T; TC_866_1061.port_a.Q_flow = TC_866_1061.Q_flow; TC_866_1061.port_b.Q_flow = -TC_866_1061.Q_flow; TC_867_868.Q_flow = TC_867_868.G * TC_867_868.dT; TC_867_868.dT = TC_867_868.port_a.T - TC_867_868.port_b.T; TC_867_868.port_a.Q_flow = TC_867_868.Q_flow; TC_867_868.port_b.Q_flow = -TC_867_868.Q_flow; TC_867_878.Q_flow = TC_867_878.G * TC_867_878.dT; TC_867_878.dT = TC_867_878.port_a.T - TC_867_878.port_b.T; TC_867_878.port_a.Q_flow = TC_867_878.Q_flow; TC_867_878.port_b.Q_flow = -TC_867_878.Q_flow; TC_867_1062.Q_flow = TC_867_1062.G * TC_867_1062.dT; TC_867_1062.dT = TC_867_1062.port_a.T - TC_867_1062.port_b.T; TC_867_1062.port_a.Q_flow = TC_867_1062.Q_flow; TC_867_1062.port_b.Q_flow = -TC_867_1062.Q_flow; TC_868_869.Q_flow = TC_868_869.G * TC_868_869.dT; TC_868_869.dT = TC_868_869.port_a.T - TC_868_869.port_b.T; TC_868_869.port_a.Q_flow = TC_868_869.Q_flow; TC_868_869.port_b.Q_flow = -TC_868_869.Q_flow; TC_868_879.Q_flow = TC_868_879.G * TC_868_879.dT; TC_868_879.dT = TC_868_879.port_a.T - TC_868_879.port_b.T; TC_868_879.port_a.Q_flow = TC_868_879.Q_flow; TC_868_879.port_b.Q_flow = -TC_868_879.Q_flow; TC_868_1063.Q_flow = TC_868_1063.G * TC_868_1063.dT; TC_868_1063.dT = TC_868_1063.port_a.T - TC_868_1063.port_b.T; TC_868_1063.port_a.Q_flow = TC_868_1063.Q_flow; TC_868_1063.port_b.Q_flow = -TC_868_1063.Q_flow; TC_869_870.Q_flow = TC_869_870.G * TC_869_870.dT; TC_869_870.dT = TC_869_870.port_a.T - TC_869_870.port_b.T; TC_869_870.port_a.Q_flow = TC_869_870.Q_flow; TC_869_870.port_b.Q_flow = -TC_869_870.Q_flow; TC_869_880.Q_flow = TC_869_880.G * TC_869_880.dT; TC_869_880.dT = TC_869_880.port_a.T - TC_869_880.port_b.T; TC_869_880.port_a.Q_flow = TC_869_880.Q_flow; TC_869_880.port_b.Q_flow = -TC_869_880.Q_flow; TC_869_1064.Q_flow = TC_869_1064.G * TC_869_1064.dT; TC_869_1064.dT = TC_869_1064.port_a.T - TC_869_1064.port_b.T; TC_869_1064.port_a.Q_flow = TC_869_1064.Q_flow; TC_869_1064.port_b.Q_flow = -TC_869_1064.Q_flow; TC_870_871.Q_flow = TC_870_871.G * TC_870_871.dT; TC_870_871.dT = TC_870_871.port_a.T - TC_870_871.port_b.T; TC_870_871.port_a.Q_flow = TC_870_871.Q_flow; TC_870_871.port_b.Q_flow = -TC_870_871.Q_flow; TC_870_881.Q_flow = TC_870_881.G * TC_870_881.dT; TC_870_881.dT = TC_870_881.port_a.T - TC_870_881.port_b.T; TC_870_881.port_a.Q_flow = TC_870_881.Q_flow; TC_870_881.port_b.Q_flow = -TC_870_881.Q_flow; TC_870_1065.Q_flow = TC_870_1065.G * TC_870_1065.dT; TC_870_1065.dT = TC_870_1065.port_a.T - TC_870_1065.port_b.T; TC_870_1065.port_a.Q_flow = TC_870_1065.Q_flow; TC_870_1065.port_b.Q_flow = -TC_870_1065.Q_flow; TC_871_872.Q_flow = TC_871_872.G * TC_871_872.dT; TC_871_872.dT = TC_871_872.port_a.T - TC_871_872.port_b.T; TC_871_872.port_a.Q_flow = TC_871_872.Q_flow; TC_871_872.port_b.Q_flow = -TC_871_872.Q_flow; TC_871_882.Q_flow = TC_871_882.G * TC_871_882.dT; TC_871_882.dT = TC_871_882.port_a.T - TC_871_882.port_b.T; TC_871_882.port_a.Q_flow = TC_871_882.Q_flow; TC_871_882.port_b.Q_flow = -TC_871_882.Q_flow; TC_871_1647.Q_flow = TC_871_1647.G * TC_871_1647.dT; TC_871_1647.dT = TC_871_1647.port_a.T - TC_871_1647.port_b.T; TC_871_1647.port_a.Q_flow = TC_871_1647.Q_flow; TC_871_1647.port_b.Q_flow = -TC_871_1647.Q_flow; TC_872_873.Q_flow = TC_872_873.G * TC_872_873.dT; TC_872_873.dT = TC_872_873.port_a.T - TC_872_873.port_b.T; TC_872_873.port_a.Q_flow = TC_872_873.Q_flow; TC_872_873.port_b.Q_flow = -TC_872_873.Q_flow; TC_872_883.Q_flow = TC_872_883.G * TC_872_883.dT; TC_872_883.dT = TC_872_883.port_a.T - TC_872_883.port_b.T; TC_872_883.port_a.Q_flow = TC_872_883.Q_flow; TC_872_883.port_b.Q_flow = -TC_872_883.Q_flow; TC_872_1648.Q_flow = TC_872_1648.G * TC_872_1648.dT; TC_872_1648.dT = TC_872_1648.port_a.T - TC_872_1648.port_b.T; TC_872_1648.port_a.Q_flow = TC_872_1648.Q_flow; TC_872_1648.port_b.Q_flow = -TC_872_1648.Q_flow; TC_873_874.Q_flow = TC_873_874.G * TC_873_874.dT; TC_873_874.dT = TC_873_874.port_a.T - TC_873_874.port_b.T; TC_873_874.port_a.Q_flow = TC_873_874.Q_flow; TC_873_874.port_b.Q_flow = -TC_873_874.Q_flow; TC_873_884.Q_flow = TC_873_884.G * TC_873_884.dT; TC_873_884.dT = TC_873_884.port_a.T - TC_873_884.port_b.T; TC_873_884.port_a.Q_flow = TC_873_884.Q_flow; TC_873_884.port_b.Q_flow = -TC_873_884.Q_flow; TC_873_1649.Q_flow = TC_873_1649.G * TC_873_1649.dT; TC_873_1649.dT = TC_873_1649.port_a.T - TC_873_1649.port_b.T; TC_873_1649.port_a.Q_flow = TC_873_1649.Q_flow; TC_873_1649.port_b.Q_flow = -TC_873_1649.Q_flow; TC_874_875.Q_flow = TC_874_875.G * TC_874_875.dT; TC_874_875.dT = TC_874_875.port_a.T - TC_874_875.port_b.T; TC_874_875.port_a.Q_flow = TC_874_875.Q_flow; TC_874_875.port_b.Q_flow = -TC_874_875.Q_flow; TC_874_885.Q_flow = TC_874_885.G * TC_874_885.dT; TC_874_885.dT = TC_874_885.port_a.T - TC_874_885.port_b.T; TC_874_885.port_a.Q_flow = TC_874_885.Q_flow; TC_874_885.port_b.Q_flow = -TC_874_885.Q_flow; TC_874_975.Q_flow = TC_874_975.G * TC_874_975.dT; TC_874_975.dT = TC_874_975.port_a.T - TC_874_975.port_b.T; TC_874_975.port_a.Q_flow = TC_874_975.Q_flow; TC_874_975.port_b.Q_flow = -TC_874_975.Q_flow; TC_875_886.Q_flow = TC_875_886.G * TC_875_886.dT; TC_875_886.dT = TC_875_886.port_a.T - TC_875_886.port_b.T; TC_875_886.port_a.Q_flow = TC_875_886.Q_flow; TC_875_886.port_b.Q_flow = -TC_875_886.Q_flow; TC_875_976.Q_flow = TC_875_976.G * TC_875_976.dT; TC_875_976.dT = TC_875_976.port_a.T - TC_875_976.port_b.T; TC_875_976.port_a.Q_flow = TC_875_976.Q_flow; TC_875_976.port_b.Q_flow = -TC_875_976.Q_flow; TC_876_877.Q_flow = TC_876_877.G * TC_876_877.dT; TC_876_877.dT = TC_876_877.port_a.T - TC_876_877.port_b.T; TC_876_877.port_a.Q_flow = TC_876_877.Q_flow; TC_876_877.port_b.Q_flow = -TC_876_877.Q_flow; TC_876_887.Q_flow = TC_876_887.G * TC_876_887.dT; TC_876_887.dT = TC_876_887.port_a.T - TC_876_887.port_b.T; TC_876_887.port_a.Q_flow = TC_876_887.Q_flow; TC_876_887.port_b.Q_flow = -TC_876_887.Q_flow; TC_876_977.Q_flow = TC_876_977.G * TC_876_977.dT; TC_876_977.dT = TC_876_977.port_a.T - TC_876_977.port_b.T; TC_876_977.port_a.Q_flow = TC_876_977.Q_flow; TC_876_977.port_b.Q_flow = -TC_876_977.Q_flow; TC_877_878.Q_flow = TC_877_878.G * TC_877_878.dT; TC_877_878.dT = TC_877_878.port_a.T - TC_877_878.port_b.T; TC_877_878.port_a.Q_flow = TC_877_878.Q_flow; TC_877_878.port_b.Q_flow = -TC_877_878.Q_flow; TC_877_888.Q_flow = TC_877_888.G * TC_877_888.dT; TC_877_888.dT = TC_877_888.port_a.T - TC_877_888.port_b.T; TC_877_888.port_a.Q_flow = TC_877_888.Q_flow; TC_877_888.port_b.Q_flow = -TC_877_888.Q_flow; TC_877_978.Q_flow = TC_877_978.G * TC_877_978.dT; TC_877_978.dT = TC_877_978.port_a.T - TC_877_978.port_b.T; TC_877_978.port_a.Q_flow = TC_877_978.Q_flow; TC_877_978.port_b.Q_flow = -TC_877_978.Q_flow; TC_878_879.Q_flow = TC_878_879.G * TC_878_879.dT; TC_878_879.dT = TC_878_879.port_a.T - TC_878_879.port_b.T; TC_878_879.port_a.Q_flow = TC_878_879.Q_flow; TC_878_879.port_b.Q_flow = -TC_878_879.Q_flow; TC_878_889.Q_flow = TC_878_889.G * TC_878_889.dT; TC_878_889.dT = TC_878_889.port_a.T - TC_878_889.port_b.T; TC_878_889.port_a.Q_flow = TC_878_889.Q_flow; TC_878_889.port_b.Q_flow = -TC_878_889.Q_flow; TC_878_979.Q_flow = TC_878_979.G * TC_878_979.dT; TC_878_979.dT = TC_878_979.port_a.T - TC_878_979.port_b.T; TC_878_979.port_a.Q_flow = TC_878_979.Q_flow; TC_878_979.port_b.Q_flow = -TC_878_979.Q_flow; TC_879_880.Q_flow = TC_879_880.G * TC_879_880.dT; TC_879_880.dT = TC_879_880.port_a.T - TC_879_880.port_b.T; TC_879_880.port_a.Q_flow = TC_879_880.Q_flow; TC_879_880.port_b.Q_flow = -TC_879_880.Q_flow; TC_879_890.Q_flow = TC_879_890.G * TC_879_890.dT; TC_879_890.dT = TC_879_890.port_a.T - TC_879_890.port_b.T; TC_879_890.port_a.Q_flow = TC_879_890.Q_flow; TC_879_890.port_b.Q_flow = -TC_879_890.Q_flow; TC_879_980.Q_flow = TC_879_980.G * TC_879_980.dT; TC_879_980.dT = TC_879_980.port_a.T - TC_879_980.port_b.T; TC_879_980.port_a.Q_flow = TC_879_980.Q_flow; TC_879_980.port_b.Q_flow = -TC_879_980.Q_flow; TC_880_881.Q_flow = TC_880_881.G * TC_880_881.dT; TC_880_881.dT = TC_880_881.port_a.T - TC_880_881.port_b.T; TC_880_881.port_a.Q_flow = TC_880_881.Q_flow; TC_880_881.port_b.Q_flow = -TC_880_881.Q_flow; TC_880_891.Q_flow = TC_880_891.G * TC_880_891.dT; TC_880_891.dT = TC_880_891.port_a.T - TC_880_891.port_b.T; TC_880_891.port_a.Q_flow = TC_880_891.Q_flow; TC_880_891.port_b.Q_flow = -TC_880_891.Q_flow; TC_880_981.Q_flow = TC_880_981.G * TC_880_981.dT; TC_880_981.dT = TC_880_981.port_a.T - TC_880_981.port_b.T; TC_880_981.port_a.Q_flow = TC_880_981.Q_flow; TC_880_981.port_b.Q_flow = -TC_880_981.Q_flow; TC_881_882.Q_flow = TC_881_882.G * TC_881_882.dT; TC_881_882.dT = TC_881_882.port_a.T - TC_881_882.port_b.T; TC_881_882.port_a.Q_flow = TC_881_882.Q_flow; TC_881_882.port_b.Q_flow = -TC_881_882.Q_flow; TC_881_892.Q_flow = TC_881_892.G * TC_881_892.dT; TC_881_892.dT = TC_881_892.port_a.T - TC_881_892.port_b.T; TC_881_892.port_a.Q_flow = TC_881_892.Q_flow; TC_881_892.port_b.Q_flow = -TC_881_892.Q_flow; TC_881_982.Q_flow = TC_881_982.G * TC_881_982.dT; TC_881_982.dT = TC_881_982.port_a.T - TC_881_982.port_b.T; TC_881_982.port_a.Q_flow = TC_881_982.Q_flow; TC_881_982.port_b.Q_flow = -TC_881_982.Q_flow; TC_882_883.Q_flow = TC_882_883.G * TC_882_883.dT; TC_882_883.dT = TC_882_883.port_a.T - TC_882_883.port_b.T; TC_882_883.port_a.Q_flow = TC_882_883.Q_flow; TC_882_883.port_b.Q_flow = -TC_882_883.Q_flow; TC_882_893.Q_flow = TC_882_893.G * TC_882_893.dT; TC_882_893.dT = TC_882_893.port_a.T - TC_882_893.port_b.T; TC_882_893.port_a.Q_flow = TC_882_893.Q_flow; TC_882_893.port_b.Q_flow = -TC_882_893.Q_flow; TC_882_1650.Q_flow = TC_882_1650.G * TC_882_1650.dT; TC_882_1650.dT = TC_882_1650.port_a.T - TC_882_1650.port_b.T; TC_882_1650.port_a.Q_flow = TC_882_1650.Q_flow; TC_882_1650.port_b.Q_flow = -TC_882_1650.Q_flow; TC_883_884.Q_flow = TC_883_884.G * TC_883_884.dT; TC_883_884.dT = TC_883_884.port_a.T - TC_883_884.port_b.T; TC_883_884.port_a.Q_flow = TC_883_884.Q_flow; TC_883_884.port_b.Q_flow = -TC_883_884.Q_flow; TC_883_894.Q_flow = TC_883_894.G * TC_883_894.dT; TC_883_894.dT = TC_883_894.port_a.T - TC_883_894.port_b.T; TC_883_894.port_a.Q_flow = TC_883_894.Q_flow; TC_883_894.port_b.Q_flow = -TC_883_894.Q_flow; TC_883_1651.Q_flow = TC_883_1651.G * TC_883_1651.dT; TC_883_1651.dT = TC_883_1651.port_a.T - TC_883_1651.port_b.T; TC_883_1651.port_a.Q_flow = TC_883_1651.Q_flow; TC_883_1651.port_b.Q_flow = -TC_883_1651.Q_flow; TC_884_885.Q_flow = TC_884_885.G * TC_884_885.dT; TC_884_885.dT = TC_884_885.port_a.T - TC_884_885.port_b.T; TC_884_885.port_a.Q_flow = TC_884_885.Q_flow; TC_884_885.port_b.Q_flow = -TC_884_885.Q_flow; TC_884_895.Q_flow = TC_884_895.G * TC_884_895.dT; TC_884_895.dT = TC_884_895.port_a.T - TC_884_895.port_b.T; TC_884_895.port_a.Q_flow = TC_884_895.Q_flow; TC_884_895.port_b.Q_flow = -TC_884_895.Q_flow; TC_884_1652.Q_flow = TC_884_1652.G * TC_884_1652.dT; TC_884_1652.dT = TC_884_1652.port_a.T - TC_884_1652.port_b.T; TC_884_1652.port_a.Q_flow = TC_884_1652.Q_flow; TC_884_1652.port_b.Q_flow = -TC_884_1652.Q_flow; TC_885_886.Q_flow = TC_885_886.G * TC_885_886.dT; TC_885_886.dT = TC_885_886.port_a.T - TC_885_886.port_b.T; TC_885_886.port_a.Q_flow = TC_885_886.Q_flow; TC_885_886.port_b.Q_flow = -TC_885_886.Q_flow; TC_885_896.Q_flow = TC_885_896.G * TC_885_896.dT; TC_885_896.dT = TC_885_896.port_a.T - TC_885_896.port_b.T; TC_885_896.port_a.Q_flow = TC_885_896.Q_flow; TC_885_896.port_b.Q_flow = -TC_885_896.Q_flow; TC_885_983.Q_flow = TC_885_983.G * TC_885_983.dT; TC_885_983.dT = TC_885_983.port_a.T - TC_885_983.port_b.T; TC_885_983.port_a.Q_flow = TC_885_983.Q_flow; TC_885_983.port_b.Q_flow = -TC_885_983.Q_flow; TC_886_897.Q_flow = TC_886_897.G * TC_886_897.dT; TC_886_897.dT = TC_886_897.port_a.T - TC_886_897.port_b.T; TC_886_897.port_a.Q_flow = TC_886_897.Q_flow; TC_886_897.port_b.Q_flow = -TC_886_897.Q_flow; TC_886_984.Q_flow = TC_886_984.G * TC_886_984.dT; TC_886_984.dT = TC_886_984.port_a.T - TC_886_984.port_b.T; TC_886_984.port_a.Q_flow = TC_886_984.Q_flow; TC_886_984.port_b.Q_flow = -TC_886_984.Q_flow; TC_887_888.Q_flow = TC_887_888.G * TC_887_888.dT; TC_887_888.dT = TC_887_888.port_a.T - TC_887_888.port_b.T; TC_887_888.port_a.Q_flow = TC_887_888.Q_flow; TC_887_888.port_b.Q_flow = -TC_887_888.Q_flow; TC_887_898.Q_flow = TC_887_898.G * TC_887_898.dT; TC_887_898.dT = TC_887_898.port_a.T - TC_887_898.port_b.T; TC_887_898.port_a.Q_flow = TC_887_898.Q_flow; TC_887_898.port_b.Q_flow = -TC_887_898.Q_flow; TC_887_985.Q_flow = TC_887_985.G * TC_887_985.dT; TC_887_985.dT = TC_887_985.port_a.T - TC_887_985.port_b.T; TC_887_985.port_a.Q_flow = TC_887_985.Q_flow; TC_887_985.port_b.Q_flow = -TC_887_985.Q_flow; TC_888_889.Q_flow = TC_888_889.G * TC_888_889.dT; TC_888_889.dT = TC_888_889.port_a.T - TC_888_889.port_b.T; TC_888_889.port_a.Q_flow = TC_888_889.Q_flow; TC_888_889.port_b.Q_flow = -TC_888_889.Q_flow; TC_888_899.Q_flow = TC_888_899.G * TC_888_899.dT; TC_888_899.dT = TC_888_899.port_a.T - TC_888_899.port_b.T; TC_888_899.port_a.Q_flow = TC_888_899.Q_flow; TC_888_899.port_b.Q_flow = -TC_888_899.Q_flow; TC_888_986.Q_flow = TC_888_986.G * TC_888_986.dT; TC_888_986.dT = TC_888_986.port_a.T - TC_888_986.port_b.T; TC_888_986.port_a.Q_flow = TC_888_986.Q_flow; TC_888_986.port_b.Q_flow = -TC_888_986.Q_flow; TC_889_890.Q_flow = TC_889_890.G * TC_889_890.dT; TC_889_890.dT = TC_889_890.port_a.T - TC_889_890.port_b.T; TC_889_890.port_a.Q_flow = TC_889_890.Q_flow; TC_889_890.port_b.Q_flow = -TC_889_890.Q_flow; TC_889_900.Q_flow = TC_889_900.G * TC_889_900.dT; TC_889_900.dT = TC_889_900.port_a.T - TC_889_900.port_b.T; TC_889_900.port_a.Q_flow = TC_889_900.Q_flow; TC_889_900.port_b.Q_flow = -TC_889_900.Q_flow; TC_889_1656.Q_flow = TC_889_1656.G * TC_889_1656.dT; TC_889_1656.dT = TC_889_1656.port_a.T - TC_889_1656.port_b.T; TC_889_1656.port_a.Q_flow = TC_889_1656.Q_flow; TC_889_1656.port_b.Q_flow = -TC_889_1656.Q_flow; TC_890_891.Q_flow = TC_890_891.G * TC_890_891.dT; TC_890_891.dT = TC_890_891.port_a.T - TC_890_891.port_b.T; TC_890_891.port_a.Q_flow = TC_890_891.Q_flow; TC_890_891.port_b.Q_flow = -TC_890_891.Q_flow; TC_890_901.Q_flow = TC_890_901.G * TC_890_901.dT; TC_890_901.dT = TC_890_901.port_a.T - TC_890_901.port_b.T; TC_890_901.port_a.Q_flow = TC_890_901.Q_flow; TC_890_901.port_b.Q_flow = -TC_890_901.Q_flow; TC_890_1657.Q_flow = TC_890_1657.G * TC_890_1657.dT; TC_890_1657.dT = TC_890_1657.port_a.T - TC_890_1657.port_b.T; TC_890_1657.port_a.Q_flow = TC_890_1657.Q_flow; TC_890_1657.port_b.Q_flow = -TC_890_1657.Q_flow; TC_891_892.Q_flow = TC_891_892.G * TC_891_892.dT; TC_891_892.dT = TC_891_892.port_a.T - TC_891_892.port_b.T; TC_891_892.port_a.Q_flow = TC_891_892.Q_flow; TC_891_892.port_b.Q_flow = -TC_891_892.Q_flow; TC_891_902.Q_flow = TC_891_902.G * TC_891_902.dT; TC_891_902.dT = TC_891_902.port_a.T - TC_891_902.port_b.T; TC_891_902.port_a.Q_flow = TC_891_902.Q_flow; TC_891_902.port_b.Q_flow = -TC_891_902.Q_flow; TC_891_1658.Q_flow = TC_891_1658.G * TC_891_1658.dT; TC_891_1658.dT = TC_891_1658.port_a.T - TC_891_1658.port_b.T; TC_891_1658.port_a.Q_flow = TC_891_1658.Q_flow; TC_891_1658.port_b.Q_flow = -TC_891_1658.Q_flow; TC_892_893.Q_flow = TC_892_893.G * TC_892_893.dT; TC_892_893.dT = TC_892_893.port_a.T - TC_892_893.port_b.T; TC_892_893.port_a.Q_flow = TC_892_893.Q_flow; TC_892_893.port_b.Q_flow = -TC_892_893.Q_flow; TC_892_903.Q_flow = TC_892_903.G * TC_892_903.dT; TC_892_903.dT = TC_892_903.port_a.T - TC_892_903.port_b.T; TC_892_903.port_a.Q_flow = TC_892_903.Q_flow; TC_892_903.port_b.Q_flow = -TC_892_903.Q_flow; TC_892_987.Q_flow = TC_892_987.G * TC_892_987.dT; TC_892_987.dT = TC_892_987.port_a.T - TC_892_987.port_b.T; TC_892_987.port_a.Q_flow = TC_892_987.Q_flow; TC_892_987.port_b.Q_flow = -TC_892_987.Q_flow; TC_893_894.Q_flow = TC_893_894.G * TC_893_894.dT; TC_893_894.dT = TC_893_894.port_a.T - TC_893_894.port_b.T; TC_893_894.port_a.Q_flow = TC_893_894.Q_flow; TC_893_894.port_b.Q_flow = -TC_893_894.Q_flow; TC_893_904.Q_flow = TC_893_904.G * TC_893_904.dT; TC_893_904.dT = TC_893_904.port_a.T - TC_893_904.port_b.T; TC_893_904.port_a.Q_flow = TC_893_904.Q_flow; TC_893_904.port_b.Q_flow = -TC_893_904.Q_flow; TC_893_1653.Q_flow = TC_893_1653.G * TC_893_1653.dT; TC_893_1653.dT = TC_893_1653.port_a.T - TC_893_1653.port_b.T; TC_893_1653.port_a.Q_flow = TC_893_1653.Q_flow; TC_893_1653.port_b.Q_flow = -TC_893_1653.Q_flow; TC_894_895.Q_flow = TC_894_895.G * TC_894_895.dT; TC_894_895.dT = TC_894_895.port_a.T - TC_894_895.port_b.T; TC_894_895.port_a.Q_flow = TC_894_895.Q_flow; TC_894_895.port_b.Q_flow = -TC_894_895.Q_flow; TC_894_905.Q_flow = TC_894_905.G * TC_894_905.dT; TC_894_905.dT = TC_894_905.port_a.T - TC_894_905.port_b.T; TC_894_905.port_a.Q_flow = TC_894_905.Q_flow; TC_894_905.port_b.Q_flow = -TC_894_905.Q_flow; TC_894_1654.Q_flow = TC_894_1654.G * TC_894_1654.dT; TC_894_1654.dT = TC_894_1654.port_a.T - TC_894_1654.port_b.T; TC_894_1654.port_a.Q_flow = TC_894_1654.Q_flow; TC_894_1654.port_b.Q_flow = -TC_894_1654.Q_flow; TC_895_896.Q_flow = TC_895_896.G * TC_895_896.dT; TC_895_896.dT = TC_895_896.port_a.T - TC_895_896.port_b.T; TC_895_896.port_a.Q_flow = TC_895_896.Q_flow; TC_895_896.port_b.Q_flow = -TC_895_896.Q_flow; TC_895_906.Q_flow = TC_895_906.G * TC_895_906.dT; TC_895_906.dT = TC_895_906.port_a.T - TC_895_906.port_b.T; TC_895_906.port_a.Q_flow = TC_895_906.Q_flow; TC_895_906.port_b.Q_flow = -TC_895_906.Q_flow; TC_895_1655.Q_flow = TC_895_1655.G * TC_895_1655.dT; TC_895_1655.dT = TC_895_1655.port_a.T - TC_895_1655.port_b.T; TC_895_1655.port_a.Q_flow = TC_895_1655.Q_flow; TC_895_1655.port_b.Q_flow = -TC_895_1655.Q_flow; TC_896_897.Q_flow = TC_896_897.G * TC_896_897.dT; TC_896_897.dT = TC_896_897.port_a.T - TC_896_897.port_b.T; TC_896_897.port_a.Q_flow = TC_896_897.Q_flow; TC_896_897.port_b.Q_flow = -TC_896_897.Q_flow; TC_896_907.Q_flow = TC_896_907.G * TC_896_907.dT; TC_896_907.dT = TC_896_907.port_a.T - TC_896_907.port_b.T; TC_896_907.port_a.Q_flow = TC_896_907.Q_flow; TC_896_907.port_b.Q_flow = -TC_896_907.Q_flow; TC_896_988.Q_flow = TC_896_988.G * TC_896_988.dT; TC_896_988.dT = TC_896_988.port_a.T - TC_896_988.port_b.T; TC_896_988.port_a.Q_flow = TC_896_988.Q_flow; TC_896_988.port_b.Q_flow = -TC_896_988.Q_flow; TC_897_908.Q_flow = TC_897_908.G * TC_897_908.dT; TC_897_908.dT = TC_897_908.port_a.T - TC_897_908.port_b.T; TC_897_908.port_a.Q_flow = TC_897_908.Q_flow; TC_897_908.port_b.Q_flow = -TC_897_908.Q_flow; TC_897_989.Q_flow = TC_897_989.G * TC_897_989.dT; TC_897_989.dT = TC_897_989.port_a.T - TC_897_989.port_b.T; TC_897_989.port_a.Q_flow = TC_897_989.Q_flow; TC_897_989.port_b.Q_flow = -TC_897_989.Q_flow; TC_898_899.Q_flow = TC_898_899.G * TC_898_899.dT; TC_898_899.dT = TC_898_899.port_a.T - TC_898_899.port_b.T; TC_898_899.port_a.Q_flow = TC_898_899.Q_flow; TC_898_899.port_b.Q_flow = -TC_898_899.Q_flow; TC_898_909.Q_flow = TC_898_909.G * TC_898_909.dT; TC_898_909.dT = TC_898_909.port_a.T - TC_898_909.port_b.T; TC_898_909.port_a.Q_flow = TC_898_909.Q_flow; TC_898_909.port_b.Q_flow = -TC_898_909.Q_flow; TC_898_990.Q_flow = TC_898_990.G * TC_898_990.dT; TC_898_990.dT = TC_898_990.port_a.T - TC_898_990.port_b.T; TC_898_990.port_a.Q_flow = TC_898_990.Q_flow; TC_898_990.port_b.Q_flow = -TC_898_990.Q_flow; TC_899_900.Q_flow = TC_899_900.G * TC_899_900.dT; TC_899_900.dT = TC_899_900.port_a.T - TC_899_900.port_b.T; TC_899_900.port_a.Q_flow = TC_899_900.Q_flow; TC_899_900.port_b.Q_flow = -TC_899_900.Q_flow; TC_899_910.Q_flow = TC_899_910.G * TC_899_910.dT; TC_899_910.dT = TC_899_910.port_a.T - TC_899_910.port_b.T; TC_899_910.port_a.Q_flow = TC_899_910.Q_flow; TC_899_910.port_b.Q_flow = -TC_899_910.Q_flow; TC_899_991.Q_flow = TC_899_991.G * TC_899_991.dT; TC_899_991.dT = TC_899_991.port_a.T - TC_899_991.port_b.T; TC_899_991.port_a.Q_flow = TC_899_991.Q_flow; TC_899_991.port_b.Q_flow = -TC_899_991.Q_flow; TC_900_901.Q_flow = TC_900_901.G * TC_900_901.dT; TC_900_901.dT = TC_900_901.port_a.T - TC_900_901.port_b.T; TC_900_901.port_a.Q_flow = TC_900_901.Q_flow; TC_900_901.port_b.Q_flow = -TC_900_901.Q_flow; TC_900_911.Q_flow = TC_900_911.G * TC_900_911.dT; TC_900_911.dT = TC_900_911.port_a.T - TC_900_911.port_b.T; TC_900_911.port_a.Q_flow = TC_900_911.Q_flow; TC_900_911.port_b.Q_flow = -TC_900_911.Q_flow; TC_900_1659.Q_flow = TC_900_1659.G * TC_900_1659.dT; TC_900_1659.dT = TC_900_1659.port_a.T - TC_900_1659.port_b.T; TC_900_1659.port_a.Q_flow = TC_900_1659.Q_flow; TC_900_1659.port_b.Q_flow = -TC_900_1659.Q_flow; TC_901_902.Q_flow = TC_901_902.G * TC_901_902.dT; TC_901_902.dT = TC_901_902.port_a.T - TC_901_902.port_b.T; TC_901_902.port_a.Q_flow = TC_901_902.Q_flow; TC_901_902.port_b.Q_flow = -TC_901_902.Q_flow; TC_901_912.Q_flow = TC_901_912.G * TC_901_912.dT; TC_901_912.dT = TC_901_912.port_a.T - TC_901_912.port_b.T; TC_901_912.port_a.Q_flow = TC_901_912.Q_flow; TC_901_912.port_b.Q_flow = -TC_901_912.Q_flow; TC_901_1660.Q_flow = TC_901_1660.G * TC_901_1660.dT; TC_901_1660.dT = TC_901_1660.port_a.T - TC_901_1660.port_b.T; TC_901_1660.port_a.Q_flow = TC_901_1660.Q_flow; TC_901_1660.port_b.Q_flow = -TC_901_1660.Q_flow; TC_902_903.Q_flow = TC_902_903.G * TC_902_903.dT; TC_902_903.dT = TC_902_903.port_a.T - TC_902_903.port_b.T; TC_902_903.port_a.Q_flow = TC_902_903.Q_flow; TC_902_903.port_b.Q_flow = -TC_902_903.Q_flow; TC_902_913.Q_flow = TC_902_913.G * TC_902_913.dT; TC_902_913.dT = TC_902_913.port_a.T - TC_902_913.port_b.T; TC_902_913.port_a.Q_flow = TC_902_913.Q_flow; TC_902_913.port_b.Q_flow = -TC_902_913.Q_flow; TC_902_1661.Q_flow = TC_902_1661.G * TC_902_1661.dT; TC_902_1661.dT = TC_902_1661.port_a.T - TC_902_1661.port_b.T; TC_902_1661.port_a.Q_flow = TC_902_1661.Q_flow; TC_902_1661.port_b.Q_flow = -TC_902_1661.Q_flow; TC_903_904.Q_flow = TC_903_904.G * TC_903_904.dT; TC_903_904.dT = TC_903_904.port_a.T - TC_903_904.port_b.T; TC_903_904.port_a.Q_flow = TC_903_904.Q_flow; TC_903_904.port_b.Q_flow = -TC_903_904.Q_flow; TC_903_914.Q_flow = TC_903_914.G * TC_903_914.dT; TC_903_914.dT = TC_903_914.port_a.T - TC_903_914.port_b.T; TC_903_914.port_a.Q_flow = TC_903_914.Q_flow; TC_903_914.port_b.Q_flow = -TC_903_914.Q_flow; TC_903_992.Q_flow = TC_903_992.G * TC_903_992.dT; TC_903_992.dT = TC_903_992.port_a.T - TC_903_992.port_b.T; TC_903_992.port_a.Q_flow = TC_903_992.Q_flow; TC_903_992.port_b.Q_flow = -TC_903_992.Q_flow; TC_904_905.Q_flow = TC_904_905.G * TC_904_905.dT; TC_904_905.dT = TC_904_905.port_a.T - TC_904_905.port_b.T; TC_904_905.port_a.Q_flow = TC_904_905.Q_flow; TC_904_905.port_b.Q_flow = -TC_904_905.Q_flow; TC_904_915.Q_flow = TC_904_915.G * TC_904_915.dT; TC_904_915.dT = TC_904_915.port_a.T - TC_904_915.port_b.T; TC_904_915.port_a.Q_flow = TC_904_915.Q_flow; TC_904_915.port_b.Q_flow = -TC_904_915.Q_flow; TC_904_993.Q_flow = TC_904_993.G * TC_904_993.dT; TC_904_993.dT = TC_904_993.port_a.T - TC_904_993.port_b.T; TC_904_993.port_a.Q_flow = TC_904_993.Q_flow; TC_904_993.port_b.Q_flow = -TC_904_993.Q_flow; TC_905_906.Q_flow = TC_905_906.G * TC_905_906.dT; TC_905_906.dT = TC_905_906.port_a.T - TC_905_906.port_b.T; TC_905_906.port_a.Q_flow = TC_905_906.Q_flow; TC_905_906.port_b.Q_flow = -TC_905_906.Q_flow; TC_905_916.Q_flow = TC_905_916.G * TC_905_916.dT; TC_905_916.dT = TC_905_916.port_a.T - TC_905_916.port_b.T; TC_905_916.port_a.Q_flow = TC_905_916.Q_flow; TC_905_916.port_b.Q_flow = -TC_905_916.Q_flow; TC_905_994.Q_flow = TC_905_994.G * TC_905_994.dT; TC_905_994.dT = TC_905_994.port_a.T - TC_905_994.port_b.T; TC_905_994.port_a.Q_flow = TC_905_994.Q_flow; TC_905_994.port_b.Q_flow = -TC_905_994.Q_flow; TC_906_907.Q_flow = TC_906_907.G * TC_906_907.dT; TC_906_907.dT = TC_906_907.port_a.T - TC_906_907.port_b.T; TC_906_907.port_a.Q_flow = TC_906_907.Q_flow; TC_906_907.port_b.Q_flow = -TC_906_907.Q_flow; TC_906_917.Q_flow = TC_906_917.G * TC_906_917.dT; TC_906_917.dT = TC_906_917.port_a.T - TC_906_917.port_b.T; TC_906_917.port_a.Q_flow = TC_906_917.Q_flow; TC_906_917.port_b.Q_flow = -TC_906_917.Q_flow; TC_906_995.Q_flow = TC_906_995.G * TC_906_995.dT; TC_906_995.dT = TC_906_995.port_a.T - TC_906_995.port_b.T; TC_906_995.port_a.Q_flow = TC_906_995.Q_flow; TC_906_995.port_b.Q_flow = -TC_906_995.Q_flow; TC_907_908.Q_flow = TC_907_908.G * TC_907_908.dT; TC_907_908.dT = TC_907_908.port_a.T - TC_907_908.port_b.T; TC_907_908.port_a.Q_flow = TC_907_908.Q_flow; TC_907_908.port_b.Q_flow = -TC_907_908.Q_flow; TC_907_918.Q_flow = TC_907_918.G * TC_907_918.dT; TC_907_918.dT = TC_907_918.port_a.T - TC_907_918.port_b.T; TC_907_918.port_a.Q_flow = TC_907_918.Q_flow; TC_907_918.port_b.Q_flow = -TC_907_918.Q_flow; TC_907_996.Q_flow = TC_907_996.G * TC_907_996.dT; TC_907_996.dT = TC_907_996.port_a.T - TC_907_996.port_b.T; TC_907_996.port_a.Q_flow = TC_907_996.Q_flow; TC_907_996.port_b.Q_flow = -TC_907_996.Q_flow; TC_908_919.Q_flow = TC_908_919.G * TC_908_919.dT; TC_908_919.dT = TC_908_919.port_a.T - TC_908_919.port_b.T; TC_908_919.port_a.Q_flow = TC_908_919.Q_flow; TC_908_919.port_b.Q_flow = -TC_908_919.Q_flow; TC_908_997.Q_flow = TC_908_997.G * TC_908_997.dT; TC_908_997.dT = TC_908_997.port_a.T - TC_908_997.port_b.T; TC_908_997.port_a.Q_flow = TC_908_997.Q_flow; TC_908_997.port_b.Q_flow = -TC_908_997.Q_flow; TC_909_910.Q_flow = TC_909_910.G * TC_909_910.dT; TC_909_910.dT = TC_909_910.port_a.T - TC_909_910.port_b.T; TC_909_910.port_a.Q_flow = TC_909_910.Q_flow; TC_909_910.port_b.Q_flow = -TC_909_910.Q_flow; TC_909_998.Q_flow = TC_909_998.G * TC_909_998.dT; TC_909_998.dT = TC_909_998.port_a.T - TC_909_998.port_b.T; TC_909_998.port_a.Q_flow = TC_909_998.Q_flow; TC_909_998.port_b.Q_flow = -TC_909_998.Q_flow; TC_910_911.Q_flow = TC_910_911.G * TC_910_911.dT; TC_910_911.dT = TC_910_911.port_a.T - TC_910_911.port_b.T; TC_910_911.port_a.Q_flow = TC_910_911.Q_flow; TC_910_911.port_b.Q_flow = -TC_910_911.Q_flow; TC_910_999.Q_flow = TC_910_999.G * TC_910_999.dT; TC_910_999.dT = TC_910_999.port_a.T - TC_910_999.port_b.T; TC_910_999.port_a.Q_flow = TC_910_999.Q_flow; TC_910_999.port_b.Q_flow = -TC_910_999.Q_flow; TC_911_912.Q_flow = TC_911_912.G * TC_911_912.dT; TC_911_912.dT = TC_911_912.port_a.T - TC_911_912.port_b.T; TC_911_912.port_a.Q_flow = TC_911_912.Q_flow; TC_911_912.port_b.Q_flow = -TC_911_912.Q_flow; TC_911_1662.Q_flow = TC_911_1662.G * TC_911_1662.dT; TC_911_1662.dT = TC_911_1662.port_a.T - TC_911_1662.port_b.T; TC_911_1662.port_a.Q_flow = TC_911_1662.Q_flow; TC_911_1662.port_b.Q_flow = -TC_911_1662.Q_flow; TC_912_913.Q_flow = TC_912_913.G * TC_912_913.dT; TC_912_913.dT = TC_912_913.port_a.T - TC_912_913.port_b.T; TC_912_913.port_a.Q_flow = TC_912_913.Q_flow; TC_912_913.port_b.Q_flow = -TC_912_913.Q_flow; TC_912_1663.Q_flow = TC_912_1663.G * TC_912_1663.dT; TC_912_1663.dT = TC_912_1663.port_a.T - TC_912_1663.port_b.T; TC_912_1663.port_a.Q_flow = TC_912_1663.Q_flow; TC_912_1663.port_b.Q_flow = -TC_912_1663.Q_flow; TC_913_914.Q_flow = TC_913_914.G * TC_913_914.dT; TC_913_914.dT = TC_913_914.port_a.T - TC_913_914.port_b.T; TC_913_914.port_a.Q_flow = TC_913_914.Q_flow; TC_913_914.port_b.Q_flow = -TC_913_914.Q_flow; TC_913_1664.Q_flow = TC_913_1664.G * TC_913_1664.dT; TC_913_1664.dT = TC_913_1664.port_a.T - TC_913_1664.port_b.T; TC_913_1664.port_a.Q_flow = TC_913_1664.Q_flow; TC_913_1664.port_b.Q_flow = -TC_913_1664.Q_flow; TC_914_915.Q_flow = TC_914_915.G * TC_914_915.dT; TC_914_915.dT = TC_914_915.port_a.T - TC_914_915.port_b.T; TC_914_915.port_a.Q_flow = TC_914_915.Q_flow; TC_914_915.port_b.Q_flow = -TC_914_915.Q_flow; TC_914_1000.Q_flow = TC_914_1000.G * TC_914_1000.dT; TC_914_1000.dT = TC_914_1000.port_a.T - TC_914_1000.port_b.T; TC_914_1000.port_a.Q_flow = TC_914_1000.Q_flow; TC_914_1000.port_b.Q_flow = -TC_914_1000.Q_flow; TC_915_916.Q_flow = TC_915_916.G * TC_915_916.dT; TC_915_916.dT = TC_915_916.port_a.T - TC_915_916.port_b.T; TC_915_916.port_a.Q_flow = TC_915_916.Q_flow; TC_915_916.port_b.Q_flow = -TC_915_916.Q_flow; TC_915_1001.Q_flow = TC_915_1001.G * TC_915_1001.dT; TC_915_1001.dT = TC_915_1001.port_a.T - TC_915_1001.port_b.T; TC_915_1001.port_a.Q_flow = TC_915_1001.Q_flow; TC_915_1001.port_b.Q_flow = -TC_915_1001.Q_flow; TC_916_917.Q_flow = TC_916_917.G * TC_916_917.dT; TC_916_917.dT = TC_916_917.port_a.T - TC_916_917.port_b.T; TC_916_917.port_a.Q_flow = TC_916_917.Q_flow; TC_916_917.port_b.Q_flow = -TC_916_917.Q_flow; TC_916_1002.Q_flow = TC_916_1002.G * TC_916_1002.dT; TC_916_1002.dT = TC_916_1002.port_a.T - TC_916_1002.port_b.T; TC_916_1002.port_a.Q_flow = TC_916_1002.Q_flow; TC_916_1002.port_b.Q_flow = -TC_916_1002.Q_flow; TC_917_918.Q_flow = TC_917_918.G * TC_917_918.dT; TC_917_918.dT = TC_917_918.port_a.T - TC_917_918.port_b.T; TC_917_918.port_a.Q_flow = TC_917_918.Q_flow; TC_917_918.port_b.Q_flow = -TC_917_918.Q_flow; TC_917_1003.Q_flow = TC_917_1003.G * TC_917_1003.dT; TC_917_1003.dT = TC_917_1003.port_a.T - TC_917_1003.port_b.T; TC_917_1003.port_a.Q_flow = TC_917_1003.Q_flow; TC_917_1003.port_b.Q_flow = -TC_917_1003.Q_flow; TC_918_919.Q_flow = TC_918_919.G * TC_918_919.dT; TC_918_919.dT = TC_918_919.port_a.T - TC_918_919.port_b.T; TC_918_919.port_a.Q_flow = TC_918_919.Q_flow; TC_918_919.port_b.Q_flow = -TC_918_919.Q_flow; TC_918_1004.Q_flow = TC_918_1004.G * TC_918_1004.dT; TC_918_1004.dT = TC_918_1004.port_a.T - TC_918_1004.port_b.T; TC_918_1004.port_a.Q_flow = TC_918_1004.Q_flow; TC_918_1004.port_b.Q_flow = -TC_918_1004.Q_flow; TC_919_1005.Q_flow = TC_919_1005.G * TC_919_1005.dT; TC_919_1005.dT = TC_919_1005.port_a.T - TC_919_1005.port_b.T; TC_919_1005.port_a.Q_flow = TC_919_1005.Q_flow; TC_919_1005.port_b.Q_flow = -TC_919_1005.Q_flow; TC_920_921.Q_flow = TC_920_921.G * TC_920_921.dT; TC_920_921.dT = TC_920_921.port_a.T - TC_920_921.port_b.T; TC_920_921.port_a.Q_flow = TC_920_921.Q_flow; TC_920_921.port_b.Q_flow = -TC_920_921.Q_flow; TC_920_931.Q_flow = TC_920_931.G * TC_920_931.dT; TC_920_931.dT = TC_920_931.port_a.T - TC_920_931.port_b.T; TC_920_931.port_a.Q_flow = TC_920_931.Q_flow; TC_920_931.port_b.Q_flow = -TC_920_931.Q_flow; TC_920_1066.Q_flow = TC_920_1066.G * TC_920_1066.dT; TC_920_1066.dT = TC_920_1066.port_a.T - TC_920_1066.port_b.T; TC_920_1066.port_a.Q_flow = TC_920_1066.Q_flow; TC_920_1066.port_b.Q_flow = -TC_920_1066.Q_flow; TC_921_922.Q_flow = TC_921_922.G * TC_921_922.dT; TC_921_922.dT = TC_921_922.port_a.T - TC_921_922.port_b.T; TC_921_922.port_a.Q_flow = TC_921_922.Q_flow; TC_921_922.port_b.Q_flow = -TC_921_922.Q_flow; TC_921_932.Q_flow = TC_921_932.G * TC_921_932.dT; TC_921_932.dT = TC_921_932.port_a.T - TC_921_932.port_b.T; TC_921_932.port_a.Q_flow = TC_921_932.Q_flow; TC_921_932.port_b.Q_flow = -TC_921_932.Q_flow; TC_921_1067.Q_flow = TC_921_1067.G * TC_921_1067.dT; TC_921_1067.dT = TC_921_1067.port_a.T - TC_921_1067.port_b.T; TC_921_1067.port_a.Q_flow = TC_921_1067.Q_flow; TC_921_1067.port_b.Q_flow = -TC_921_1067.Q_flow; TC_922_923.Q_flow = TC_922_923.G * TC_922_923.dT; TC_922_923.dT = TC_922_923.port_a.T - TC_922_923.port_b.T; TC_922_923.port_a.Q_flow = TC_922_923.Q_flow; TC_922_923.port_b.Q_flow = -TC_922_923.Q_flow; TC_922_933.Q_flow = TC_922_933.G * TC_922_933.dT; TC_922_933.dT = TC_922_933.port_a.T - TC_922_933.port_b.T; TC_922_933.port_a.Q_flow = TC_922_933.Q_flow; TC_922_933.port_b.Q_flow = -TC_922_933.Q_flow; TC_922_1068.Q_flow = TC_922_1068.G * TC_922_1068.dT; TC_922_1068.dT = TC_922_1068.port_a.T - TC_922_1068.port_b.T; TC_922_1068.port_a.Q_flow = TC_922_1068.Q_flow; TC_922_1068.port_b.Q_flow = -TC_922_1068.Q_flow; TC_923_924.Q_flow = TC_923_924.G * TC_923_924.dT; TC_923_924.dT = TC_923_924.port_a.T - TC_923_924.port_b.T; TC_923_924.port_a.Q_flow = TC_923_924.Q_flow; TC_923_924.port_b.Q_flow = -TC_923_924.Q_flow; TC_923_934.Q_flow = TC_923_934.G * TC_923_934.dT; TC_923_934.dT = TC_923_934.port_a.T - TC_923_934.port_b.T; TC_923_934.port_a.Q_flow = TC_923_934.Q_flow; TC_923_934.port_b.Q_flow = -TC_923_934.Q_flow; TC_923_1069.Q_flow = TC_923_1069.G * TC_923_1069.dT; TC_923_1069.dT = TC_923_1069.port_a.T - TC_923_1069.port_b.T; TC_923_1069.port_a.Q_flow = TC_923_1069.Q_flow; TC_923_1069.port_b.Q_flow = -TC_923_1069.Q_flow; TC_924_925.Q_flow = TC_924_925.G * TC_924_925.dT; TC_924_925.dT = TC_924_925.port_a.T - TC_924_925.port_b.T; TC_924_925.port_a.Q_flow = TC_924_925.Q_flow; TC_924_925.port_b.Q_flow = -TC_924_925.Q_flow; TC_924_935.Q_flow = TC_924_935.G * TC_924_935.dT; TC_924_935.dT = TC_924_935.port_a.T - TC_924_935.port_b.T; TC_924_935.port_a.Q_flow = TC_924_935.Q_flow; TC_924_935.port_b.Q_flow = -TC_924_935.Q_flow; TC_924_1070.Q_flow = TC_924_1070.G * TC_924_1070.dT; TC_924_1070.dT = TC_924_1070.port_a.T - TC_924_1070.port_b.T; TC_924_1070.port_a.Q_flow = TC_924_1070.Q_flow; TC_924_1070.port_b.Q_flow = -TC_924_1070.Q_flow; TC_925_926.Q_flow = TC_925_926.G * TC_925_926.dT; TC_925_926.dT = TC_925_926.port_a.T - TC_925_926.port_b.T; TC_925_926.port_a.Q_flow = TC_925_926.Q_flow; TC_925_926.port_b.Q_flow = -TC_925_926.Q_flow; TC_925_936.Q_flow = TC_925_936.G * TC_925_936.dT; TC_925_936.dT = TC_925_936.port_a.T - TC_925_936.port_b.T; TC_925_936.port_a.Q_flow = TC_925_936.Q_flow; TC_925_936.port_b.Q_flow = -TC_925_936.Q_flow; TC_925_1071.Q_flow = TC_925_1071.G * TC_925_1071.dT; TC_925_1071.dT = TC_925_1071.port_a.T - TC_925_1071.port_b.T; TC_925_1071.port_a.Q_flow = TC_925_1071.Q_flow; TC_925_1071.port_b.Q_flow = -TC_925_1071.Q_flow; TC_926_927.Q_flow = TC_926_927.G * TC_926_927.dT; TC_926_927.dT = TC_926_927.port_a.T - TC_926_927.port_b.T; TC_926_927.port_a.Q_flow = TC_926_927.Q_flow; TC_926_927.port_b.Q_flow = -TC_926_927.Q_flow; TC_926_937.Q_flow = TC_926_937.G * TC_926_937.dT; TC_926_937.dT = TC_926_937.port_a.T - TC_926_937.port_b.T; TC_926_937.port_a.Q_flow = TC_926_937.Q_flow; TC_926_937.port_b.Q_flow = -TC_926_937.Q_flow; TC_926_1072.Q_flow = TC_926_1072.G * TC_926_1072.dT; TC_926_1072.dT = TC_926_1072.port_a.T - TC_926_1072.port_b.T; TC_926_1072.port_a.Q_flow = TC_926_1072.Q_flow; TC_926_1072.port_b.Q_flow = -TC_926_1072.Q_flow; TC_927_928.Q_flow = TC_927_928.G * TC_927_928.dT; TC_927_928.dT = TC_927_928.port_a.T - TC_927_928.port_b.T; TC_927_928.port_a.Q_flow = TC_927_928.Q_flow; TC_927_928.port_b.Q_flow = -TC_927_928.Q_flow; TC_927_938.Q_flow = TC_927_938.G * TC_927_938.dT; TC_927_938.dT = TC_927_938.port_a.T - TC_927_938.port_b.T; TC_927_938.port_a.Q_flow = TC_927_938.Q_flow; TC_927_938.port_b.Q_flow = -TC_927_938.Q_flow; TC_927_1073.Q_flow = TC_927_1073.G * TC_927_1073.dT; TC_927_1073.dT = TC_927_1073.port_a.T - TC_927_1073.port_b.T; TC_927_1073.port_a.Q_flow = TC_927_1073.Q_flow; TC_927_1073.port_b.Q_flow = -TC_927_1073.Q_flow; TC_928_929.Q_flow = TC_928_929.G * TC_928_929.dT; TC_928_929.dT = TC_928_929.port_a.T - TC_928_929.port_b.T; TC_928_929.port_a.Q_flow = TC_928_929.Q_flow; TC_928_929.port_b.Q_flow = -TC_928_929.Q_flow; TC_928_939.Q_flow = TC_928_939.G * TC_928_939.dT; TC_928_939.dT = TC_928_939.port_a.T - TC_928_939.port_b.T; TC_928_939.port_a.Q_flow = TC_928_939.Q_flow; TC_928_939.port_b.Q_flow = -TC_928_939.Q_flow; TC_928_1074.Q_flow = TC_928_1074.G * TC_928_1074.dT; TC_928_1074.dT = TC_928_1074.port_a.T - TC_928_1074.port_b.T; TC_928_1074.port_a.Q_flow = TC_928_1074.Q_flow; TC_928_1074.port_b.Q_flow = -TC_928_1074.Q_flow; TC_929_930.Q_flow = TC_929_930.G * TC_929_930.dT; TC_929_930.dT = TC_929_930.port_a.T - TC_929_930.port_b.T; TC_929_930.port_a.Q_flow = TC_929_930.Q_flow; TC_929_930.port_b.Q_flow = -TC_929_930.Q_flow; TC_929_940.Q_flow = TC_929_940.G * TC_929_940.dT; TC_929_940.dT = TC_929_940.port_a.T - TC_929_940.port_b.T; TC_929_940.port_a.Q_flow = TC_929_940.Q_flow; TC_929_940.port_b.Q_flow = -TC_929_940.Q_flow; TC_929_1075.Q_flow = TC_929_1075.G * TC_929_1075.dT; TC_929_1075.dT = TC_929_1075.port_a.T - TC_929_1075.port_b.T; TC_929_1075.port_a.Q_flow = TC_929_1075.Q_flow; TC_929_1075.port_b.Q_flow = -TC_929_1075.Q_flow; TC_930_941.Q_flow = TC_930_941.G * TC_930_941.dT; TC_930_941.dT = TC_930_941.port_a.T - TC_930_941.port_b.T; TC_930_941.port_a.Q_flow = TC_930_941.Q_flow; TC_930_941.port_b.Q_flow = -TC_930_941.Q_flow; TC_930_1076.Q_flow = TC_930_1076.G * TC_930_1076.dT; TC_930_1076.dT = TC_930_1076.port_a.T - TC_930_1076.port_b.T; TC_930_1076.port_a.Q_flow = TC_930_1076.Q_flow; TC_930_1076.port_b.Q_flow = -TC_930_1076.Q_flow; TC_931_932.Q_flow = TC_931_932.G * TC_931_932.dT; TC_931_932.dT = TC_931_932.port_a.T - TC_931_932.port_b.T; TC_931_932.port_a.Q_flow = TC_931_932.Q_flow; TC_931_932.port_b.Q_flow = -TC_931_932.Q_flow; TC_931_942.Q_flow = TC_931_942.G * TC_931_942.dT; TC_931_942.dT = TC_931_942.port_a.T - TC_931_942.port_b.T; TC_931_942.port_a.Q_flow = TC_931_942.Q_flow; TC_931_942.port_b.Q_flow = -TC_931_942.Q_flow; TC_931_1077.Q_flow = TC_931_1077.G * TC_931_1077.dT; TC_931_1077.dT = TC_931_1077.port_a.T - TC_931_1077.port_b.T; TC_931_1077.port_a.Q_flow = TC_931_1077.Q_flow; TC_931_1077.port_b.Q_flow = -TC_931_1077.Q_flow; TC_932_933.Q_flow = TC_932_933.G * TC_932_933.dT; TC_932_933.dT = TC_932_933.port_a.T - TC_932_933.port_b.T; TC_932_933.port_a.Q_flow = TC_932_933.Q_flow; TC_932_933.port_b.Q_flow = -TC_932_933.Q_flow; TC_932_943.Q_flow = TC_932_943.G * TC_932_943.dT; TC_932_943.dT = TC_932_943.port_a.T - TC_932_943.port_b.T; TC_932_943.port_a.Q_flow = TC_932_943.Q_flow; TC_932_943.port_b.Q_flow = -TC_932_943.Q_flow; TC_932_1078.Q_flow = TC_932_1078.G * TC_932_1078.dT; TC_932_1078.dT = TC_932_1078.port_a.T - TC_932_1078.port_b.T; TC_932_1078.port_a.Q_flow = TC_932_1078.Q_flow; TC_932_1078.port_b.Q_flow = -TC_932_1078.Q_flow; TC_933_934.Q_flow = TC_933_934.G * TC_933_934.dT; TC_933_934.dT = TC_933_934.port_a.T - TC_933_934.port_b.T; TC_933_934.port_a.Q_flow = TC_933_934.Q_flow; TC_933_934.port_b.Q_flow = -TC_933_934.Q_flow; TC_933_944.Q_flow = TC_933_944.G * TC_933_944.dT; TC_933_944.dT = TC_933_944.port_a.T - TC_933_944.port_b.T; TC_933_944.port_a.Q_flow = TC_933_944.Q_flow; TC_933_944.port_b.Q_flow = -TC_933_944.Q_flow; TC_933_1079.Q_flow = TC_933_1079.G * TC_933_1079.dT; TC_933_1079.dT = TC_933_1079.port_a.T - TC_933_1079.port_b.T; TC_933_1079.port_a.Q_flow = TC_933_1079.Q_flow; TC_933_1079.port_b.Q_flow = -TC_933_1079.Q_flow; TC_934_935.Q_flow = TC_934_935.G * TC_934_935.dT; TC_934_935.dT = TC_934_935.port_a.T - TC_934_935.port_b.T; TC_934_935.port_a.Q_flow = TC_934_935.Q_flow; TC_934_935.port_b.Q_flow = -TC_934_935.Q_flow; TC_934_945.Q_flow = TC_934_945.G * TC_934_945.dT; TC_934_945.dT = TC_934_945.port_a.T - TC_934_945.port_b.T; TC_934_945.port_a.Q_flow = TC_934_945.Q_flow; TC_934_945.port_b.Q_flow = -TC_934_945.Q_flow; TC_934_1080.Q_flow = TC_934_1080.G * TC_934_1080.dT; TC_934_1080.dT = TC_934_1080.port_a.T - TC_934_1080.port_b.T; TC_934_1080.port_a.Q_flow = TC_934_1080.Q_flow; TC_934_1080.port_b.Q_flow = -TC_934_1080.Q_flow; TC_935_936.Q_flow = TC_935_936.G * TC_935_936.dT; TC_935_936.dT = TC_935_936.port_a.T - TC_935_936.port_b.T; TC_935_936.port_a.Q_flow = TC_935_936.Q_flow; TC_935_936.port_b.Q_flow = -TC_935_936.Q_flow; TC_935_946.Q_flow = TC_935_946.G * TC_935_946.dT; TC_935_946.dT = TC_935_946.port_a.T - TC_935_946.port_b.T; TC_935_946.port_a.Q_flow = TC_935_946.Q_flow; TC_935_946.port_b.Q_flow = -TC_935_946.Q_flow; TC_935_1081.Q_flow = TC_935_1081.G * TC_935_1081.dT; TC_935_1081.dT = TC_935_1081.port_a.T - TC_935_1081.port_b.T; TC_935_1081.port_a.Q_flow = TC_935_1081.Q_flow; TC_935_1081.port_b.Q_flow = -TC_935_1081.Q_flow; TC_936_937.Q_flow = TC_936_937.G * TC_936_937.dT; TC_936_937.dT = TC_936_937.port_a.T - TC_936_937.port_b.T; TC_936_937.port_a.Q_flow = TC_936_937.Q_flow; TC_936_937.port_b.Q_flow = -TC_936_937.Q_flow; TC_936_947.Q_flow = TC_936_947.G * TC_936_947.dT; TC_936_947.dT = TC_936_947.port_a.T - TC_936_947.port_b.T; TC_936_947.port_a.Q_flow = TC_936_947.Q_flow; TC_936_947.port_b.Q_flow = -TC_936_947.Q_flow; TC_936_1082.Q_flow = TC_936_1082.G * TC_936_1082.dT; TC_936_1082.dT = TC_936_1082.port_a.T - TC_936_1082.port_b.T; TC_936_1082.port_a.Q_flow = TC_936_1082.Q_flow; TC_936_1082.port_b.Q_flow = -TC_936_1082.Q_flow; TC_937_938.Q_flow = TC_937_938.G * TC_937_938.dT; TC_937_938.dT = TC_937_938.port_a.T - TC_937_938.port_b.T; TC_937_938.port_a.Q_flow = TC_937_938.Q_flow; TC_937_938.port_b.Q_flow = -TC_937_938.Q_flow; TC_937_948.Q_flow = TC_937_948.G * TC_937_948.dT; TC_937_948.dT = TC_937_948.port_a.T - TC_937_948.port_b.T; TC_937_948.port_a.Q_flow = TC_937_948.Q_flow; TC_937_948.port_b.Q_flow = -TC_937_948.Q_flow; TC_937_1083.Q_flow = TC_937_1083.G * TC_937_1083.dT; TC_937_1083.dT = TC_937_1083.port_a.T - TC_937_1083.port_b.T; TC_937_1083.port_a.Q_flow = TC_937_1083.Q_flow; TC_937_1083.port_b.Q_flow = -TC_937_1083.Q_flow; TC_938_939.Q_flow = TC_938_939.G * TC_938_939.dT; TC_938_939.dT = TC_938_939.port_a.T - TC_938_939.port_b.T; TC_938_939.port_a.Q_flow = TC_938_939.Q_flow; TC_938_939.port_b.Q_flow = -TC_938_939.Q_flow; TC_938_949.Q_flow = TC_938_949.G * TC_938_949.dT; TC_938_949.dT = TC_938_949.port_a.T - TC_938_949.port_b.T; TC_938_949.port_a.Q_flow = TC_938_949.Q_flow; TC_938_949.port_b.Q_flow = -TC_938_949.Q_flow; TC_938_1084.Q_flow = TC_938_1084.G * TC_938_1084.dT; TC_938_1084.dT = TC_938_1084.port_a.T - TC_938_1084.port_b.T; TC_938_1084.port_a.Q_flow = TC_938_1084.Q_flow; TC_938_1084.port_b.Q_flow = -TC_938_1084.Q_flow; TC_939_940.Q_flow = TC_939_940.G * TC_939_940.dT; TC_939_940.dT = TC_939_940.port_a.T - TC_939_940.port_b.T; TC_939_940.port_a.Q_flow = TC_939_940.Q_flow; TC_939_940.port_b.Q_flow = -TC_939_940.Q_flow; TC_939_950.Q_flow = TC_939_950.G * TC_939_950.dT; TC_939_950.dT = TC_939_950.port_a.T - TC_939_950.port_b.T; TC_939_950.port_a.Q_flow = TC_939_950.Q_flow; TC_939_950.port_b.Q_flow = -TC_939_950.Q_flow; TC_939_1085.Q_flow = TC_939_1085.G * TC_939_1085.dT; TC_939_1085.dT = TC_939_1085.port_a.T - TC_939_1085.port_b.T; TC_939_1085.port_a.Q_flow = TC_939_1085.Q_flow; TC_939_1085.port_b.Q_flow = -TC_939_1085.Q_flow; TC_940_941.Q_flow = TC_940_941.G * TC_940_941.dT; TC_940_941.dT = TC_940_941.port_a.T - TC_940_941.port_b.T; TC_940_941.port_a.Q_flow = TC_940_941.Q_flow; TC_940_941.port_b.Q_flow = -TC_940_941.Q_flow; TC_940_951.Q_flow = TC_940_951.G * TC_940_951.dT; TC_940_951.dT = TC_940_951.port_a.T - TC_940_951.port_b.T; TC_940_951.port_a.Q_flow = TC_940_951.Q_flow; TC_940_951.port_b.Q_flow = -TC_940_951.Q_flow; TC_940_1086.Q_flow = TC_940_1086.G * TC_940_1086.dT; TC_940_1086.dT = TC_940_1086.port_a.T - TC_940_1086.port_b.T; TC_940_1086.port_a.Q_flow = TC_940_1086.Q_flow; TC_940_1086.port_b.Q_flow = -TC_940_1086.Q_flow; TC_941_952.Q_flow = TC_941_952.G * TC_941_952.dT; TC_941_952.dT = TC_941_952.port_a.T - TC_941_952.port_b.T; TC_941_952.port_a.Q_flow = TC_941_952.Q_flow; TC_941_952.port_b.Q_flow = -TC_941_952.Q_flow; TC_941_1087.Q_flow = TC_941_1087.G * TC_941_1087.dT; TC_941_1087.dT = TC_941_1087.port_a.T - TC_941_1087.port_b.T; TC_941_1087.port_a.Q_flow = TC_941_1087.Q_flow; TC_941_1087.port_b.Q_flow = -TC_941_1087.Q_flow; TC_942_943.Q_flow = TC_942_943.G * TC_942_943.dT; TC_942_943.dT = TC_942_943.port_a.T - TC_942_943.port_b.T; TC_942_943.port_a.Q_flow = TC_942_943.Q_flow; TC_942_943.port_b.Q_flow = -TC_942_943.Q_flow; TC_942_953.Q_flow = TC_942_953.G * TC_942_953.dT; TC_942_953.dT = TC_942_953.port_a.T - TC_942_953.port_b.T; TC_942_953.port_a.Q_flow = TC_942_953.Q_flow; TC_942_953.port_b.Q_flow = -TC_942_953.Q_flow; TC_942_1088.Q_flow = TC_942_1088.G * TC_942_1088.dT; TC_942_1088.dT = TC_942_1088.port_a.T - TC_942_1088.port_b.T; TC_942_1088.port_a.Q_flow = TC_942_1088.Q_flow; TC_942_1088.port_b.Q_flow = -TC_942_1088.Q_flow; TC_943_944.Q_flow = TC_943_944.G * TC_943_944.dT; TC_943_944.dT = TC_943_944.port_a.T - TC_943_944.port_b.T; TC_943_944.port_a.Q_flow = TC_943_944.Q_flow; TC_943_944.port_b.Q_flow = -TC_943_944.Q_flow; TC_943_954.Q_flow = TC_943_954.G * TC_943_954.dT; TC_943_954.dT = TC_943_954.port_a.T - TC_943_954.port_b.T; TC_943_954.port_a.Q_flow = TC_943_954.Q_flow; TC_943_954.port_b.Q_flow = -TC_943_954.Q_flow; TC_943_1089.Q_flow = TC_943_1089.G * TC_943_1089.dT; TC_943_1089.dT = TC_943_1089.port_a.T - TC_943_1089.port_b.T; TC_943_1089.port_a.Q_flow = TC_943_1089.Q_flow; TC_943_1089.port_b.Q_flow = -TC_943_1089.Q_flow; TC_944_945.Q_flow = TC_944_945.G * TC_944_945.dT; TC_944_945.dT = TC_944_945.port_a.T - TC_944_945.port_b.T; TC_944_945.port_a.Q_flow = TC_944_945.Q_flow; TC_944_945.port_b.Q_flow = -TC_944_945.Q_flow; TC_944_955.Q_flow = TC_944_955.G * TC_944_955.dT; TC_944_955.dT = TC_944_955.port_a.T - TC_944_955.port_b.T; TC_944_955.port_a.Q_flow = TC_944_955.Q_flow; TC_944_955.port_b.Q_flow = -TC_944_955.Q_flow; TC_944_1090.Q_flow = TC_944_1090.G * TC_944_1090.dT; TC_944_1090.dT = TC_944_1090.port_a.T - TC_944_1090.port_b.T; TC_944_1090.port_a.Q_flow = TC_944_1090.Q_flow; TC_944_1090.port_b.Q_flow = -TC_944_1090.Q_flow; TC_945_946.Q_flow = TC_945_946.G * TC_945_946.dT; TC_945_946.dT = TC_945_946.port_a.T - TC_945_946.port_b.T; TC_945_946.port_a.Q_flow = TC_945_946.Q_flow; TC_945_946.port_b.Q_flow = -TC_945_946.Q_flow; TC_945_956.Q_flow = TC_945_956.G * TC_945_956.dT; TC_945_956.dT = TC_945_956.port_a.T - TC_945_956.port_b.T; TC_945_956.port_a.Q_flow = TC_945_956.Q_flow; TC_945_956.port_b.Q_flow = -TC_945_956.Q_flow; TC_945_1091.Q_flow = TC_945_1091.G * TC_945_1091.dT; TC_945_1091.dT = TC_945_1091.port_a.T - TC_945_1091.port_b.T; TC_945_1091.port_a.Q_flow = TC_945_1091.Q_flow; TC_945_1091.port_b.Q_flow = -TC_945_1091.Q_flow; TC_946_947.Q_flow = TC_946_947.G * TC_946_947.dT; TC_946_947.dT = TC_946_947.port_a.T - TC_946_947.port_b.T; TC_946_947.port_a.Q_flow = TC_946_947.Q_flow; TC_946_947.port_b.Q_flow = -TC_946_947.Q_flow; TC_946_957.Q_flow = TC_946_957.G * TC_946_957.dT; TC_946_957.dT = TC_946_957.port_a.T - TC_946_957.port_b.T; TC_946_957.port_a.Q_flow = TC_946_957.Q_flow; TC_946_957.port_b.Q_flow = -TC_946_957.Q_flow; TC_946_1635.Q_flow = TC_946_1635.G * TC_946_1635.dT; TC_946_1635.dT = TC_946_1635.port_a.T - TC_946_1635.port_b.T; TC_946_1635.port_a.Q_flow = TC_946_1635.Q_flow; TC_946_1635.port_b.Q_flow = -TC_946_1635.Q_flow; TC_947_948.Q_flow = TC_947_948.G * TC_947_948.dT; TC_947_948.dT = TC_947_948.port_a.T - TC_947_948.port_b.T; TC_947_948.port_a.Q_flow = TC_947_948.Q_flow; TC_947_948.port_b.Q_flow = -TC_947_948.Q_flow; TC_947_958.Q_flow = TC_947_958.G * TC_947_958.dT; TC_947_958.dT = TC_947_958.port_a.T - TC_947_958.port_b.T; TC_947_958.port_a.Q_flow = TC_947_958.Q_flow; TC_947_958.port_b.Q_flow = -TC_947_958.Q_flow; TC_947_1636.Q_flow = TC_947_1636.G * TC_947_1636.dT; TC_947_1636.dT = TC_947_1636.port_a.T - TC_947_1636.port_b.T; TC_947_1636.port_a.Q_flow = TC_947_1636.Q_flow; TC_947_1636.port_b.Q_flow = -TC_947_1636.Q_flow; TC_948_949.Q_flow = TC_948_949.G * TC_948_949.dT; TC_948_949.dT = TC_948_949.port_a.T - TC_948_949.port_b.T; TC_948_949.port_a.Q_flow = TC_948_949.Q_flow; TC_948_949.port_b.Q_flow = -TC_948_949.Q_flow; TC_948_959.Q_flow = TC_948_959.G * TC_948_959.dT; TC_948_959.dT = TC_948_959.port_a.T - TC_948_959.port_b.T; TC_948_959.port_a.Q_flow = TC_948_959.Q_flow; TC_948_959.port_b.Q_flow = -TC_948_959.Q_flow; TC_948_1637.Q_flow = TC_948_1637.G * TC_948_1637.dT; TC_948_1637.dT = TC_948_1637.port_a.T - TC_948_1637.port_b.T; TC_948_1637.port_a.Q_flow = TC_948_1637.Q_flow; TC_948_1637.port_b.Q_flow = -TC_948_1637.Q_flow; TC_949_950.Q_flow = TC_949_950.G * TC_949_950.dT; TC_949_950.dT = TC_949_950.port_a.T - TC_949_950.port_b.T; TC_949_950.port_a.Q_flow = TC_949_950.Q_flow; TC_949_950.port_b.Q_flow = -TC_949_950.Q_flow; TC_949_960.Q_flow = TC_949_960.G * TC_949_960.dT; TC_949_960.dT = TC_949_960.port_a.T - TC_949_960.port_b.T; TC_949_960.port_a.Q_flow = TC_949_960.Q_flow; TC_949_960.port_b.Q_flow = -TC_949_960.Q_flow; TC_949_1638.Q_flow = TC_949_1638.G * TC_949_1638.dT; TC_949_1638.dT = TC_949_1638.port_a.T - TC_949_1638.port_b.T; TC_949_1638.port_a.Q_flow = TC_949_1638.Q_flow; TC_949_1638.port_b.Q_flow = -TC_949_1638.Q_flow; TC_950_951.Q_flow = TC_950_951.G * TC_950_951.dT; TC_950_951.dT = TC_950_951.port_a.T - TC_950_951.port_b.T; TC_950_951.port_a.Q_flow = TC_950_951.Q_flow; TC_950_951.port_b.Q_flow = -TC_950_951.Q_flow; TC_950_961.Q_flow = TC_950_961.G * TC_950_961.dT; TC_950_961.dT = TC_950_961.port_a.T - TC_950_961.port_b.T; TC_950_961.port_a.Q_flow = TC_950_961.Q_flow; TC_950_961.port_b.Q_flow = -TC_950_961.Q_flow; TC_950_1092.Q_flow = TC_950_1092.G * TC_950_1092.dT; TC_950_1092.dT = TC_950_1092.port_a.T - TC_950_1092.port_b.T; TC_950_1092.port_a.Q_flow = TC_950_1092.Q_flow; TC_950_1092.port_b.Q_flow = -TC_950_1092.Q_flow; TC_951_952.Q_flow = TC_951_952.G * TC_951_952.dT; TC_951_952.dT = TC_951_952.port_a.T - TC_951_952.port_b.T; TC_951_952.port_a.Q_flow = TC_951_952.Q_flow; TC_951_952.port_b.Q_flow = -TC_951_952.Q_flow; TC_951_962.Q_flow = TC_951_962.G * TC_951_962.dT; TC_951_962.dT = TC_951_962.port_a.T - TC_951_962.port_b.T; TC_951_962.port_a.Q_flow = TC_951_962.Q_flow; TC_951_962.port_b.Q_flow = -TC_951_962.Q_flow; TC_951_1093.Q_flow = TC_951_1093.G * TC_951_1093.dT; TC_951_1093.dT = TC_951_1093.port_a.T - TC_951_1093.port_b.T; TC_951_1093.port_a.Q_flow = TC_951_1093.Q_flow; TC_951_1093.port_b.Q_flow = -TC_951_1093.Q_flow; TC_952_963.Q_flow = TC_952_963.G * TC_952_963.dT; TC_952_963.dT = TC_952_963.port_a.T - TC_952_963.port_b.T; TC_952_963.port_a.Q_flow = TC_952_963.Q_flow; TC_952_963.port_b.Q_flow = -TC_952_963.Q_flow; TC_952_1094.Q_flow = TC_952_1094.G * TC_952_1094.dT; TC_952_1094.dT = TC_952_1094.port_a.T - TC_952_1094.port_b.T; TC_952_1094.port_a.Q_flow = TC_952_1094.Q_flow; TC_952_1094.port_b.Q_flow = -TC_952_1094.Q_flow; TC_953_954.Q_flow = TC_953_954.G * TC_953_954.dT; TC_953_954.dT = TC_953_954.port_a.T - TC_953_954.port_b.T; TC_953_954.port_a.Q_flow = TC_953_954.Q_flow; TC_953_954.port_b.Q_flow = -TC_953_954.Q_flow; TC_953_964.Q_flow = TC_953_964.G * TC_953_964.dT; TC_953_964.dT = TC_953_964.port_a.T - TC_953_964.port_b.T; TC_953_964.port_a.Q_flow = TC_953_964.Q_flow; TC_953_964.port_b.Q_flow = -TC_953_964.Q_flow; TC_953_1095.Q_flow = TC_953_1095.G * TC_953_1095.dT; TC_953_1095.dT = TC_953_1095.port_a.T - TC_953_1095.port_b.T; TC_953_1095.port_a.Q_flow = TC_953_1095.Q_flow; TC_953_1095.port_b.Q_flow = -TC_953_1095.Q_flow; TC_954_955.Q_flow = TC_954_955.G * TC_954_955.dT; TC_954_955.dT = TC_954_955.port_a.T - TC_954_955.port_b.T; TC_954_955.port_a.Q_flow = TC_954_955.Q_flow; TC_954_955.port_b.Q_flow = -TC_954_955.Q_flow; TC_954_965.Q_flow = TC_954_965.G * TC_954_965.dT; TC_954_965.dT = TC_954_965.port_a.T - TC_954_965.port_b.T; TC_954_965.port_a.Q_flow = TC_954_965.Q_flow; TC_954_965.port_b.Q_flow = -TC_954_965.Q_flow; TC_954_1096.Q_flow = TC_954_1096.G * TC_954_1096.dT; TC_954_1096.dT = TC_954_1096.port_a.T - TC_954_1096.port_b.T; TC_954_1096.port_a.Q_flow = TC_954_1096.Q_flow; TC_954_1096.port_b.Q_flow = -TC_954_1096.Q_flow; TC_955_956.Q_flow = TC_955_956.G * TC_955_956.dT; TC_955_956.dT = TC_955_956.port_a.T - TC_955_956.port_b.T; TC_955_956.port_a.Q_flow = TC_955_956.Q_flow; TC_955_956.port_b.Q_flow = -TC_955_956.Q_flow; TC_955_966.Q_flow = TC_955_966.G * TC_955_966.dT; TC_955_966.dT = TC_955_966.port_a.T - TC_955_966.port_b.T; TC_955_966.port_a.Q_flow = TC_955_966.Q_flow; TC_955_966.port_b.Q_flow = -TC_955_966.Q_flow; TC_955_1097.Q_flow = TC_955_1097.G * TC_955_1097.dT; TC_955_1097.dT = TC_955_1097.port_a.T - TC_955_1097.port_b.T; TC_955_1097.port_a.Q_flow = TC_955_1097.Q_flow; TC_955_1097.port_b.Q_flow = -TC_955_1097.Q_flow; TC_956_957.Q_flow = TC_956_957.G * TC_956_957.dT; TC_956_957.dT = TC_956_957.port_a.T - TC_956_957.port_b.T; TC_956_957.port_a.Q_flow = TC_956_957.Q_flow; TC_956_957.port_b.Q_flow = -TC_956_957.Q_flow; TC_956_967.Q_flow = TC_956_967.G * TC_956_967.dT; TC_956_967.dT = TC_956_967.port_a.T - TC_956_967.port_b.T; TC_956_967.port_a.Q_flow = TC_956_967.Q_flow; TC_956_967.port_b.Q_flow = -TC_956_967.Q_flow; TC_956_1098.Q_flow = TC_956_1098.G * TC_956_1098.dT; TC_956_1098.dT = TC_956_1098.port_a.T - TC_956_1098.port_b.T; TC_956_1098.port_a.Q_flow = TC_956_1098.Q_flow; TC_956_1098.port_b.Q_flow = -TC_956_1098.Q_flow; TC_957_958.Q_flow = TC_957_958.G * TC_957_958.dT; TC_957_958.dT = TC_957_958.port_a.T - TC_957_958.port_b.T; TC_957_958.port_a.Q_flow = TC_957_958.Q_flow; TC_957_958.port_b.Q_flow = -TC_957_958.Q_flow; TC_957_968.Q_flow = TC_957_968.G * TC_957_968.dT; TC_957_968.dT = TC_957_968.port_a.T - TC_957_968.port_b.T; TC_957_968.port_a.Q_flow = TC_957_968.Q_flow; TC_957_968.port_b.Q_flow = -TC_957_968.Q_flow; TC_957_1639.Q_flow = TC_957_1639.G * TC_957_1639.dT; TC_957_1639.dT = TC_957_1639.port_a.T - TC_957_1639.port_b.T; TC_957_1639.port_a.Q_flow = TC_957_1639.Q_flow; TC_957_1639.port_b.Q_flow = -TC_957_1639.Q_flow; TC_958_959.Q_flow = TC_958_959.G * TC_958_959.dT; TC_958_959.dT = TC_958_959.port_a.T - TC_958_959.port_b.T; TC_958_959.port_a.Q_flow = TC_958_959.Q_flow; TC_958_959.port_b.Q_flow = -TC_958_959.Q_flow; TC_958_969.Q_flow = TC_958_969.G * TC_958_969.dT; TC_958_969.dT = TC_958_969.port_a.T - TC_958_969.port_b.T; TC_958_969.port_a.Q_flow = TC_958_969.Q_flow; TC_958_969.port_b.Q_flow = -TC_958_969.Q_flow; TC_958_1640.Q_flow = TC_958_1640.G * TC_958_1640.dT; TC_958_1640.dT = TC_958_1640.port_a.T - TC_958_1640.port_b.T; TC_958_1640.port_a.Q_flow = TC_958_1640.Q_flow; TC_958_1640.port_b.Q_flow = -TC_958_1640.Q_flow; TC_959_960.Q_flow = TC_959_960.G * TC_959_960.dT; TC_959_960.dT = TC_959_960.port_a.T - TC_959_960.port_b.T; TC_959_960.port_a.Q_flow = TC_959_960.Q_flow; TC_959_960.port_b.Q_flow = -TC_959_960.Q_flow; TC_959_970.Q_flow = TC_959_970.G * TC_959_970.dT; TC_959_970.dT = TC_959_970.port_a.T - TC_959_970.port_b.T; TC_959_970.port_a.Q_flow = TC_959_970.Q_flow; TC_959_970.port_b.Q_flow = -TC_959_970.Q_flow; TC_959_1641.Q_flow = TC_959_1641.G * TC_959_1641.dT; TC_959_1641.dT = TC_959_1641.port_a.T - TC_959_1641.port_b.T; TC_959_1641.port_a.Q_flow = TC_959_1641.Q_flow; TC_959_1641.port_b.Q_flow = -TC_959_1641.Q_flow; TC_960_961.Q_flow = TC_960_961.G * TC_960_961.dT; TC_960_961.dT = TC_960_961.port_a.T - TC_960_961.port_b.T; TC_960_961.port_a.Q_flow = TC_960_961.Q_flow; TC_960_961.port_b.Q_flow = -TC_960_961.Q_flow; TC_960_971.Q_flow = TC_960_971.G * TC_960_971.dT; TC_960_971.dT = TC_960_971.port_a.T - TC_960_971.port_b.T; TC_960_971.port_a.Q_flow = TC_960_971.Q_flow; TC_960_971.port_b.Q_flow = -TC_960_971.Q_flow; TC_960_1642.Q_flow = TC_960_1642.G * TC_960_1642.dT; TC_960_1642.dT = TC_960_1642.port_a.T - TC_960_1642.port_b.T; TC_960_1642.port_a.Q_flow = TC_960_1642.Q_flow; TC_960_1642.port_b.Q_flow = -TC_960_1642.Q_flow; TC_961_962.Q_flow = TC_961_962.G * TC_961_962.dT; TC_961_962.dT = TC_961_962.port_a.T - TC_961_962.port_b.T; TC_961_962.port_a.Q_flow = TC_961_962.Q_flow; TC_961_962.port_b.Q_flow = -TC_961_962.Q_flow; TC_961_972.Q_flow = TC_961_972.G * TC_961_972.dT; TC_961_972.dT = TC_961_972.port_a.T - TC_961_972.port_b.T; TC_961_972.port_a.Q_flow = TC_961_972.Q_flow; TC_961_972.port_b.Q_flow = -TC_961_972.Q_flow; TC_961_1028.Q_flow = TC_961_1028.G * TC_961_1028.dT; TC_961_1028.dT = TC_961_1028.port_a.T - TC_961_1028.port_b.T; TC_961_1028.port_a.Q_flow = TC_961_1028.Q_flow; TC_961_1028.port_b.Q_flow = -TC_961_1028.Q_flow; TC_962_963.Q_flow = TC_962_963.G * TC_962_963.dT; TC_962_963.dT = TC_962_963.port_a.T - TC_962_963.port_b.T; TC_962_963.port_a.Q_flow = TC_962_963.Q_flow; TC_962_963.port_b.Q_flow = -TC_962_963.Q_flow; TC_962_973.Q_flow = TC_962_973.G * TC_962_973.dT; TC_962_973.dT = TC_962_973.port_a.T - TC_962_973.port_b.T; TC_962_973.port_a.Q_flow = TC_962_973.Q_flow; TC_962_973.port_b.Q_flow = -TC_962_973.Q_flow; TC_962_1029.Q_flow = TC_962_1029.G * TC_962_1029.dT; TC_962_1029.dT = TC_962_1029.port_a.T - TC_962_1029.port_b.T; TC_962_1029.port_a.Q_flow = TC_962_1029.Q_flow; TC_962_1029.port_b.Q_flow = -TC_962_1029.Q_flow; TC_963_974.Q_flow = TC_963_974.G * TC_963_974.dT; TC_963_974.dT = TC_963_974.port_a.T - TC_963_974.port_b.T; TC_963_974.port_a.Q_flow = TC_963_974.Q_flow; TC_963_974.port_b.Q_flow = -TC_963_974.Q_flow; TC_963_1030.Q_flow = TC_963_1030.G * TC_963_1030.dT; TC_963_1030.dT = TC_963_1030.port_a.T - TC_963_1030.port_b.T; TC_963_1030.port_a.Q_flow = TC_963_1030.Q_flow; TC_963_1030.port_b.Q_flow = -TC_963_1030.Q_flow; TC_964_965.Q_flow = TC_964_965.G * TC_964_965.dT; TC_964_965.dT = TC_964_965.port_a.T - TC_964_965.port_b.T; TC_964_965.port_a.Q_flow = TC_964_965.Q_flow; TC_964_965.port_b.Q_flow = -TC_964_965.Q_flow; TC_964_1031.Q_flow = TC_964_1031.G * TC_964_1031.dT; TC_964_1031.dT = TC_964_1031.port_a.T - TC_964_1031.port_b.T; TC_964_1031.port_a.Q_flow = TC_964_1031.Q_flow; TC_964_1031.port_b.Q_flow = -TC_964_1031.Q_flow; TC_965_966.Q_flow = TC_965_966.G * TC_965_966.dT; TC_965_966.dT = TC_965_966.port_a.T - TC_965_966.port_b.T; TC_965_966.port_a.Q_flow = TC_965_966.Q_flow; TC_965_966.port_b.Q_flow = -TC_965_966.Q_flow; TC_965_1032.Q_flow = TC_965_1032.G * TC_965_1032.dT; TC_965_1032.dT = TC_965_1032.port_a.T - TC_965_1032.port_b.T; TC_965_1032.port_a.Q_flow = TC_965_1032.Q_flow; TC_965_1032.port_b.Q_flow = -TC_965_1032.Q_flow; TC_966_967.Q_flow = TC_966_967.G * TC_966_967.dT; TC_966_967.dT = TC_966_967.port_a.T - TC_966_967.port_b.T; TC_966_967.port_a.Q_flow = TC_966_967.Q_flow; TC_966_967.port_b.Q_flow = -TC_966_967.Q_flow; TC_966_1033.Q_flow = TC_966_1033.G * TC_966_1033.dT; TC_966_1033.dT = TC_966_1033.port_a.T - TC_966_1033.port_b.T; TC_966_1033.port_a.Q_flow = TC_966_1033.Q_flow; TC_966_1033.port_b.Q_flow = -TC_966_1033.Q_flow; TC_967_968.Q_flow = TC_967_968.G * TC_967_968.dT; TC_967_968.dT = TC_967_968.port_a.T - TC_967_968.port_b.T; TC_967_968.port_a.Q_flow = TC_967_968.Q_flow; TC_967_968.port_b.Q_flow = -TC_967_968.Q_flow; TC_967_1034.Q_flow = TC_967_1034.G * TC_967_1034.dT; TC_967_1034.dT = TC_967_1034.port_a.T - TC_967_1034.port_b.T; TC_967_1034.port_a.Q_flow = TC_967_1034.Q_flow; TC_967_1034.port_b.Q_flow = -TC_967_1034.Q_flow; TC_968_969.Q_flow = TC_968_969.G * TC_968_969.dT; TC_968_969.dT = TC_968_969.port_a.T - TC_968_969.port_b.T; TC_968_969.port_a.Q_flow = TC_968_969.Q_flow; TC_968_969.port_b.Q_flow = -TC_968_969.Q_flow; TC_968_1643.Q_flow = TC_968_1643.G * TC_968_1643.dT; TC_968_1643.dT = TC_968_1643.port_a.T - TC_968_1643.port_b.T; TC_968_1643.port_a.Q_flow = TC_968_1643.Q_flow; TC_968_1643.port_b.Q_flow = -TC_968_1643.Q_flow; TC_969_970.Q_flow = TC_969_970.G * TC_969_970.dT; TC_969_970.dT = TC_969_970.port_a.T - TC_969_970.port_b.T; TC_969_970.port_a.Q_flow = TC_969_970.Q_flow; TC_969_970.port_b.Q_flow = -TC_969_970.Q_flow; TC_969_1644.Q_flow = TC_969_1644.G * TC_969_1644.dT; TC_969_1644.dT = TC_969_1644.port_a.T - TC_969_1644.port_b.T; TC_969_1644.port_a.Q_flow = TC_969_1644.Q_flow; TC_969_1644.port_b.Q_flow = -TC_969_1644.Q_flow; TC_970_971.Q_flow = TC_970_971.G * TC_970_971.dT; TC_970_971.dT = TC_970_971.port_a.T - TC_970_971.port_b.T; TC_970_971.port_a.Q_flow = TC_970_971.Q_flow; TC_970_971.port_b.Q_flow = -TC_970_971.Q_flow; TC_970_1645.Q_flow = TC_970_1645.G * TC_970_1645.dT; TC_970_1645.dT = TC_970_1645.port_a.T - TC_970_1645.port_b.T; TC_970_1645.port_a.Q_flow = TC_970_1645.Q_flow; TC_970_1645.port_b.Q_flow = -TC_970_1645.Q_flow; TC_971_972.Q_flow = TC_971_972.G * TC_971_972.dT; TC_971_972.dT = TC_971_972.port_a.T - TC_971_972.port_b.T; TC_971_972.port_a.Q_flow = TC_971_972.Q_flow; TC_971_972.port_b.Q_flow = -TC_971_972.Q_flow; TC_971_1646.Q_flow = TC_971_1646.G * TC_971_1646.dT; TC_971_1646.dT = TC_971_1646.port_a.T - TC_971_1646.port_b.T; TC_971_1646.port_a.Q_flow = TC_971_1646.Q_flow; TC_971_1646.port_b.Q_flow = -TC_971_1646.Q_flow; TC_972_973.Q_flow = TC_972_973.G * TC_972_973.dT; TC_972_973.dT = TC_972_973.port_a.T - TC_972_973.port_b.T; TC_972_973.port_a.Q_flow = TC_972_973.Q_flow; TC_972_973.port_b.Q_flow = -TC_972_973.Q_flow; TC_972_1035.Q_flow = TC_972_1035.G * TC_972_1035.dT; TC_972_1035.dT = TC_972_1035.port_a.T - TC_972_1035.port_b.T; TC_972_1035.port_a.Q_flow = TC_972_1035.Q_flow; TC_972_1035.port_b.Q_flow = -TC_972_1035.Q_flow; TC_973_974.Q_flow = TC_973_974.G * TC_973_974.dT; TC_973_974.dT = TC_973_974.port_a.T - TC_973_974.port_b.T; TC_973_974.port_a.Q_flow = TC_973_974.Q_flow; TC_973_974.port_b.Q_flow = -TC_973_974.Q_flow; TC_973_1036.Q_flow = TC_973_1036.G * TC_973_1036.dT; TC_973_1036.dT = TC_973_1036.port_a.T - TC_973_1036.port_b.T; TC_973_1036.port_a.Q_flow = TC_973_1036.Q_flow; TC_973_1036.port_b.Q_flow = -TC_973_1036.Q_flow; TC_974_1037.Q_flow = TC_974_1037.G * TC_974_1037.dT; TC_974_1037.dT = TC_974_1037.port_a.T - TC_974_1037.port_b.T; TC_974_1037.port_a.Q_flow = TC_974_1037.Q_flow; TC_974_1037.port_b.Q_flow = -TC_974_1037.Q_flow; TC_975_976.Q_flow = TC_975_976.G * TC_975_976.dT; TC_975_976.dT = TC_975_976.port_a.T - TC_975_976.port_b.T; TC_975_976.port_a.Q_flow = TC_975_976.Q_flow; TC_975_976.port_b.Q_flow = -TC_975_976.Q_flow; TC_975_983.Q_flow = TC_975_983.G * TC_975_983.dT; TC_975_983.dT = TC_975_983.port_a.T - TC_975_983.port_b.T; TC_975_983.port_a.Q_flow = TC_975_983.Q_flow; TC_975_983.port_b.Q_flow = -TC_975_983.Q_flow; TC_975_1058.Q_flow = TC_975_1058.G * TC_975_1058.dT; TC_975_1058.dT = TC_975_1058.port_a.T - TC_975_1058.port_b.T; TC_975_1058.port_a.Q_flow = TC_975_1058.Q_flow; TC_975_1058.port_b.Q_flow = -TC_975_1058.Q_flow; TC_975_1598.Q_flow = TC_975_1598.G * TC_975_1598.dT; TC_975_1598.dT = TC_975_1598.port_a.T - TC_975_1598.port_b.T; TC_975_1598.port_a.Q_flow = TC_975_1598.Q_flow; TC_975_1598.port_b.Q_flow = -TC_975_1598.Q_flow; TC_975_1649.Q_flow = TC_975_1649.G * TC_975_1649.dT; TC_975_1649.dT = TC_975_1649.port_a.T - TC_975_1649.port_b.T; TC_975_1649.port_a.Q_flow = TC_975_1649.Q_flow; TC_975_1649.port_b.Q_flow = -TC_975_1649.Q_flow; TC_976_984.Q_flow = TC_976_984.G * TC_976_984.dT; TC_976_984.dT = TC_976_984.port_a.T - TC_976_984.port_b.T; TC_976_984.port_a.Q_flow = TC_976_984.Q_flow; TC_976_984.port_b.Q_flow = -TC_976_984.Q_flow; TC_976_1059.Q_flow = TC_976_1059.G * TC_976_1059.dT; TC_976_1059.dT = TC_976_1059.port_a.T - TC_976_1059.port_b.T; TC_976_1059.port_a.Q_flow = TC_976_1059.Q_flow; TC_976_1059.port_b.Q_flow = -TC_976_1059.Q_flow; TC_976_1123.Q_flow = TC_976_1123.G * TC_976_1123.dT; TC_976_1123.dT = TC_976_1123.port_a.T - TC_976_1123.port_b.T; TC_976_1123.port_a.Q_flow = TC_976_1123.Q_flow; TC_976_1123.port_b.Q_flow = -TC_976_1123.Q_flow; TC_977_978.Q_flow = TC_977_978.G * TC_977_978.dT; TC_977_978.dT = TC_977_978.port_a.T - TC_977_978.port_b.T; TC_977_978.port_a.Q_flow = TC_977_978.Q_flow; TC_977_978.port_b.Q_flow = -TC_977_978.Q_flow; TC_977_985.Q_flow = TC_977_985.G * TC_977_985.dT; TC_977_985.dT = TC_977_985.port_a.T - TC_977_985.port_b.T; TC_977_985.port_a.Q_flow = TC_977_985.Q_flow; TC_977_985.port_b.Q_flow = -TC_977_985.Q_flow; TC_977_1060.Q_flow = TC_977_1060.G * TC_977_1060.dT; TC_977_1060.dT = TC_977_1060.port_a.T - TC_977_1060.port_b.T; TC_977_1060.port_a.Q_flow = TC_977_1060.Q_flow; TC_977_1060.port_b.Q_flow = -TC_977_1060.Q_flow; TC_977_1124.Q_flow = TC_977_1124.G * TC_977_1124.dT; TC_977_1124.dT = TC_977_1124.port_a.T - TC_977_1124.port_b.T; TC_977_1124.port_a.Q_flow = TC_977_1124.Q_flow; TC_977_1124.port_b.Q_flow = -TC_977_1124.Q_flow; TC_978_979.Q_flow = TC_978_979.G * TC_978_979.dT; TC_978_979.dT = TC_978_979.port_a.T - TC_978_979.port_b.T; TC_978_979.port_a.Q_flow = TC_978_979.Q_flow; TC_978_979.port_b.Q_flow = -TC_978_979.Q_flow; TC_978_986.Q_flow = TC_978_986.G * TC_978_986.dT; TC_978_986.dT = TC_978_986.port_a.T - TC_978_986.port_b.T; TC_978_986.port_a.Q_flow = TC_978_986.Q_flow; TC_978_986.port_b.Q_flow = -TC_978_986.Q_flow; TC_978_1061.Q_flow = TC_978_1061.G * TC_978_1061.dT; TC_978_1061.dT = TC_978_1061.port_a.T - TC_978_1061.port_b.T; TC_978_1061.port_a.Q_flow = TC_978_1061.Q_flow; TC_978_1061.port_b.Q_flow = -TC_978_1061.Q_flow; TC_978_1599.Q_flow = TC_978_1599.G * TC_978_1599.dT; TC_978_1599.dT = TC_978_1599.port_a.T - TC_978_1599.port_b.T; TC_978_1599.port_a.Q_flow = TC_978_1599.Q_flow; TC_978_1599.port_b.Q_flow = -TC_978_1599.Q_flow; TC_979_980.Q_flow = TC_979_980.G * TC_979_980.dT; TC_979_980.dT = TC_979_980.port_a.T - TC_979_980.port_b.T; TC_979_980.port_a.Q_flow = TC_979_980.Q_flow; TC_979_980.port_b.Q_flow = -TC_979_980.Q_flow; TC_979_1062.Q_flow = TC_979_1062.G * TC_979_1062.dT; TC_979_1062.dT = TC_979_1062.port_a.T - TC_979_1062.port_b.T; TC_979_1062.port_a.Q_flow = TC_979_1062.Q_flow; TC_979_1062.port_b.Q_flow = -TC_979_1062.Q_flow; TC_979_1600.Q_flow = TC_979_1600.G * TC_979_1600.dT; TC_979_1600.dT = TC_979_1600.port_a.T - TC_979_1600.port_b.T; TC_979_1600.port_a.Q_flow = TC_979_1600.Q_flow; TC_979_1600.port_b.Q_flow = -TC_979_1600.Q_flow; TC_979_1656.Q_flow = TC_979_1656.G * TC_979_1656.dT; TC_979_1656.dT = TC_979_1656.port_a.T - TC_979_1656.port_b.T; TC_979_1656.port_a.Q_flow = TC_979_1656.Q_flow; TC_979_1656.port_b.Q_flow = -TC_979_1656.Q_flow; TC_980_981.Q_flow = TC_980_981.G * TC_980_981.dT; TC_980_981.dT = TC_980_981.port_a.T - TC_980_981.port_b.T; TC_980_981.port_a.Q_flow = TC_980_981.Q_flow; TC_980_981.port_b.Q_flow = -TC_980_981.Q_flow; TC_980_1063.Q_flow = TC_980_1063.G * TC_980_1063.dT; TC_980_1063.dT = TC_980_1063.port_a.T - TC_980_1063.port_b.T; TC_980_1063.port_a.Q_flow = TC_980_1063.Q_flow; TC_980_1063.port_b.Q_flow = -TC_980_1063.Q_flow; TC_980_1601.Q_flow = TC_980_1601.G * TC_980_1601.dT; TC_980_1601.dT = TC_980_1601.port_a.T - TC_980_1601.port_b.T; TC_980_1601.port_a.Q_flow = TC_980_1601.Q_flow; TC_980_1601.port_b.Q_flow = -TC_980_1601.Q_flow; TC_980_1657.Q_flow = TC_980_1657.G * TC_980_1657.dT; TC_980_1657.dT = TC_980_1657.port_a.T - TC_980_1657.port_b.T; TC_980_1657.port_a.Q_flow = TC_980_1657.Q_flow; TC_980_1657.port_b.Q_flow = -TC_980_1657.Q_flow; TC_981_982.Q_flow = TC_981_982.G * TC_981_982.dT; TC_981_982.dT = TC_981_982.port_a.T - TC_981_982.port_b.T; TC_981_982.port_a.Q_flow = TC_981_982.Q_flow; TC_981_982.port_b.Q_flow = -TC_981_982.Q_flow; TC_981_1064.Q_flow = TC_981_1064.G * TC_981_1064.dT; TC_981_1064.dT = TC_981_1064.port_a.T - TC_981_1064.port_b.T; TC_981_1064.port_a.Q_flow = TC_981_1064.Q_flow; TC_981_1064.port_b.Q_flow = -TC_981_1064.Q_flow; TC_981_1602.Q_flow = TC_981_1602.G * TC_981_1602.dT; TC_981_1602.dT = TC_981_1602.port_a.T - TC_981_1602.port_b.T; TC_981_1602.port_a.Q_flow = TC_981_1602.Q_flow; TC_981_1602.port_b.Q_flow = -TC_981_1602.Q_flow; TC_981_1658.Q_flow = TC_981_1658.G * TC_981_1658.dT; TC_981_1658.dT = TC_981_1658.port_a.T - TC_981_1658.port_b.T; TC_981_1658.port_a.Q_flow = TC_981_1658.Q_flow; TC_981_1658.port_b.Q_flow = -TC_981_1658.Q_flow; TC_982_987.Q_flow = TC_982_987.G * TC_982_987.dT; TC_982_987.dT = TC_982_987.port_a.T - TC_982_987.port_b.T; TC_982_987.port_a.Q_flow = TC_982_987.Q_flow; TC_982_987.port_b.Q_flow = -TC_982_987.Q_flow; TC_982_1065.Q_flow = TC_982_1065.G * TC_982_1065.dT; TC_982_1065.dT = TC_982_1065.port_a.T - TC_982_1065.port_b.T; TC_982_1065.port_a.Q_flow = TC_982_1065.Q_flow; TC_982_1065.port_b.Q_flow = -TC_982_1065.Q_flow; TC_982_1603.Q_flow = TC_982_1603.G * TC_982_1603.dT; TC_982_1603.dT = TC_982_1603.port_a.T - TC_982_1603.port_b.T; TC_982_1603.port_a.Q_flow = TC_982_1603.Q_flow; TC_982_1603.port_b.Q_flow = -TC_982_1603.Q_flow; TC_982_1650.Q_flow = TC_982_1650.G * TC_982_1650.dT; TC_982_1650.dT = TC_982_1650.port_a.T - TC_982_1650.port_b.T; TC_982_1650.port_a.Q_flow = TC_982_1650.Q_flow; TC_982_1650.port_b.Q_flow = -TC_982_1650.Q_flow; TC_983_984.Q_flow = TC_983_984.G * TC_983_984.dT; TC_983_984.dT = TC_983_984.port_a.T - TC_983_984.port_b.T; TC_983_984.port_a.Q_flow = TC_983_984.Q_flow; TC_983_984.port_b.Q_flow = -TC_983_984.Q_flow; TC_983_988.Q_flow = TC_983_988.G * TC_983_988.dT; TC_983_988.dT = TC_983_988.port_a.T - TC_983_988.port_b.T; TC_983_988.port_a.Q_flow = TC_983_988.Q_flow; TC_983_988.port_b.Q_flow = -TC_983_988.Q_flow; TC_983_1607.Q_flow = TC_983_1607.G * TC_983_1607.dT; TC_983_1607.dT = TC_983_1607.port_a.T - TC_983_1607.port_b.T; TC_983_1607.port_a.Q_flow = TC_983_1607.Q_flow; TC_983_1607.port_b.Q_flow = -TC_983_1607.Q_flow; TC_983_1652.Q_flow = TC_983_1652.G * TC_983_1652.dT; TC_983_1652.dT = TC_983_1652.port_a.T - TC_983_1652.port_b.T; TC_983_1652.port_a.Q_flow = TC_983_1652.Q_flow; TC_983_1652.port_b.Q_flow = -TC_983_1652.Q_flow; TC_984_989.Q_flow = TC_984_989.G * TC_984_989.dT; TC_984_989.dT = TC_984_989.port_a.T - TC_984_989.port_b.T; TC_984_989.port_a.Q_flow = TC_984_989.Q_flow; TC_984_989.port_b.Q_flow = -TC_984_989.Q_flow; TC_984_1125.Q_flow = TC_984_1125.G * TC_984_1125.dT; TC_984_1125.dT = TC_984_1125.port_a.T - TC_984_1125.port_b.T; TC_984_1125.port_a.Q_flow = TC_984_1125.Q_flow; TC_984_1125.port_b.Q_flow = -TC_984_1125.Q_flow; TC_985_986.Q_flow = TC_985_986.G * TC_985_986.dT; TC_985_986.dT = TC_985_986.port_a.T - TC_985_986.port_b.T; TC_985_986.port_a.Q_flow = TC_985_986.Q_flow; TC_985_986.port_b.Q_flow = -TC_985_986.Q_flow; TC_985_990.Q_flow = TC_985_990.G * TC_985_990.dT; TC_985_990.dT = TC_985_990.port_a.T - TC_985_990.port_b.T; TC_985_990.port_a.Q_flow = TC_985_990.Q_flow; TC_985_990.port_b.Q_flow = -TC_985_990.Q_flow; TC_985_1126.Q_flow = TC_985_1126.G * TC_985_1126.dT; TC_985_1126.dT = TC_985_1126.port_a.T - TC_985_1126.port_b.T; TC_985_1126.port_a.Q_flow = TC_985_1126.Q_flow; TC_985_1126.port_b.Q_flow = -TC_985_1126.Q_flow; TC_986_991.Q_flow = TC_986_991.G * TC_986_991.dT; TC_986_991.dT = TC_986_991.port_a.T - TC_986_991.port_b.T; TC_986_991.port_a.Q_flow = TC_986_991.Q_flow; TC_986_991.port_b.Q_flow = -TC_986_991.Q_flow; TC_986_1527.Q_flow = TC_986_1527.G * TC_986_1527.dT; TC_986_1527.dT = TC_986_1527.port_a.T - TC_986_1527.port_b.T; TC_986_1527.port_a.Q_flow = TC_986_1527.Q_flow; TC_986_1527.port_b.Q_flow = -TC_986_1527.Q_flow; TC_986_1656.Q_flow = TC_986_1656.G * TC_986_1656.dT; TC_986_1656.dT = TC_986_1656.port_a.T - TC_986_1656.port_b.T; TC_986_1656.port_a.Q_flow = TC_986_1656.Q_flow; TC_986_1656.port_b.Q_flow = -TC_986_1656.Q_flow; TC_987_992.Q_flow = TC_987_992.G * TC_987_992.dT; TC_987_992.dT = TC_987_992.port_a.T - TC_987_992.port_b.T; TC_987_992.port_a.Q_flow = TC_987_992.Q_flow; TC_987_992.port_b.Q_flow = -TC_987_992.Q_flow; TC_987_1531.Q_flow = TC_987_1531.G * TC_987_1531.dT; TC_987_1531.dT = TC_987_1531.port_a.T - TC_987_1531.port_b.T; TC_987_1531.port_a.Q_flow = TC_987_1531.Q_flow; TC_987_1531.port_b.Q_flow = -TC_987_1531.Q_flow; TC_987_1653.Q_flow = TC_987_1653.G * TC_987_1653.dT; TC_987_1653.dT = TC_987_1653.port_a.T - TC_987_1653.port_b.T; TC_987_1653.port_a.Q_flow = TC_987_1653.Q_flow; TC_987_1653.port_b.Q_flow = -TC_987_1653.Q_flow; TC_987_1658.Q_flow = TC_987_1658.G * TC_987_1658.dT; TC_987_1658.dT = TC_987_1658.port_a.T - TC_987_1658.port_b.T; TC_987_1658.port_a.Q_flow = TC_987_1658.Q_flow; TC_987_1658.port_b.Q_flow = -TC_987_1658.Q_flow; TC_988_989.Q_flow = TC_988_989.G * TC_988_989.dT; TC_988_989.dT = TC_988_989.port_a.T - TC_988_989.port_b.T; TC_988_989.port_a.Q_flow = TC_988_989.Q_flow; TC_988_989.port_b.Q_flow = -TC_988_989.Q_flow; TC_988_996.Q_flow = TC_988_996.G * TC_988_996.dT; TC_988_996.dT = TC_988_996.port_a.T - TC_988_996.port_b.T; TC_988_996.port_a.Q_flow = TC_988_996.Q_flow; TC_988_996.port_b.Q_flow = -TC_988_996.Q_flow; TC_988_1535.Q_flow = TC_988_1535.G * TC_988_1535.dT; TC_988_1535.dT = TC_988_1535.port_a.T - TC_988_1535.port_b.T; TC_988_1535.port_a.Q_flow = TC_988_1535.Q_flow; TC_988_1535.port_b.Q_flow = -TC_988_1535.Q_flow; TC_988_1655.Q_flow = TC_988_1655.G * TC_988_1655.dT; TC_988_1655.dT = TC_988_1655.port_a.T - TC_988_1655.port_b.T; TC_988_1655.port_a.Q_flow = TC_988_1655.Q_flow; TC_988_1655.port_b.Q_flow = -TC_988_1655.Q_flow; TC_989_997.Q_flow = TC_989_997.G * TC_989_997.dT; TC_989_997.dT = TC_989_997.port_a.T - TC_989_997.port_b.T; TC_989_997.port_a.Q_flow = TC_989_997.Q_flow; TC_989_997.port_b.Q_flow = -TC_989_997.Q_flow; TC_989_1127.Q_flow = TC_989_1127.G * TC_989_1127.dT; TC_989_1127.dT = TC_989_1127.port_a.T - TC_989_1127.port_b.T; TC_989_1127.port_a.Q_flow = TC_989_1127.Q_flow; TC_989_1127.port_b.Q_flow = -TC_989_1127.Q_flow; TC_990_991.Q_flow = TC_990_991.G * TC_990_991.dT; TC_990_991.dT = TC_990_991.port_a.T - TC_990_991.port_b.T; TC_990_991.port_a.Q_flow = TC_990_991.Q_flow; TC_990_991.port_b.Q_flow = -TC_990_991.Q_flow; TC_990_998.Q_flow = TC_990_998.G * TC_990_998.dT; TC_990_998.dT = TC_990_998.port_a.T - TC_990_998.port_b.T; TC_990_998.port_a.Q_flow = TC_990_998.Q_flow; TC_990_998.port_b.Q_flow = -TC_990_998.Q_flow; TC_990_1128.Q_flow = TC_990_1128.G * TC_990_1128.dT; TC_990_1128.dT = TC_990_1128.port_a.T - TC_990_1128.port_b.T; TC_990_1128.port_a.Q_flow = TC_990_1128.Q_flow; TC_990_1128.port_b.Q_flow = -TC_990_1128.Q_flow; TC_991_999.Q_flow = TC_991_999.G * TC_991_999.dT; TC_991_999.dT = TC_991_999.port_a.T - TC_991_999.port_b.T; TC_991_999.port_a.Q_flow = TC_991_999.Q_flow; TC_991_999.port_b.Q_flow = -TC_991_999.Q_flow; TC_991_1536.Q_flow = TC_991_1536.G * TC_991_1536.dT; TC_991_1536.dT = TC_991_1536.port_a.T - TC_991_1536.port_b.T; TC_991_1536.port_a.Q_flow = TC_991_1536.Q_flow; TC_991_1536.port_b.Q_flow = -TC_991_1536.Q_flow; TC_991_1659.Q_flow = TC_991_1659.G * TC_991_1659.dT; TC_991_1659.dT = TC_991_1659.port_a.T - TC_991_1659.port_b.T; TC_991_1659.port_a.Q_flow = TC_991_1659.Q_flow; TC_991_1659.port_b.Q_flow = -TC_991_1659.Q_flow; TC_992_993.Q_flow = TC_992_993.G * TC_992_993.dT; TC_992_993.dT = TC_992_993.port_a.T - TC_992_993.port_b.T; TC_992_993.port_a.Q_flow = TC_992_993.Q_flow; TC_992_993.port_b.Q_flow = -TC_992_993.Q_flow; TC_992_1000.Q_flow = TC_992_1000.G * TC_992_1000.dT; TC_992_1000.dT = TC_992_1000.port_a.T - TC_992_1000.port_b.T; TC_992_1000.port_a.Q_flow = TC_992_1000.Q_flow; TC_992_1000.port_b.Q_flow = -TC_992_1000.Q_flow; TC_992_1540.Q_flow = TC_992_1540.G * TC_992_1540.dT; TC_992_1540.dT = TC_992_1540.port_a.T - TC_992_1540.port_b.T; TC_992_1540.port_a.Q_flow = TC_992_1540.Q_flow; TC_992_1540.port_b.Q_flow = -TC_992_1540.Q_flow; TC_992_1661.Q_flow = TC_992_1661.G * TC_992_1661.dT; TC_992_1661.dT = TC_992_1661.port_a.T - TC_992_1661.port_b.T; TC_992_1661.port_a.Q_flow = TC_992_1661.Q_flow; TC_992_1661.port_b.Q_flow = -TC_992_1661.Q_flow; TC_993_994.Q_flow = TC_993_994.G * TC_993_994.dT; TC_993_994.dT = TC_993_994.port_a.T - TC_993_994.port_b.T; TC_993_994.port_a.Q_flow = TC_993_994.Q_flow; TC_993_994.port_b.Q_flow = -TC_993_994.Q_flow; TC_993_1001.Q_flow = TC_993_1001.G * TC_993_1001.dT; TC_993_1001.dT = TC_993_1001.port_a.T - TC_993_1001.port_b.T; TC_993_1001.port_a.Q_flow = TC_993_1001.Q_flow; TC_993_1001.port_b.Q_flow = -TC_993_1001.Q_flow; TC_993_1541.Q_flow = TC_993_1541.G * TC_993_1541.dT; TC_993_1541.dT = TC_993_1541.port_a.T - TC_993_1541.port_b.T; TC_993_1541.port_a.Q_flow = TC_993_1541.Q_flow; TC_993_1541.port_b.Q_flow = -TC_993_1541.Q_flow; TC_993_1653.Q_flow = TC_993_1653.G * TC_993_1653.dT; TC_993_1653.dT = TC_993_1653.port_a.T - TC_993_1653.port_b.T; TC_993_1653.port_a.Q_flow = TC_993_1653.Q_flow; TC_993_1653.port_b.Q_flow = -TC_993_1653.Q_flow; TC_994_995.Q_flow = TC_994_995.G * TC_994_995.dT; TC_994_995.dT = TC_994_995.port_a.T - TC_994_995.port_b.T; TC_994_995.port_a.Q_flow = TC_994_995.Q_flow; TC_994_995.port_b.Q_flow = -TC_994_995.Q_flow; TC_994_1002.Q_flow = TC_994_1002.G * TC_994_1002.dT; TC_994_1002.dT = TC_994_1002.port_a.T - TC_994_1002.port_b.T; TC_994_1002.port_a.Q_flow = TC_994_1002.Q_flow; TC_994_1002.port_b.Q_flow = -TC_994_1002.Q_flow; TC_994_1542.Q_flow = TC_994_1542.G * TC_994_1542.dT; TC_994_1542.dT = TC_994_1542.port_a.T - TC_994_1542.port_b.T; TC_994_1542.port_a.Q_flow = TC_994_1542.Q_flow; TC_994_1542.port_b.Q_flow = -TC_994_1542.Q_flow; TC_994_1654.Q_flow = TC_994_1654.G * TC_994_1654.dT; TC_994_1654.dT = TC_994_1654.port_a.T - TC_994_1654.port_b.T; TC_994_1654.port_a.Q_flow = TC_994_1654.Q_flow; TC_994_1654.port_b.Q_flow = -TC_994_1654.Q_flow; TC_995_996.Q_flow = TC_995_996.G * TC_995_996.dT; TC_995_996.dT = TC_995_996.port_a.T - TC_995_996.port_b.T; TC_995_996.port_a.Q_flow = TC_995_996.Q_flow; TC_995_996.port_b.Q_flow = -TC_995_996.Q_flow; TC_995_1003.Q_flow = TC_995_1003.G * TC_995_1003.dT; TC_995_1003.dT = TC_995_1003.port_a.T - TC_995_1003.port_b.T; TC_995_1003.port_a.Q_flow = TC_995_1003.Q_flow; TC_995_1003.port_b.Q_flow = -TC_995_1003.Q_flow; TC_995_1543.Q_flow = TC_995_1543.G * TC_995_1543.dT; TC_995_1543.dT = TC_995_1543.port_a.T - TC_995_1543.port_b.T; TC_995_1543.port_a.Q_flow = TC_995_1543.Q_flow; TC_995_1543.port_b.Q_flow = -TC_995_1543.Q_flow; TC_995_1655.Q_flow = TC_995_1655.G * TC_995_1655.dT; TC_995_1655.dT = TC_995_1655.port_a.T - TC_995_1655.port_b.T; TC_995_1655.port_a.Q_flow = TC_995_1655.Q_flow; TC_995_1655.port_b.Q_flow = -TC_995_1655.Q_flow; TC_996_997.Q_flow = TC_996_997.G * TC_996_997.dT; TC_996_997.dT = TC_996_997.port_a.T - TC_996_997.port_b.T; TC_996_997.port_a.Q_flow = TC_996_997.Q_flow; TC_996_997.port_b.Q_flow = -TC_996_997.Q_flow; TC_996_1004.Q_flow = TC_996_1004.G * TC_996_1004.dT; TC_996_1004.dT = TC_996_1004.port_a.T - TC_996_1004.port_b.T; TC_996_1004.port_a.Q_flow = TC_996_1004.Q_flow; TC_996_1004.port_b.Q_flow = -TC_996_1004.Q_flow; TC_996_1544.Q_flow = TC_996_1544.G * TC_996_1544.dT; TC_996_1544.dT = TC_996_1544.port_a.T - TC_996_1544.port_b.T; TC_996_1544.port_a.Q_flow = TC_996_1544.Q_flow; TC_996_1544.port_b.Q_flow = -TC_996_1544.Q_flow; TC_997_1005.Q_flow = TC_997_1005.G * TC_997_1005.dT; TC_997_1005.dT = TC_997_1005.port_a.T - TC_997_1005.port_b.T; TC_997_1005.port_a.Q_flow = TC_997_1005.Q_flow; TC_997_1005.port_b.Q_flow = -TC_997_1005.Q_flow; TC_997_1129.Q_flow = TC_997_1129.G * TC_997_1129.dT; TC_997_1129.dT = TC_997_1129.port_a.T - TC_997_1129.port_b.T; TC_997_1129.port_a.Q_flow = TC_997_1129.Q_flow; TC_997_1129.port_b.Q_flow = -TC_997_1129.Q_flow; TC_998_999.Q_flow = TC_998_999.G * TC_998_999.dT; TC_998_999.dT = TC_998_999.port_a.T - TC_998_999.port_b.T; TC_998_999.port_a.Q_flow = TC_998_999.Q_flow; TC_998_999.port_b.Q_flow = -TC_998_999.Q_flow; TC_998_1006.Q_flow = TC_998_1006.G * TC_998_1006.dT; TC_998_1006.dT = TC_998_1006.port_a.T - TC_998_1006.port_b.T; TC_998_1006.port_a.Q_flow = TC_998_1006.Q_flow; TC_998_1006.port_b.Q_flow = -TC_998_1006.Q_flow; TC_998_1130.Q_flow = TC_998_1130.G * TC_998_1130.dT; TC_998_1130.dT = TC_998_1130.port_a.T - TC_998_1130.port_b.T; TC_998_1130.port_a.Q_flow = TC_998_1130.Q_flow; TC_998_1130.port_b.Q_flow = -TC_998_1130.Q_flow; TC_999_1007.Q_flow = TC_999_1007.G * TC_999_1007.dT; TC_999_1007.dT = TC_999_1007.port_a.T - TC_999_1007.port_b.T; TC_999_1007.port_a.Q_flow = TC_999_1007.Q_flow; TC_999_1007.port_b.Q_flow = -TC_999_1007.Q_flow; TC_999_1545.Q_flow = TC_999_1545.G * TC_999_1545.dT; TC_999_1545.dT = TC_999_1545.port_a.T - TC_999_1545.port_b.T; TC_999_1545.port_a.Q_flow = TC_999_1545.Q_flow; TC_999_1545.port_b.Q_flow = -TC_999_1545.Q_flow; TC_999_1662.Q_flow = TC_999_1662.G * TC_999_1662.dT; TC_999_1662.dT = TC_999_1662.port_a.T - TC_999_1662.port_b.T; TC_999_1662.port_a.Q_flow = TC_999_1662.Q_flow; TC_999_1662.port_b.Q_flow = -TC_999_1662.Q_flow; TC_1000_1001.Q_flow = TC_1000_1001.G * TC_1000_1001.dT; TC_1000_1001.dT = TC_1000_1001.port_a.T - TC_1000_1001.port_b.T; TC_1000_1001.port_a.Q_flow = TC_1000_1001.Q_flow; TC_1000_1001.port_b.Q_flow = -TC_1000_1001.Q_flow; TC_1000_1011.Q_flow = TC_1000_1011.G * TC_1000_1011.dT; TC_1000_1011.dT = TC_1000_1011.port_a.T - TC_1000_1011.port_b.T; TC_1000_1011.port_a.Q_flow = TC_1000_1011.Q_flow; TC_1000_1011.port_b.Q_flow = -TC_1000_1011.Q_flow; TC_1000_1549.Q_flow = TC_1000_1549.G * TC_1000_1549.dT; TC_1000_1549.dT = TC_1000_1549.port_a.T - TC_1000_1549.port_b.T; TC_1000_1549.port_a.Q_flow = TC_1000_1549.Q_flow; TC_1000_1549.port_b.Q_flow = -TC_1000_1549.Q_flow; TC_1000_1664.Q_flow = TC_1000_1664.G * TC_1000_1664.dT; TC_1000_1664.dT = TC_1000_1664.port_a.T - TC_1000_1664.port_b.T; TC_1000_1664.port_a.Q_flow = TC_1000_1664.Q_flow; TC_1000_1664.port_b.Q_flow = -TC_1000_1664.Q_flow; TC_1001_1002.Q_flow = TC_1001_1002.G * TC_1001_1002.dT; TC_1001_1002.dT = TC_1001_1002.port_a.T - TC_1001_1002.port_b.T; TC_1001_1002.port_a.Q_flow = TC_1001_1002.Q_flow; TC_1001_1002.port_b.Q_flow = -TC_1001_1002.Q_flow; TC_1001_1012.Q_flow = TC_1001_1012.G * TC_1001_1012.dT; TC_1001_1012.dT = TC_1001_1012.port_a.T - TC_1001_1012.port_b.T; TC_1001_1012.port_a.Q_flow = TC_1001_1012.Q_flow; TC_1001_1012.port_b.Q_flow = -TC_1001_1012.Q_flow; TC_1001_1550.Q_flow = TC_1001_1550.G * TC_1001_1550.dT; TC_1001_1550.dT = TC_1001_1550.port_a.T - TC_1001_1550.port_b.T; TC_1001_1550.port_a.Q_flow = TC_1001_1550.Q_flow; TC_1001_1550.port_b.Q_flow = -TC_1001_1550.Q_flow; TC_1002_1003.Q_flow = TC_1002_1003.G * TC_1002_1003.dT; TC_1002_1003.dT = TC_1002_1003.port_a.T - TC_1002_1003.port_b.T; TC_1002_1003.port_a.Q_flow = TC_1002_1003.Q_flow; TC_1002_1003.port_b.Q_flow = -TC_1002_1003.Q_flow; TC_1002_1013.Q_flow = TC_1002_1013.G * TC_1002_1013.dT; TC_1002_1013.dT = TC_1002_1013.port_a.T - TC_1002_1013.port_b.T; TC_1002_1013.port_a.Q_flow = TC_1002_1013.Q_flow; TC_1002_1013.port_b.Q_flow = -TC_1002_1013.Q_flow; TC_1002_1551.Q_flow = TC_1002_1551.G * TC_1002_1551.dT; TC_1002_1551.dT = TC_1002_1551.port_a.T - TC_1002_1551.port_b.T; TC_1002_1551.port_a.Q_flow = TC_1002_1551.Q_flow; TC_1002_1551.port_b.Q_flow = -TC_1002_1551.Q_flow; TC_1003_1004.Q_flow = TC_1003_1004.G * TC_1003_1004.dT; TC_1003_1004.dT = TC_1003_1004.port_a.T - TC_1003_1004.port_b.T; TC_1003_1004.port_a.Q_flow = TC_1003_1004.Q_flow; TC_1003_1004.port_b.Q_flow = -TC_1003_1004.Q_flow; TC_1003_1014.Q_flow = TC_1003_1014.G * TC_1003_1014.dT; TC_1003_1014.dT = TC_1003_1014.port_a.T - TC_1003_1014.port_b.T; TC_1003_1014.port_a.Q_flow = TC_1003_1014.Q_flow; TC_1003_1014.port_b.Q_flow = -TC_1003_1014.Q_flow; TC_1003_1552.Q_flow = TC_1003_1552.G * TC_1003_1552.dT; TC_1003_1552.dT = TC_1003_1552.port_a.T - TC_1003_1552.port_b.T; TC_1003_1552.port_a.Q_flow = TC_1003_1552.Q_flow; TC_1003_1552.port_b.Q_flow = -TC_1003_1552.Q_flow; TC_1004_1005.Q_flow = TC_1004_1005.G * TC_1004_1005.dT; TC_1004_1005.dT = TC_1004_1005.port_a.T - TC_1004_1005.port_b.T; TC_1004_1005.port_a.Q_flow = TC_1004_1005.Q_flow; TC_1004_1005.port_b.Q_flow = -TC_1004_1005.Q_flow; TC_1004_1015.Q_flow = TC_1004_1015.G * TC_1004_1015.dT; TC_1004_1015.dT = TC_1004_1015.port_a.T - TC_1004_1015.port_b.T; TC_1004_1015.port_a.Q_flow = TC_1004_1015.Q_flow; TC_1004_1015.port_b.Q_flow = -TC_1004_1015.Q_flow; TC_1004_1553.Q_flow = TC_1004_1553.G * TC_1004_1553.dT; TC_1004_1553.dT = TC_1004_1553.port_a.T - TC_1004_1553.port_b.T; TC_1004_1553.port_a.Q_flow = TC_1004_1553.Q_flow; TC_1004_1553.port_b.Q_flow = -TC_1004_1553.Q_flow; TC_1005_1016.Q_flow = TC_1005_1016.G * TC_1005_1016.dT; TC_1005_1016.dT = TC_1005_1016.port_a.T - TC_1005_1016.port_b.T; TC_1005_1016.port_a.Q_flow = TC_1005_1016.Q_flow; TC_1005_1016.port_b.Q_flow = -TC_1005_1016.Q_flow; TC_1005_1131.Q_flow = TC_1005_1131.G * TC_1005_1131.dT; TC_1005_1131.dT = TC_1005_1131.port_a.T - TC_1005_1131.port_b.T; TC_1005_1131.port_a.Q_flow = TC_1005_1131.Q_flow; TC_1005_1131.port_b.Q_flow = -TC_1005_1131.Q_flow; TC_1006_1007.Q_flow = TC_1006_1007.G * TC_1006_1007.dT; TC_1006_1007.dT = TC_1006_1007.port_a.T - TC_1006_1007.port_b.T; TC_1006_1007.port_a.Q_flow = TC_1006_1007.Q_flow; TC_1006_1007.port_b.Q_flow = -TC_1006_1007.Q_flow; TC_1006_1017.Q_flow = TC_1006_1017.G * TC_1006_1017.dT; TC_1006_1017.dT = TC_1006_1017.port_a.T - TC_1006_1017.port_b.T; TC_1006_1017.port_a.Q_flow = TC_1006_1017.Q_flow; TC_1006_1017.port_b.Q_flow = -TC_1006_1017.Q_flow; TC_1006_1132.Q_flow = TC_1006_1132.G * TC_1006_1132.dT; TC_1006_1132.dT = TC_1006_1132.port_a.T - TC_1006_1132.port_b.T; TC_1006_1132.port_a.Q_flow = TC_1006_1132.Q_flow; TC_1006_1132.port_b.Q_flow = -TC_1006_1132.Q_flow; TC_1007_1008.Q_flow = TC_1007_1008.G * TC_1007_1008.dT; TC_1007_1008.dT = TC_1007_1008.port_a.T - TC_1007_1008.port_b.T; TC_1007_1008.port_a.Q_flow = TC_1007_1008.Q_flow; TC_1007_1008.port_b.Q_flow = -TC_1007_1008.Q_flow; TC_1007_1018.Q_flow = TC_1007_1018.G * TC_1007_1018.dT; TC_1007_1018.dT = TC_1007_1018.port_a.T - TC_1007_1018.port_b.T; TC_1007_1018.port_a.Q_flow = TC_1007_1018.Q_flow; TC_1007_1018.port_b.Q_flow = -TC_1007_1018.Q_flow; TC_1007_1554.Q_flow = TC_1007_1554.G * TC_1007_1554.dT; TC_1007_1554.dT = TC_1007_1554.port_a.T - TC_1007_1554.port_b.T; TC_1007_1554.port_a.Q_flow = TC_1007_1554.Q_flow; TC_1007_1554.port_b.Q_flow = -TC_1007_1554.Q_flow; TC_1008_1009.Q_flow = TC_1008_1009.G * TC_1008_1009.dT; TC_1008_1009.dT = TC_1008_1009.port_a.T - TC_1008_1009.port_b.T; TC_1008_1009.port_a.Q_flow = TC_1008_1009.Q_flow; TC_1008_1009.port_b.Q_flow = -TC_1008_1009.Q_flow; TC_1008_1019.Q_flow = TC_1008_1019.G * TC_1008_1019.dT; TC_1008_1019.dT = TC_1008_1019.port_a.T - TC_1008_1019.port_b.T; TC_1008_1019.port_a.Q_flow = TC_1008_1019.Q_flow; TC_1008_1019.port_b.Q_flow = -TC_1008_1019.Q_flow; TC_1008_1555.Q_flow = TC_1008_1555.G * TC_1008_1555.dT; TC_1008_1555.dT = TC_1008_1555.port_a.T - TC_1008_1555.port_b.T; TC_1008_1555.port_a.Q_flow = TC_1008_1555.Q_flow; TC_1008_1555.port_b.Q_flow = -TC_1008_1555.Q_flow; TC_1008_1662.Q_flow = TC_1008_1662.G * TC_1008_1662.dT; TC_1008_1662.dT = TC_1008_1662.port_a.T - TC_1008_1662.port_b.T; TC_1008_1662.port_a.Q_flow = TC_1008_1662.Q_flow; TC_1008_1662.port_b.Q_flow = -TC_1008_1662.Q_flow; TC_1009_1010.Q_flow = TC_1009_1010.G * TC_1009_1010.dT; TC_1009_1010.dT = TC_1009_1010.port_a.T - TC_1009_1010.port_b.T; TC_1009_1010.port_a.Q_flow = TC_1009_1010.Q_flow; TC_1009_1010.port_b.Q_flow = -TC_1009_1010.Q_flow; TC_1009_1020.Q_flow = TC_1009_1020.G * TC_1009_1020.dT; TC_1009_1020.dT = TC_1009_1020.port_a.T - TC_1009_1020.port_b.T; TC_1009_1020.port_a.Q_flow = TC_1009_1020.Q_flow; TC_1009_1020.port_b.Q_flow = -TC_1009_1020.Q_flow; TC_1009_1556.Q_flow = TC_1009_1556.G * TC_1009_1556.dT; TC_1009_1556.dT = TC_1009_1556.port_a.T - TC_1009_1556.port_b.T; TC_1009_1556.port_a.Q_flow = TC_1009_1556.Q_flow; TC_1009_1556.port_b.Q_flow = -TC_1009_1556.Q_flow; TC_1009_1663.Q_flow = TC_1009_1663.G * TC_1009_1663.dT; TC_1009_1663.dT = TC_1009_1663.port_a.T - TC_1009_1663.port_b.T; TC_1009_1663.port_a.Q_flow = TC_1009_1663.Q_flow; TC_1009_1663.port_b.Q_flow = -TC_1009_1663.Q_flow; TC_1010_1011.Q_flow = TC_1010_1011.G * TC_1010_1011.dT; TC_1010_1011.dT = TC_1010_1011.port_a.T - TC_1010_1011.port_b.T; TC_1010_1011.port_a.Q_flow = TC_1010_1011.Q_flow; TC_1010_1011.port_b.Q_flow = -TC_1010_1011.Q_flow; TC_1010_1021.Q_flow = TC_1010_1021.G * TC_1010_1021.dT; TC_1010_1021.dT = TC_1010_1021.port_a.T - TC_1010_1021.port_b.T; TC_1010_1021.port_a.Q_flow = TC_1010_1021.Q_flow; TC_1010_1021.port_b.Q_flow = -TC_1010_1021.Q_flow; TC_1010_1557.Q_flow = TC_1010_1557.G * TC_1010_1557.dT; TC_1010_1557.dT = TC_1010_1557.port_a.T - TC_1010_1557.port_b.T; TC_1010_1557.port_a.Q_flow = TC_1010_1557.Q_flow; TC_1010_1557.port_b.Q_flow = -TC_1010_1557.Q_flow; TC_1010_1664.Q_flow = TC_1010_1664.G * TC_1010_1664.dT; TC_1010_1664.dT = TC_1010_1664.port_a.T - TC_1010_1664.port_b.T; TC_1010_1664.port_a.Q_flow = TC_1010_1664.Q_flow; TC_1010_1664.port_b.Q_flow = -TC_1010_1664.Q_flow; TC_1011_1012.Q_flow = TC_1011_1012.G * TC_1011_1012.dT; TC_1011_1012.dT = TC_1011_1012.port_a.T - TC_1011_1012.port_b.T; TC_1011_1012.port_a.Q_flow = TC_1011_1012.Q_flow; TC_1011_1012.port_b.Q_flow = -TC_1011_1012.Q_flow; TC_1011_1022.Q_flow = TC_1011_1022.G * TC_1011_1022.dT; TC_1011_1022.dT = TC_1011_1022.port_a.T - TC_1011_1022.port_b.T; TC_1011_1022.port_a.Q_flow = TC_1011_1022.Q_flow; TC_1011_1022.port_b.Q_flow = -TC_1011_1022.Q_flow; TC_1011_1558.Q_flow = TC_1011_1558.G * TC_1011_1558.dT; TC_1011_1558.dT = TC_1011_1558.port_a.T - TC_1011_1558.port_b.T; TC_1011_1558.port_a.Q_flow = TC_1011_1558.Q_flow; TC_1011_1558.port_b.Q_flow = -TC_1011_1558.Q_flow; TC_1012_1013.Q_flow = TC_1012_1013.G * TC_1012_1013.dT; TC_1012_1013.dT = TC_1012_1013.port_a.T - TC_1012_1013.port_b.T; TC_1012_1013.port_a.Q_flow = TC_1012_1013.Q_flow; TC_1012_1013.port_b.Q_flow = -TC_1012_1013.Q_flow; TC_1012_1023.Q_flow = TC_1012_1023.G * TC_1012_1023.dT; TC_1012_1023.dT = TC_1012_1023.port_a.T - TC_1012_1023.port_b.T; TC_1012_1023.port_a.Q_flow = TC_1012_1023.Q_flow; TC_1012_1023.port_b.Q_flow = -TC_1012_1023.Q_flow; TC_1012_1559.Q_flow = TC_1012_1559.G * TC_1012_1559.dT; TC_1012_1559.dT = TC_1012_1559.port_a.T - TC_1012_1559.port_b.T; TC_1012_1559.port_a.Q_flow = TC_1012_1559.Q_flow; TC_1012_1559.port_b.Q_flow = -TC_1012_1559.Q_flow; TC_1013_1014.Q_flow = TC_1013_1014.G * TC_1013_1014.dT; TC_1013_1014.dT = TC_1013_1014.port_a.T - TC_1013_1014.port_b.T; TC_1013_1014.port_a.Q_flow = TC_1013_1014.Q_flow; TC_1013_1014.port_b.Q_flow = -TC_1013_1014.Q_flow; TC_1013_1024.Q_flow = TC_1013_1024.G * TC_1013_1024.dT; TC_1013_1024.dT = TC_1013_1024.port_a.T - TC_1013_1024.port_b.T; TC_1013_1024.port_a.Q_flow = TC_1013_1024.Q_flow; TC_1013_1024.port_b.Q_flow = -TC_1013_1024.Q_flow; TC_1013_1560.Q_flow = TC_1013_1560.G * TC_1013_1560.dT; TC_1013_1560.dT = TC_1013_1560.port_a.T - TC_1013_1560.port_b.T; TC_1013_1560.port_a.Q_flow = TC_1013_1560.Q_flow; TC_1013_1560.port_b.Q_flow = -TC_1013_1560.Q_flow; TC_1014_1015.Q_flow = TC_1014_1015.G * TC_1014_1015.dT; TC_1014_1015.dT = TC_1014_1015.port_a.T - TC_1014_1015.port_b.T; TC_1014_1015.port_a.Q_flow = TC_1014_1015.Q_flow; TC_1014_1015.port_b.Q_flow = -TC_1014_1015.Q_flow; TC_1014_1025.Q_flow = TC_1014_1025.G * TC_1014_1025.dT; TC_1014_1025.dT = TC_1014_1025.port_a.T - TC_1014_1025.port_b.T; TC_1014_1025.port_a.Q_flow = TC_1014_1025.Q_flow; TC_1014_1025.port_b.Q_flow = -TC_1014_1025.Q_flow; TC_1014_1561.Q_flow = TC_1014_1561.G * TC_1014_1561.dT; TC_1014_1561.dT = TC_1014_1561.port_a.T - TC_1014_1561.port_b.T; TC_1014_1561.port_a.Q_flow = TC_1014_1561.Q_flow; TC_1014_1561.port_b.Q_flow = -TC_1014_1561.Q_flow; TC_1015_1016.Q_flow = TC_1015_1016.G * TC_1015_1016.dT; TC_1015_1016.dT = TC_1015_1016.port_a.T - TC_1015_1016.port_b.T; TC_1015_1016.port_a.Q_flow = TC_1015_1016.Q_flow; TC_1015_1016.port_b.Q_flow = -TC_1015_1016.Q_flow; TC_1015_1026.Q_flow = TC_1015_1026.G * TC_1015_1026.dT; TC_1015_1026.dT = TC_1015_1026.port_a.T - TC_1015_1026.port_b.T; TC_1015_1026.port_a.Q_flow = TC_1015_1026.Q_flow; TC_1015_1026.port_b.Q_flow = -TC_1015_1026.Q_flow; TC_1015_1562.Q_flow = TC_1015_1562.G * TC_1015_1562.dT; TC_1015_1562.dT = TC_1015_1562.port_a.T - TC_1015_1562.port_b.T; TC_1015_1562.port_a.Q_flow = TC_1015_1562.Q_flow; TC_1015_1562.port_b.Q_flow = -TC_1015_1562.Q_flow; TC_1016_1027.Q_flow = TC_1016_1027.G * TC_1016_1027.dT; TC_1016_1027.dT = TC_1016_1027.port_a.T - TC_1016_1027.port_b.T; TC_1016_1027.port_a.Q_flow = TC_1016_1027.Q_flow; TC_1016_1027.port_b.Q_flow = -TC_1016_1027.Q_flow; TC_1016_1133.Q_flow = TC_1016_1133.G * TC_1016_1133.dT; TC_1016_1133.dT = TC_1016_1133.port_a.T - TC_1016_1133.port_b.T; TC_1016_1133.port_a.Q_flow = TC_1016_1133.Q_flow; TC_1016_1133.port_b.Q_flow = -TC_1016_1133.Q_flow; TC_1017_1018.Q_flow = TC_1017_1018.G * TC_1017_1018.dT; TC_1017_1018.dT = TC_1017_1018.port_a.T - TC_1017_1018.port_b.T; TC_1017_1018.port_a.Q_flow = TC_1017_1018.Q_flow; TC_1017_1018.port_b.Q_flow = -TC_1017_1018.Q_flow; TC_1017_1134.Q_flow = TC_1017_1134.G * TC_1017_1134.dT; TC_1017_1134.dT = TC_1017_1134.port_a.T - TC_1017_1134.port_b.T; TC_1017_1134.port_a.Q_flow = TC_1017_1134.Q_flow; TC_1017_1134.port_b.Q_flow = -TC_1017_1134.Q_flow; TC_1018_1019.Q_flow = TC_1018_1019.G * TC_1018_1019.dT; TC_1018_1019.dT = TC_1018_1019.port_a.T - TC_1018_1019.port_b.T; TC_1018_1019.port_a.Q_flow = TC_1018_1019.Q_flow; TC_1018_1019.port_b.Q_flow = -TC_1018_1019.Q_flow; TC_1018_1135.Q_flow = TC_1018_1135.G * TC_1018_1135.dT; TC_1018_1135.dT = TC_1018_1135.port_a.T - TC_1018_1135.port_b.T; TC_1018_1135.port_a.Q_flow = TC_1018_1135.Q_flow; TC_1018_1135.port_b.Q_flow = -TC_1018_1135.Q_flow; TC_1019_1020.Q_flow = TC_1019_1020.G * TC_1019_1020.dT; TC_1019_1020.dT = TC_1019_1020.port_a.T - TC_1019_1020.port_b.T; TC_1019_1020.port_a.Q_flow = TC_1019_1020.Q_flow; TC_1019_1020.port_b.Q_flow = -TC_1019_1020.Q_flow; TC_1019_1136.Q_flow = TC_1019_1136.G * TC_1019_1136.dT; TC_1019_1136.dT = TC_1019_1136.port_a.T - TC_1019_1136.port_b.T; TC_1019_1136.port_a.Q_flow = TC_1019_1136.Q_flow; TC_1019_1136.port_b.Q_flow = -TC_1019_1136.Q_flow; TC_1020_1021.Q_flow = TC_1020_1021.G * TC_1020_1021.dT; TC_1020_1021.dT = TC_1020_1021.port_a.T - TC_1020_1021.port_b.T; TC_1020_1021.port_a.Q_flow = TC_1020_1021.Q_flow; TC_1020_1021.port_b.Q_flow = -TC_1020_1021.Q_flow; TC_1020_1137.Q_flow = TC_1020_1137.G * TC_1020_1137.dT; TC_1020_1137.dT = TC_1020_1137.port_a.T - TC_1020_1137.port_b.T; TC_1020_1137.port_a.Q_flow = TC_1020_1137.Q_flow; TC_1020_1137.port_b.Q_flow = -TC_1020_1137.Q_flow; TC_1021_1022.Q_flow = TC_1021_1022.G * TC_1021_1022.dT; TC_1021_1022.dT = TC_1021_1022.port_a.T - TC_1021_1022.port_b.T; TC_1021_1022.port_a.Q_flow = TC_1021_1022.Q_flow; TC_1021_1022.port_b.Q_flow = -TC_1021_1022.Q_flow; TC_1021_1138.Q_flow = TC_1021_1138.G * TC_1021_1138.dT; TC_1021_1138.dT = TC_1021_1138.port_a.T - TC_1021_1138.port_b.T; TC_1021_1138.port_a.Q_flow = TC_1021_1138.Q_flow; TC_1021_1138.port_b.Q_flow = -TC_1021_1138.Q_flow; TC_1022_1023.Q_flow = TC_1022_1023.G * TC_1022_1023.dT; TC_1022_1023.dT = TC_1022_1023.port_a.T - TC_1022_1023.port_b.T; TC_1022_1023.port_a.Q_flow = TC_1022_1023.Q_flow; TC_1022_1023.port_b.Q_flow = -TC_1022_1023.Q_flow; TC_1022_1139.Q_flow = TC_1022_1139.G * TC_1022_1139.dT; TC_1022_1139.dT = TC_1022_1139.port_a.T - TC_1022_1139.port_b.T; TC_1022_1139.port_a.Q_flow = TC_1022_1139.Q_flow; TC_1022_1139.port_b.Q_flow = -TC_1022_1139.Q_flow; TC_1023_1024.Q_flow = TC_1023_1024.G * TC_1023_1024.dT; TC_1023_1024.dT = TC_1023_1024.port_a.T - TC_1023_1024.port_b.T; TC_1023_1024.port_a.Q_flow = TC_1023_1024.Q_flow; TC_1023_1024.port_b.Q_flow = -TC_1023_1024.Q_flow; TC_1023_1140.Q_flow = TC_1023_1140.G * TC_1023_1140.dT; TC_1023_1140.dT = TC_1023_1140.port_a.T - TC_1023_1140.port_b.T; TC_1023_1140.port_a.Q_flow = TC_1023_1140.Q_flow; TC_1023_1140.port_b.Q_flow = -TC_1023_1140.Q_flow; TC_1024_1025.Q_flow = TC_1024_1025.G * TC_1024_1025.dT; TC_1024_1025.dT = TC_1024_1025.port_a.T - TC_1024_1025.port_b.T; TC_1024_1025.port_a.Q_flow = TC_1024_1025.Q_flow; TC_1024_1025.port_b.Q_flow = -TC_1024_1025.Q_flow; TC_1024_1141.Q_flow = TC_1024_1141.G * TC_1024_1141.dT; TC_1024_1141.dT = TC_1024_1141.port_a.T - TC_1024_1141.port_b.T; TC_1024_1141.port_a.Q_flow = TC_1024_1141.Q_flow; TC_1024_1141.port_b.Q_flow = -TC_1024_1141.Q_flow; TC_1025_1026.Q_flow = TC_1025_1026.G * TC_1025_1026.dT; TC_1025_1026.dT = TC_1025_1026.port_a.T - TC_1025_1026.port_b.T; TC_1025_1026.port_a.Q_flow = TC_1025_1026.Q_flow; TC_1025_1026.port_b.Q_flow = -TC_1025_1026.Q_flow; TC_1025_1142.Q_flow = TC_1025_1142.G * TC_1025_1142.dT; TC_1025_1142.dT = TC_1025_1142.port_a.T - TC_1025_1142.port_b.T; TC_1025_1142.port_a.Q_flow = TC_1025_1142.Q_flow; TC_1025_1142.port_b.Q_flow = -TC_1025_1142.Q_flow; TC_1026_1027.Q_flow = TC_1026_1027.G * TC_1026_1027.dT; TC_1026_1027.dT = TC_1026_1027.port_a.T - TC_1026_1027.port_b.T; TC_1026_1027.port_a.Q_flow = TC_1026_1027.Q_flow; TC_1026_1027.port_b.Q_flow = -TC_1026_1027.Q_flow; TC_1026_1143.Q_flow = TC_1026_1143.G * TC_1026_1143.dT; TC_1026_1143.dT = TC_1026_1143.port_a.T - TC_1026_1143.port_b.T; TC_1026_1143.port_a.Q_flow = TC_1026_1143.Q_flow; TC_1026_1143.port_b.Q_flow = -TC_1026_1143.Q_flow; TC_1027_1144.Q_flow = TC_1027_1144.G * TC_1027_1144.dT; TC_1027_1144.dT = TC_1027_1144.port_a.T - TC_1027_1144.port_b.T; TC_1027_1144.port_a.Q_flow = TC_1027_1144.Q_flow; TC_1027_1144.port_b.Q_flow = -TC_1027_1144.Q_flow; TC_1028_1029.Q_flow = TC_1028_1029.G * TC_1028_1029.dT; TC_1028_1029.dT = TC_1028_1029.port_a.T - TC_1028_1029.port_b.T; TC_1028_1029.port_a.Q_flow = TC_1028_1029.Q_flow; TC_1028_1029.port_b.Q_flow = -TC_1028_1029.Q_flow; TC_1028_1035.Q_flow = TC_1028_1035.G * TC_1028_1035.dT; TC_1028_1035.dT = TC_1028_1035.port_a.T - TC_1028_1035.port_b.T; TC_1028_1035.port_a.Q_flow = TC_1028_1035.Q_flow; TC_1028_1035.port_b.Q_flow = -TC_1028_1035.Q_flow; TC_1028_1092.Q_flow = TC_1028_1092.G * TC_1028_1092.dT; TC_1028_1092.dT = TC_1028_1092.port_a.T - TC_1028_1092.port_b.T; TC_1028_1092.port_a.Q_flow = TC_1028_1092.Q_flow; TC_1028_1092.port_b.Q_flow = -TC_1028_1092.Q_flow; TC_1028_1633.Q_flow = TC_1028_1633.G * TC_1028_1633.dT; TC_1028_1633.dT = TC_1028_1633.port_a.T - TC_1028_1633.port_b.T; TC_1028_1633.port_a.Q_flow = TC_1028_1633.Q_flow; TC_1028_1633.port_b.Q_flow = -TC_1028_1633.Q_flow; TC_1028_1642.Q_flow = TC_1028_1642.G * TC_1028_1642.dT; TC_1028_1642.dT = TC_1028_1642.port_a.T - TC_1028_1642.port_b.T; TC_1028_1642.port_a.Q_flow = TC_1028_1642.Q_flow; TC_1028_1642.port_b.Q_flow = -TC_1028_1642.Q_flow; TC_1029_1030.Q_flow = TC_1029_1030.G * TC_1029_1030.dT; TC_1029_1030.dT = TC_1029_1030.port_a.T - TC_1029_1030.port_b.T; TC_1029_1030.port_a.Q_flow = TC_1029_1030.Q_flow; TC_1029_1030.port_b.Q_flow = -TC_1029_1030.Q_flow; TC_1029_1036.Q_flow = TC_1029_1036.G * TC_1029_1036.dT; TC_1029_1036.dT = TC_1029_1036.port_a.T - TC_1029_1036.port_b.T; TC_1029_1036.port_a.Q_flow = TC_1029_1036.Q_flow; TC_1029_1036.port_b.Q_flow = -TC_1029_1036.Q_flow; TC_1029_1093.Q_flow = TC_1029_1093.G * TC_1029_1093.dT; TC_1029_1093.dT = TC_1029_1093.port_a.T - TC_1029_1093.port_b.T; TC_1029_1093.port_a.Q_flow = TC_1029_1093.Q_flow; TC_1029_1093.port_b.Q_flow = -TC_1029_1093.Q_flow; TC_1029_1634.Q_flow = TC_1029_1634.G * TC_1029_1634.dT; TC_1029_1634.dT = TC_1029_1634.port_a.T - TC_1029_1634.port_b.T; TC_1029_1634.port_a.Q_flow = TC_1029_1634.Q_flow; TC_1029_1634.port_b.Q_flow = -TC_1029_1634.Q_flow; TC_1030_1037.Q_flow = TC_1030_1037.G * TC_1030_1037.dT; TC_1030_1037.dT = TC_1030_1037.port_a.T - TC_1030_1037.port_b.T; TC_1030_1037.port_a.Q_flow = TC_1030_1037.Q_flow; TC_1030_1037.port_b.Q_flow = -TC_1030_1037.Q_flow; TC_1030_1094.Q_flow = TC_1030_1094.G * TC_1030_1094.dT; TC_1030_1094.dT = TC_1030_1094.port_a.T - TC_1030_1094.port_b.T; TC_1030_1094.port_a.Q_flow = TC_1030_1094.Q_flow; TC_1030_1094.port_b.Q_flow = -TC_1030_1094.Q_flow; TC_1030_1115.Q_flow = TC_1030_1115.G * TC_1030_1115.dT; TC_1030_1115.dT = TC_1030_1115.port_a.T - TC_1030_1115.port_b.T; TC_1030_1115.port_a.Q_flow = TC_1030_1115.Q_flow; TC_1030_1115.port_b.Q_flow = -TC_1030_1115.Q_flow; TC_1031_1032.Q_flow = TC_1031_1032.G * TC_1031_1032.dT; TC_1031_1032.dT = TC_1031_1032.port_a.T - TC_1031_1032.port_b.T; TC_1031_1032.port_a.Q_flow = TC_1031_1032.Q_flow; TC_1031_1032.port_b.Q_flow = -TC_1031_1032.Q_flow; TC_1031_1038.Q_flow = TC_1031_1038.G * TC_1031_1038.dT; TC_1031_1038.dT = TC_1031_1038.port_a.T - TC_1031_1038.port_b.T; TC_1031_1038.port_a.Q_flow = TC_1031_1038.Q_flow; TC_1031_1038.port_b.Q_flow = -TC_1031_1038.Q_flow; TC_1031_1095.Q_flow = TC_1031_1095.G * TC_1031_1095.dT; TC_1031_1095.dT = TC_1031_1095.port_a.T - TC_1031_1095.port_b.T; TC_1031_1095.port_a.Q_flow = TC_1031_1095.Q_flow; TC_1031_1095.port_b.Q_flow = -TC_1031_1095.Q_flow; TC_1031_1116.Q_flow = TC_1031_1116.G * TC_1031_1116.dT; TC_1031_1116.dT = TC_1031_1116.port_a.T - TC_1031_1116.port_b.T; TC_1031_1116.port_a.Q_flow = TC_1031_1116.Q_flow; TC_1031_1116.port_b.Q_flow = -TC_1031_1116.Q_flow; TC_1032_1033.Q_flow = TC_1032_1033.G * TC_1032_1033.dT; TC_1032_1033.dT = TC_1032_1033.port_a.T - TC_1032_1033.port_b.T; TC_1032_1033.port_a.Q_flow = TC_1032_1033.Q_flow; TC_1032_1033.port_b.Q_flow = -TC_1032_1033.Q_flow; TC_1032_1039.Q_flow = TC_1032_1039.G * TC_1032_1039.dT; TC_1032_1039.dT = TC_1032_1039.port_a.T - TC_1032_1039.port_b.T; TC_1032_1039.port_a.Q_flow = TC_1032_1039.Q_flow; TC_1032_1039.port_b.Q_flow = -TC_1032_1039.Q_flow; TC_1032_1096.Q_flow = TC_1032_1096.G * TC_1032_1096.dT; TC_1032_1096.dT = TC_1032_1096.port_a.T - TC_1032_1096.port_b.T; TC_1032_1096.port_a.Q_flow = TC_1032_1096.Q_flow; TC_1032_1096.port_b.Q_flow = -TC_1032_1096.Q_flow; TC_1032_1563.Q_flow = TC_1032_1563.G * TC_1032_1563.dT; TC_1032_1563.dT = TC_1032_1563.port_a.T - TC_1032_1563.port_b.T; TC_1032_1563.port_a.Q_flow = TC_1032_1563.Q_flow; TC_1032_1563.port_b.Q_flow = -TC_1032_1563.Q_flow; TC_1033_1034.Q_flow = TC_1033_1034.G * TC_1033_1034.dT; TC_1033_1034.dT = TC_1033_1034.port_a.T - TC_1033_1034.port_b.T; TC_1033_1034.port_a.Q_flow = TC_1033_1034.Q_flow; TC_1033_1034.port_b.Q_flow = -TC_1033_1034.Q_flow; TC_1033_1040.Q_flow = TC_1033_1040.G * TC_1033_1040.dT; TC_1033_1040.dT = TC_1033_1040.port_a.T - TC_1033_1040.port_b.T; TC_1033_1040.port_a.Q_flow = TC_1033_1040.Q_flow; TC_1033_1040.port_b.Q_flow = -TC_1033_1040.Q_flow; TC_1033_1097.Q_flow = TC_1033_1097.G * TC_1033_1097.dT; TC_1033_1097.dT = TC_1033_1097.port_a.T - TC_1033_1097.port_b.T; TC_1033_1097.port_a.Q_flow = TC_1033_1097.Q_flow; TC_1033_1097.port_b.Q_flow = -TC_1033_1097.Q_flow; TC_1033_1564.Q_flow = TC_1033_1564.G * TC_1033_1564.dT; TC_1033_1564.dT = TC_1033_1564.port_a.T - TC_1033_1564.port_b.T; TC_1033_1564.port_a.Q_flow = TC_1033_1564.Q_flow; TC_1033_1564.port_b.Q_flow = -TC_1033_1564.Q_flow; TC_1034_1041.Q_flow = TC_1034_1041.G * TC_1034_1041.dT; TC_1034_1041.dT = TC_1034_1041.port_a.T - TC_1034_1041.port_b.T; TC_1034_1041.port_a.Q_flow = TC_1034_1041.Q_flow; TC_1034_1041.port_b.Q_flow = -TC_1034_1041.Q_flow; TC_1034_1098.Q_flow = TC_1034_1098.G * TC_1034_1098.dT; TC_1034_1098.dT = TC_1034_1098.port_a.T - TC_1034_1098.port_b.T; TC_1034_1098.port_a.Q_flow = TC_1034_1098.Q_flow; TC_1034_1098.port_b.Q_flow = -TC_1034_1098.Q_flow; TC_1034_1565.Q_flow = TC_1034_1565.G * TC_1034_1565.dT; TC_1034_1565.dT = TC_1034_1565.port_a.T - TC_1034_1565.port_b.T; TC_1034_1565.port_a.Q_flow = TC_1034_1565.Q_flow; TC_1034_1565.port_b.Q_flow = -TC_1034_1565.Q_flow; TC_1034_1643.Q_flow = TC_1034_1643.G * TC_1034_1643.dT; TC_1034_1643.dT = TC_1034_1643.port_a.T - TC_1034_1643.port_b.T; TC_1034_1643.port_a.Q_flow = TC_1034_1643.Q_flow; TC_1034_1643.port_b.Q_flow = -TC_1034_1643.Q_flow; TC_1035_1036.Q_flow = TC_1035_1036.G * TC_1035_1036.dT; TC_1035_1036.dT = TC_1035_1036.port_a.T - TC_1035_1036.port_b.T; TC_1035_1036.port_a.Q_flow = TC_1035_1036.Q_flow; TC_1035_1036.port_b.Q_flow = -TC_1035_1036.Q_flow; TC_1035_1046.Q_flow = TC_1035_1046.G * TC_1035_1046.dT; TC_1035_1046.dT = TC_1035_1046.port_a.T - TC_1035_1046.port_b.T; TC_1035_1046.port_a.Q_flow = TC_1035_1046.Q_flow; TC_1035_1046.port_b.Q_flow = -TC_1035_1046.Q_flow; TC_1035_1570.Q_flow = TC_1035_1570.G * TC_1035_1570.dT; TC_1035_1570.dT = TC_1035_1570.port_a.T - TC_1035_1570.port_b.T; TC_1035_1570.port_a.Q_flow = TC_1035_1570.Q_flow; TC_1035_1570.port_b.Q_flow = -TC_1035_1570.Q_flow; TC_1035_1646.Q_flow = TC_1035_1646.G * TC_1035_1646.dT; TC_1035_1646.dT = TC_1035_1646.port_a.T - TC_1035_1646.port_b.T; TC_1035_1646.port_a.Q_flow = TC_1035_1646.Q_flow; TC_1035_1646.port_b.Q_flow = -TC_1035_1646.Q_flow; TC_1036_1037.Q_flow = TC_1036_1037.G * TC_1036_1037.dT; TC_1036_1037.dT = TC_1036_1037.port_a.T - TC_1036_1037.port_b.T; TC_1036_1037.port_a.Q_flow = TC_1036_1037.Q_flow; TC_1036_1037.port_b.Q_flow = -TC_1036_1037.Q_flow; TC_1036_1047.Q_flow = TC_1036_1047.G * TC_1036_1047.dT; TC_1036_1047.dT = TC_1036_1047.port_a.T - TC_1036_1047.port_b.T; TC_1036_1047.port_a.Q_flow = TC_1036_1047.Q_flow; TC_1036_1047.port_b.Q_flow = -TC_1036_1047.Q_flow; TC_1036_1571.Q_flow = TC_1036_1571.G * TC_1036_1571.dT; TC_1036_1571.dT = TC_1036_1571.port_a.T - TC_1036_1571.port_b.T; TC_1036_1571.port_a.Q_flow = TC_1036_1571.Q_flow; TC_1036_1571.port_b.Q_flow = -TC_1036_1571.Q_flow; TC_1037_1048.Q_flow = TC_1037_1048.G * TC_1037_1048.dT; TC_1037_1048.dT = TC_1037_1048.port_a.T - TC_1037_1048.port_b.T; TC_1037_1048.port_a.Q_flow = TC_1037_1048.Q_flow; TC_1037_1048.port_b.Q_flow = -TC_1037_1048.Q_flow; TC_1037_1117.Q_flow = TC_1037_1117.G * TC_1037_1117.dT; TC_1037_1117.dT = TC_1037_1117.port_a.T - TC_1037_1117.port_b.T; TC_1037_1117.port_a.Q_flow = TC_1037_1117.Q_flow; TC_1037_1117.port_b.Q_flow = -TC_1037_1117.Q_flow; TC_1038_1039.Q_flow = TC_1038_1039.G * TC_1038_1039.dT; TC_1038_1039.dT = TC_1038_1039.port_a.T - TC_1038_1039.port_b.T; TC_1038_1039.port_a.Q_flow = TC_1038_1039.Q_flow; TC_1038_1039.port_b.Q_flow = -TC_1038_1039.Q_flow; TC_1038_1049.Q_flow = TC_1038_1049.G * TC_1038_1049.dT; TC_1038_1049.dT = TC_1038_1049.port_a.T - TC_1038_1049.port_b.T; TC_1038_1049.port_a.Q_flow = TC_1038_1049.Q_flow; TC_1038_1049.port_b.Q_flow = -TC_1038_1049.Q_flow; TC_1038_1118.Q_flow = TC_1038_1118.G * TC_1038_1118.dT; TC_1038_1118.dT = TC_1038_1118.port_a.T - TC_1038_1118.port_b.T; TC_1038_1118.port_a.Q_flow = TC_1038_1118.Q_flow; TC_1038_1118.port_b.Q_flow = -TC_1038_1118.Q_flow; TC_1039_1040.Q_flow = TC_1039_1040.G * TC_1039_1040.dT; TC_1039_1040.dT = TC_1039_1040.port_a.T - TC_1039_1040.port_b.T; TC_1039_1040.port_a.Q_flow = TC_1039_1040.Q_flow; TC_1039_1040.port_b.Q_flow = -TC_1039_1040.Q_flow; TC_1039_1050.Q_flow = TC_1039_1050.G * TC_1039_1050.dT; TC_1039_1050.dT = TC_1039_1050.port_a.T - TC_1039_1050.port_b.T; TC_1039_1050.port_a.Q_flow = TC_1039_1050.Q_flow; TC_1039_1050.port_b.Q_flow = -TC_1039_1050.Q_flow; TC_1039_1572.Q_flow = TC_1039_1572.G * TC_1039_1572.dT; TC_1039_1572.dT = TC_1039_1572.port_a.T - TC_1039_1572.port_b.T; TC_1039_1572.port_a.Q_flow = TC_1039_1572.Q_flow; TC_1039_1572.port_b.Q_flow = -TC_1039_1572.Q_flow; TC_1040_1041.Q_flow = TC_1040_1041.G * TC_1040_1041.dT; TC_1040_1041.dT = TC_1040_1041.port_a.T - TC_1040_1041.port_b.T; TC_1040_1041.port_a.Q_flow = TC_1040_1041.Q_flow; TC_1040_1041.port_b.Q_flow = -TC_1040_1041.Q_flow; TC_1040_1051.Q_flow = TC_1040_1051.G * TC_1040_1051.dT; TC_1040_1051.dT = TC_1040_1051.port_a.T - TC_1040_1051.port_b.T; TC_1040_1051.port_a.Q_flow = TC_1040_1051.Q_flow; TC_1040_1051.port_b.Q_flow = -TC_1040_1051.Q_flow; TC_1040_1573.Q_flow = TC_1040_1573.G * TC_1040_1573.dT; TC_1040_1573.dT = TC_1040_1573.port_a.T - TC_1040_1573.port_b.T; TC_1040_1573.port_a.Q_flow = TC_1040_1573.Q_flow; TC_1040_1573.port_b.Q_flow = -TC_1040_1573.Q_flow; TC_1041_1042.Q_flow = TC_1041_1042.G * TC_1041_1042.dT; TC_1041_1042.dT = TC_1041_1042.port_a.T - TC_1041_1042.port_b.T; TC_1041_1042.port_a.Q_flow = TC_1041_1042.Q_flow; TC_1041_1042.port_b.Q_flow = -TC_1041_1042.Q_flow; TC_1041_1052.Q_flow = TC_1041_1052.G * TC_1041_1052.dT; TC_1041_1052.dT = TC_1041_1052.port_a.T - TC_1041_1052.port_b.T; TC_1041_1052.port_a.Q_flow = TC_1041_1052.Q_flow; TC_1041_1052.port_b.Q_flow = -TC_1041_1052.Q_flow; TC_1041_1574.Q_flow = TC_1041_1574.G * TC_1041_1574.dT; TC_1041_1574.dT = TC_1041_1574.port_a.T - TC_1041_1574.port_b.T; TC_1041_1574.port_a.Q_flow = TC_1041_1574.Q_flow; TC_1041_1574.port_b.Q_flow = -TC_1041_1574.Q_flow; TC_1042_1043.Q_flow = TC_1042_1043.G * TC_1042_1043.dT; TC_1042_1043.dT = TC_1042_1043.port_a.T - TC_1042_1043.port_b.T; TC_1042_1043.port_a.Q_flow = TC_1042_1043.Q_flow; TC_1042_1043.port_b.Q_flow = -TC_1042_1043.Q_flow; TC_1042_1053.Q_flow = TC_1042_1053.G * TC_1042_1053.dT; TC_1042_1053.dT = TC_1042_1053.port_a.T - TC_1042_1053.port_b.T; TC_1042_1053.port_a.Q_flow = TC_1042_1053.Q_flow; TC_1042_1053.port_b.Q_flow = -TC_1042_1053.Q_flow; TC_1042_1575.Q_flow = TC_1042_1575.G * TC_1042_1575.dT; TC_1042_1575.dT = TC_1042_1575.port_a.T - TC_1042_1575.port_b.T; TC_1042_1575.port_a.Q_flow = TC_1042_1575.Q_flow; TC_1042_1575.port_b.Q_flow = -TC_1042_1575.Q_flow; TC_1042_1643.Q_flow = TC_1042_1643.G * TC_1042_1643.dT; TC_1042_1643.dT = TC_1042_1643.port_a.T - TC_1042_1643.port_b.T; TC_1042_1643.port_a.Q_flow = TC_1042_1643.Q_flow; TC_1042_1643.port_b.Q_flow = -TC_1042_1643.Q_flow; TC_1043_1044.Q_flow = TC_1043_1044.G * TC_1043_1044.dT; TC_1043_1044.dT = TC_1043_1044.port_a.T - TC_1043_1044.port_b.T; TC_1043_1044.port_a.Q_flow = TC_1043_1044.Q_flow; TC_1043_1044.port_b.Q_flow = -TC_1043_1044.Q_flow; TC_1043_1054.Q_flow = TC_1043_1054.G * TC_1043_1054.dT; TC_1043_1054.dT = TC_1043_1054.port_a.T - TC_1043_1054.port_b.T; TC_1043_1054.port_a.Q_flow = TC_1043_1054.Q_flow; TC_1043_1054.port_b.Q_flow = -TC_1043_1054.Q_flow; TC_1043_1576.Q_flow = TC_1043_1576.G * TC_1043_1576.dT; TC_1043_1576.dT = TC_1043_1576.port_a.T - TC_1043_1576.port_b.T; TC_1043_1576.port_a.Q_flow = TC_1043_1576.Q_flow; TC_1043_1576.port_b.Q_flow = -TC_1043_1576.Q_flow; TC_1043_1644.Q_flow = TC_1043_1644.G * TC_1043_1644.dT; TC_1043_1644.dT = TC_1043_1644.port_a.T - TC_1043_1644.port_b.T; TC_1043_1644.port_a.Q_flow = TC_1043_1644.Q_flow; TC_1043_1644.port_b.Q_flow = -TC_1043_1644.Q_flow; TC_1044_1045.Q_flow = TC_1044_1045.G * TC_1044_1045.dT; TC_1044_1045.dT = TC_1044_1045.port_a.T - TC_1044_1045.port_b.T; TC_1044_1045.port_a.Q_flow = TC_1044_1045.Q_flow; TC_1044_1045.port_b.Q_flow = -TC_1044_1045.Q_flow; TC_1044_1055.Q_flow = TC_1044_1055.G * TC_1044_1055.dT; TC_1044_1055.dT = TC_1044_1055.port_a.T - TC_1044_1055.port_b.T; TC_1044_1055.port_a.Q_flow = TC_1044_1055.Q_flow; TC_1044_1055.port_b.Q_flow = -TC_1044_1055.Q_flow; TC_1044_1577.Q_flow = TC_1044_1577.G * TC_1044_1577.dT; TC_1044_1577.dT = TC_1044_1577.port_a.T - TC_1044_1577.port_b.T; TC_1044_1577.port_a.Q_flow = TC_1044_1577.Q_flow; TC_1044_1577.port_b.Q_flow = -TC_1044_1577.Q_flow; TC_1044_1645.Q_flow = TC_1044_1645.G * TC_1044_1645.dT; TC_1044_1645.dT = TC_1044_1645.port_a.T - TC_1044_1645.port_b.T; TC_1044_1645.port_a.Q_flow = TC_1044_1645.Q_flow; TC_1044_1645.port_b.Q_flow = -TC_1044_1645.Q_flow; TC_1045_1046.Q_flow = TC_1045_1046.G * TC_1045_1046.dT; TC_1045_1046.dT = TC_1045_1046.port_a.T - TC_1045_1046.port_b.T; TC_1045_1046.port_a.Q_flow = TC_1045_1046.Q_flow; TC_1045_1046.port_b.Q_flow = -TC_1045_1046.Q_flow; TC_1045_1056.Q_flow = TC_1045_1056.G * TC_1045_1056.dT; TC_1045_1056.dT = TC_1045_1056.port_a.T - TC_1045_1056.port_b.T; TC_1045_1056.port_a.Q_flow = TC_1045_1056.Q_flow; TC_1045_1056.port_b.Q_flow = -TC_1045_1056.Q_flow; TC_1045_1578.Q_flow = TC_1045_1578.G * TC_1045_1578.dT; TC_1045_1578.dT = TC_1045_1578.port_a.T - TC_1045_1578.port_b.T; TC_1045_1578.port_a.Q_flow = TC_1045_1578.Q_flow; TC_1045_1578.port_b.Q_flow = -TC_1045_1578.Q_flow; TC_1045_1646.Q_flow = TC_1045_1646.G * TC_1045_1646.dT; TC_1045_1646.dT = TC_1045_1646.port_a.T - TC_1045_1646.port_b.T; TC_1045_1646.port_a.Q_flow = TC_1045_1646.Q_flow; TC_1045_1646.port_b.Q_flow = -TC_1045_1646.Q_flow; TC_1046_1047.Q_flow = TC_1046_1047.G * TC_1046_1047.dT; TC_1046_1047.dT = TC_1046_1047.port_a.T - TC_1046_1047.port_b.T; TC_1046_1047.port_a.Q_flow = TC_1046_1047.Q_flow; TC_1046_1047.port_b.Q_flow = -TC_1046_1047.Q_flow; TC_1046_1057.Q_flow = TC_1046_1057.G * TC_1046_1057.dT; TC_1046_1057.dT = TC_1046_1057.port_a.T - TC_1046_1057.port_b.T; TC_1046_1057.port_a.Q_flow = TC_1046_1057.Q_flow; TC_1046_1057.port_b.Q_flow = -TC_1046_1057.Q_flow; TC_1046_1579.Q_flow = TC_1046_1579.G * TC_1046_1579.dT; TC_1046_1579.dT = TC_1046_1579.port_a.T - TC_1046_1579.port_b.T; TC_1046_1579.port_a.Q_flow = TC_1046_1579.Q_flow; TC_1046_1579.port_b.Q_flow = -TC_1046_1579.Q_flow; TC_1047_1048.Q_flow = TC_1047_1048.G * TC_1047_1048.dT; TC_1047_1048.dT = TC_1047_1048.port_a.T - TC_1047_1048.port_b.T; TC_1047_1048.port_a.Q_flow = TC_1047_1048.Q_flow; TC_1047_1048.port_b.Q_flow = -TC_1047_1048.Q_flow; TC_1047_1058.Q_flow = TC_1047_1058.G * TC_1047_1058.dT; TC_1047_1058.dT = TC_1047_1058.port_a.T - TC_1047_1058.port_b.T; TC_1047_1058.port_a.Q_flow = TC_1047_1058.Q_flow; TC_1047_1058.port_b.Q_flow = -TC_1047_1058.Q_flow; TC_1047_1580.Q_flow = TC_1047_1580.G * TC_1047_1580.dT; TC_1047_1580.dT = TC_1047_1580.port_a.T - TC_1047_1580.port_b.T; TC_1047_1580.port_a.Q_flow = TC_1047_1580.Q_flow; TC_1047_1580.port_b.Q_flow = -TC_1047_1580.Q_flow; TC_1048_1059.Q_flow = TC_1048_1059.G * TC_1048_1059.dT; TC_1048_1059.dT = TC_1048_1059.port_a.T - TC_1048_1059.port_b.T; TC_1048_1059.port_a.Q_flow = TC_1048_1059.Q_flow; TC_1048_1059.port_b.Q_flow = -TC_1048_1059.Q_flow; TC_1048_1119.Q_flow = TC_1048_1119.G * TC_1048_1119.dT; TC_1048_1119.dT = TC_1048_1119.port_a.T - TC_1048_1119.port_b.T; TC_1048_1119.port_a.Q_flow = TC_1048_1119.Q_flow; TC_1048_1119.port_b.Q_flow = -TC_1048_1119.Q_flow; TC_1049_1050.Q_flow = TC_1049_1050.G * TC_1049_1050.dT; TC_1049_1050.dT = TC_1049_1050.port_a.T - TC_1049_1050.port_b.T; TC_1049_1050.port_a.Q_flow = TC_1049_1050.Q_flow; TC_1049_1050.port_b.Q_flow = -TC_1049_1050.Q_flow; TC_1049_1060.Q_flow = TC_1049_1060.G * TC_1049_1060.dT; TC_1049_1060.dT = TC_1049_1060.port_a.T - TC_1049_1060.port_b.T; TC_1049_1060.port_a.Q_flow = TC_1049_1060.Q_flow; TC_1049_1060.port_b.Q_flow = -TC_1049_1060.Q_flow; TC_1049_1120.Q_flow = TC_1049_1120.G * TC_1049_1120.dT; TC_1049_1120.dT = TC_1049_1120.port_a.T - TC_1049_1120.port_b.T; TC_1049_1120.port_a.Q_flow = TC_1049_1120.Q_flow; TC_1049_1120.port_b.Q_flow = -TC_1049_1120.Q_flow; TC_1050_1051.Q_flow = TC_1050_1051.G * TC_1050_1051.dT; TC_1050_1051.dT = TC_1050_1051.port_a.T - TC_1050_1051.port_b.T; TC_1050_1051.port_a.Q_flow = TC_1050_1051.Q_flow; TC_1050_1051.port_b.Q_flow = -TC_1050_1051.Q_flow; TC_1050_1061.Q_flow = TC_1050_1061.G * TC_1050_1061.dT; TC_1050_1061.dT = TC_1050_1061.port_a.T - TC_1050_1061.port_b.T; TC_1050_1061.port_a.Q_flow = TC_1050_1061.Q_flow; TC_1050_1061.port_b.Q_flow = -TC_1050_1061.Q_flow; TC_1050_1581.Q_flow = TC_1050_1581.G * TC_1050_1581.dT; TC_1050_1581.dT = TC_1050_1581.port_a.T - TC_1050_1581.port_b.T; TC_1050_1581.port_a.Q_flow = TC_1050_1581.Q_flow; TC_1050_1581.port_b.Q_flow = -TC_1050_1581.Q_flow; TC_1051_1052.Q_flow = TC_1051_1052.G * TC_1051_1052.dT; TC_1051_1052.dT = TC_1051_1052.port_a.T - TC_1051_1052.port_b.T; TC_1051_1052.port_a.Q_flow = TC_1051_1052.Q_flow; TC_1051_1052.port_b.Q_flow = -TC_1051_1052.Q_flow; TC_1051_1062.Q_flow = TC_1051_1062.G * TC_1051_1062.dT; TC_1051_1062.dT = TC_1051_1062.port_a.T - TC_1051_1062.port_b.T; TC_1051_1062.port_a.Q_flow = TC_1051_1062.Q_flow; TC_1051_1062.port_b.Q_flow = -TC_1051_1062.Q_flow; TC_1051_1582.Q_flow = TC_1051_1582.G * TC_1051_1582.dT; TC_1051_1582.dT = TC_1051_1582.port_a.T - TC_1051_1582.port_b.T; TC_1051_1582.port_a.Q_flow = TC_1051_1582.Q_flow; TC_1051_1582.port_b.Q_flow = -TC_1051_1582.Q_flow; TC_1052_1053.Q_flow = TC_1052_1053.G * TC_1052_1053.dT; TC_1052_1053.dT = TC_1052_1053.port_a.T - TC_1052_1053.port_b.T; TC_1052_1053.port_a.Q_flow = TC_1052_1053.Q_flow; TC_1052_1053.port_b.Q_flow = -TC_1052_1053.Q_flow; TC_1052_1063.Q_flow = TC_1052_1063.G * TC_1052_1063.dT; TC_1052_1063.dT = TC_1052_1063.port_a.T - TC_1052_1063.port_b.T; TC_1052_1063.port_a.Q_flow = TC_1052_1063.Q_flow; TC_1052_1063.port_b.Q_flow = -TC_1052_1063.Q_flow; TC_1052_1583.Q_flow = TC_1052_1583.G * TC_1052_1583.dT; TC_1052_1583.dT = TC_1052_1583.port_a.T - TC_1052_1583.port_b.T; TC_1052_1583.port_a.Q_flow = TC_1052_1583.Q_flow; TC_1052_1583.port_b.Q_flow = -TC_1052_1583.Q_flow; TC_1053_1054.Q_flow = TC_1053_1054.G * TC_1053_1054.dT; TC_1053_1054.dT = TC_1053_1054.port_a.T - TC_1053_1054.port_b.T; TC_1053_1054.port_a.Q_flow = TC_1053_1054.Q_flow; TC_1053_1054.port_b.Q_flow = -TC_1053_1054.Q_flow; TC_1053_1064.Q_flow = TC_1053_1064.G * TC_1053_1064.dT; TC_1053_1064.dT = TC_1053_1064.port_a.T - TC_1053_1064.port_b.T; TC_1053_1064.port_a.Q_flow = TC_1053_1064.Q_flow; TC_1053_1064.port_b.Q_flow = -TC_1053_1064.Q_flow; TC_1053_1584.Q_flow = TC_1053_1584.G * TC_1053_1584.dT; TC_1053_1584.dT = TC_1053_1584.port_a.T - TC_1053_1584.port_b.T; TC_1053_1584.port_a.Q_flow = TC_1053_1584.Q_flow; TC_1053_1584.port_b.Q_flow = -TC_1053_1584.Q_flow; TC_1054_1055.Q_flow = TC_1054_1055.G * TC_1054_1055.dT; TC_1054_1055.dT = TC_1054_1055.port_a.T - TC_1054_1055.port_b.T; TC_1054_1055.port_a.Q_flow = TC_1054_1055.Q_flow; TC_1054_1055.port_b.Q_flow = -TC_1054_1055.Q_flow; TC_1054_1065.Q_flow = TC_1054_1065.G * TC_1054_1065.dT; TC_1054_1065.dT = TC_1054_1065.port_a.T - TC_1054_1065.port_b.T; TC_1054_1065.port_a.Q_flow = TC_1054_1065.Q_flow; TC_1054_1065.port_b.Q_flow = -TC_1054_1065.Q_flow; TC_1054_1585.Q_flow = TC_1054_1585.G * TC_1054_1585.dT; TC_1054_1585.dT = TC_1054_1585.port_a.T - TC_1054_1585.port_b.T; TC_1054_1585.port_a.Q_flow = TC_1054_1585.Q_flow; TC_1054_1585.port_b.Q_flow = -TC_1054_1585.Q_flow; TC_1055_1056.Q_flow = TC_1055_1056.G * TC_1055_1056.dT; TC_1055_1056.dT = TC_1055_1056.port_a.T - TC_1055_1056.port_b.T; TC_1055_1056.port_a.Q_flow = TC_1055_1056.Q_flow; TC_1055_1056.port_b.Q_flow = -TC_1055_1056.Q_flow; TC_1055_1586.Q_flow = TC_1055_1586.G * TC_1055_1586.dT; TC_1055_1586.dT = TC_1055_1586.port_a.T - TC_1055_1586.port_b.T; TC_1055_1586.port_a.Q_flow = TC_1055_1586.Q_flow; TC_1055_1586.port_b.Q_flow = -TC_1055_1586.Q_flow; TC_1055_1647.Q_flow = TC_1055_1647.G * TC_1055_1647.dT; TC_1055_1647.dT = TC_1055_1647.port_a.T - TC_1055_1647.port_b.T; TC_1055_1647.port_a.Q_flow = TC_1055_1647.Q_flow; TC_1055_1647.port_b.Q_flow = -TC_1055_1647.Q_flow; TC_1056_1057.Q_flow = TC_1056_1057.G * TC_1056_1057.dT; TC_1056_1057.dT = TC_1056_1057.port_a.T - TC_1056_1057.port_b.T; TC_1056_1057.port_a.Q_flow = TC_1056_1057.Q_flow; TC_1056_1057.port_b.Q_flow = -TC_1056_1057.Q_flow; TC_1056_1587.Q_flow = TC_1056_1587.G * TC_1056_1587.dT; TC_1056_1587.dT = TC_1056_1587.port_a.T - TC_1056_1587.port_b.T; TC_1056_1587.port_a.Q_flow = TC_1056_1587.Q_flow; TC_1056_1587.port_b.Q_flow = -TC_1056_1587.Q_flow; TC_1056_1648.Q_flow = TC_1056_1648.G * TC_1056_1648.dT; TC_1056_1648.dT = TC_1056_1648.port_a.T - TC_1056_1648.port_b.T; TC_1056_1648.port_a.Q_flow = TC_1056_1648.Q_flow; TC_1056_1648.port_b.Q_flow = -TC_1056_1648.Q_flow; TC_1057_1058.Q_flow = TC_1057_1058.G * TC_1057_1058.dT; TC_1057_1058.dT = TC_1057_1058.port_a.T - TC_1057_1058.port_b.T; TC_1057_1058.port_a.Q_flow = TC_1057_1058.Q_flow; TC_1057_1058.port_b.Q_flow = -TC_1057_1058.Q_flow; TC_1057_1588.Q_flow = TC_1057_1588.G * TC_1057_1588.dT; TC_1057_1588.dT = TC_1057_1588.port_a.T - TC_1057_1588.port_b.T; TC_1057_1588.port_a.Q_flow = TC_1057_1588.Q_flow; TC_1057_1588.port_b.Q_flow = -TC_1057_1588.Q_flow; TC_1057_1649.Q_flow = TC_1057_1649.G * TC_1057_1649.dT; TC_1057_1649.dT = TC_1057_1649.port_a.T - TC_1057_1649.port_b.T; TC_1057_1649.port_a.Q_flow = TC_1057_1649.Q_flow; TC_1057_1649.port_b.Q_flow = -TC_1057_1649.Q_flow; TC_1058_1059.Q_flow = TC_1058_1059.G * TC_1058_1059.dT; TC_1058_1059.dT = TC_1058_1059.port_a.T - TC_1058_1059.port_b.T; TC_1058_1059.port_a.Q_flow = TC_1058_1059.Q_flow; TC_1058_1059.port_b.Q_flow = -TC_1058_1059.Q_flow; TC_1058_1589.Q_flow = TC_1058_1589.G * TC_1058_1589.dT; TC_1058_1589.dT = TC_1058_1589.port_a.T - TC_1058_1589.port_b.T; TC_1058_1589.port_a.Q_flow = TC_1058_1589.Q_flow; TC_1058_1589.port_b.Q_flow = -TC_1058_1589.Q_flow; TC_1059_1121.Q_flow = TC_1059_1121.G * TC_1059_1121.dT; TC_1059_1121.dT = TC_1059_1121.port_a.T - TC_1059_1121.port_b.T; TC_1059_1121.port_a.Q_flow = TC_1059_1121.Q_flow; TC_1059_1121.port_b.Q_flow = -TC_1059_1121.Q_flow; TC_1060_1061.Q_flow = TC_1060_1061.G * TC_1060_1061.dT; TC_1060_1061.dT = TC_1060_1061.port_a.T - TC_1060_1061.port_b.T; TC_1060_1061.port_a.Q_flow = TC_1060_1061.Q_flow; TC_1060_1061.port_b.Q_flow = -TC_1060_1061.Q_flow; TC_1060_1122.Q_flow = TC_1060_1122.G * TC_1060_1122.dT; TC_1060_1122.dT = TC_1060_1122.port_a.T - TC_1060_1122.port_b.T; TC_1060_1122.port_a.Q_flow = TC_1060_1122.Q_flow; TC_1060_1122.port_b.Q_flow = -TC_1060_1122.Q_flow; TC_1061_1062.Q_flow = TC_1061_1062.G * TC_1061_1062.dT; TC_1061_1062.dT = TC_1061_1062.port_a.T - TC_1061_1062.port_b.T; TC_1061_1062.port_a.Q_flow = TC_1061_1062.Q_flow; TC_1061_1062.port_b.Q_flow = -TC_1061_1062.Q_flow; TC_1061_1590.Q_flow = TC_1061_1590.G * TC_1061_1590.dT; TC_1061_1590.dT = TC_1061_1590.port_a.T - TC_1061_1590.port_b.T; TC_1061_1590.port_a.Q_flow = TC_1061_1590.Q_flow; TC_1061_1590.port_b.Q_flow = -TC_1061_1590.Q_flow; TC_1062_1063.Q_flow = TC_1062_1063.G * TC_1062_1063.dT; TC_1062_1063.dT = TC_1062_1063.port_a.T - TC_1062_1063.port_b.T; TC_1062_1063.port_a.Q_flow = TC_1062_1063.Q_flow; TC_1062_1063.port_b.Q_flow = -TC_1062_1063.Q_flow; TC_1062_1591.Q_flow = TC_1062_1591.G * TC_1062_1591.dT; TC_1062_1591.dT = TC_1062_1591.port_a.T - TC_1062_1591.port_b.T; TC_1062_1591.port_a.Q_flow = TC_1062_1591.Q_flow; TC_1062_1591.port_b.Q_flow = -TC_1062_1591.Q_flow; TC_1063_1064.Q_flow = TC_1063_1064.G * TC_1063_1064.dT; TC_1063_1064.dT = TC_1063_1064.port_a.T - TC_1063_1064.port_b.T; TC_1063_1064.port_a.Q_flow = TC_1063_1064.Q_flow; TC_1063_1064.port_b.Q_flow = -TC_1063_1064.Q_flow; TC_1063_1592.Q_flow = TC_1063_1592.G * TC_1063_1592.dT; TC_1063_1592.dT = TC_1063_1592.port_a.T - TC_1063_1592.port_b.T; TC_1063_1592.port_a.Q_flow = TC_1063_1592.Q_flow; TC_1063_1592.port_b.Q_flow = -TC_1063_1592.Q_flow; TC_1064_1065.Q_flow = TC_1064_1065.G * TC_1064_1065.dT; TC_1064_1065.dT = TC_1064_1065.port_a.T - TC_1064_1065.port_b.T; TC_1064_1065.port_a.Q_flow = TC_1064_1065.Q_flow; TC_1064_1065.port_b.Q_flow = -TC_1064_1065.Q_flow; TC_1064_1593.Q_flow = TC_1064_1593.G * TC_1064_1593.dT; TC_1064_1593.dT = TC_1064_1593.port_a.T - TC_1064_1593.port_b.T; TC_1064_1593.port_a.Q_flow = TC_1064_1593.Q_flow; TC_1064_1593.port_b.Q_flow = -TC_1064_1593.Q_flow; TC_1065_1594.Q_flow = TC_1065_1594.G * TC_1065_1594.dT; TC_1065_1594.dT = TC_1065_1594.port_a.T - TC_1065_1594.port_b.T; TC_1065_1594.port_a.Q_flow = TC_1065_1594.Q_flow; TC_1065_1594.port_b.Q_flow = -TC_1065_1594.Q_flow; TC_1065_1647.Q_flow = TC_1065_1647.G * TC_1065_1647.dT; TC_1065_1647.dT = TC_1065_1647.port_a.T - TC_1065_1647.port_b.T; TC_1065_1647.port_a.Q_flow = TC_1065_1647.Q_flow; TC_1065_1647.port_b.Q_flow = -TC_1065_1647.Q_flow; TC_1066_1067.Q_flow = TC_1066_1067.G * TC_1066_1067.dT; TC_1066_1067.dT = TC_1066_1067.port_a.T - TC_1066_1067.port_b.T; TC_1066_1067.port_a.Q_flow = TC_1066_1067.Q_flow; TC_1066_1067.port_b.Q_flow = -TC_1066_1067.Q_flow; TC_1066_1077.Q_flow = TC_1066_1077.G * TC_1066_1077.dT; TC_1066_1077.dT = TC_1066_1077.port_a.T - TC_1066_1077.port_b.T; TC_1066_1077.port_a.Q_flow = TC_1066_1077.Q_flow; TC_1066_1077.port_b.Q_flow = -TC_1066_1077.Q_flow; TC_1066_1099.Q_flow = TC_1066_1099.G * TC_1066_1099.dT; TC_1066_1099.dT = TC_1066_1099.port_a.T - TC_1066_1099.port_b.T; TC_1066_1099.port_a.Q_flow = TC_1066_1099.Q_flow; TC_1066_1099.port_b.Q_flow = -TC_1066_1099.Q_flow; TC_1067_1068.Q_flow = TC_1067_1068.G * TC_1067_1068.dT; TC_1067_1068.dT = TC_1067_1068.port_a.T - TC_1067_1068.port_b.T; TC_1067_1068.port_a.Q_flow = TC_1067_1068.Q_flow; TC_1067_1068.port_b.Q_flow = -TC_1067_1068.Q_flow; TC_1067_1078.Q_flow = TC_1067_1078.G * TC_1067_1078.dT; TC_1067_1078.dT = TC_1067_1078.port_a.T - TC_1067_1078.port_b.T; TC_1067_1078.port_a.Q_flow = TC_1067_1078.Q_flow; TC_1067_1078.port_b.Q_flow = -TC_1067_1078.Q_flow; TC_1067_1100.Q_flow = TC_1067_1100.G * TC_1067_1100.dT; TC_1067_1100.dT = TC_1067_1100.port_a.T - TC_1067_1100.port_b.T; TC_1067_1100.port_a.Q_flow = TC_1067_1100.Q_flow; TC_1067_1100.port_b.Q_flow = -TC_1067_1100.Q_flow; TC_1068_1069.Q_flow = TC_1068_1069.G * TC_1068_1069.dT; TC_1068_1069.dT = TC_1068_1069.port_a.T - TC_1068_1069.port_b.T; TC_1068_1069.port_a.Q_flow = TC_1068_1069.Q_flow; TC_1068_1069.port_b.Q_flow = -TC_1068_1069.Q_flow; TC_1068_1079.Q_flow = TC_1068_1079.G * TC_1068_1079.dT; TC_1068_1079.dT = TC_1068_1079.port_a.T - TC_1068_1079.port_b.T; TC_1068_1079.port_a.Q_flow = TC_1068_1079.Q_flow; TC_1068_1079.port_b.Q_flow = -TC_1068_1079.Q_flow; TC_1068_1101.Q_flow = TC_1068_1101.G * TC_1068_1101.dT; TC_1068_1101.dT = TC_1068_1101.port_a.T - TC_1068_1101.port_b.T; TC_1068_1101.port_a.Q_flow = TC_1068_1101.Q_flow; TC_1068_1101.port_b.Q_flow = -TC_1068_1101.Q_flow; TC_1069_1070.Q_flow = TC_1069_1070.G * TC_1069_1070.dT; TC_1069_1070.dT = TC_1069_1070.port_a.T - TC_1069_1070.port_b.T; TC_1069_1070.port_a.Q_flow = TC_1069_1070.Q_flow; TC_1069_1070.port_b.Q_flow = -TC_1069_1070.Q_flow; TC_1069_1080.Q_flow = TC_1069_1080.G * TC_1069_1080.dT; TC_1069_1080.dT = TC_1069_1080.port_a.T - TC_1069_1080.port_b.T; TC_1069_1080.port_a.Q_flow = TC_1069_1080.Q_flow; TC_1069_1080.port_b.Q_flow = -TC_1069_1080.Q_flow; TC_1069_1102.Q_flow = TC_1069_1102.G * TC_1069_1102.dT; TC_1069_1102.dT = TC_1069_1102.port_a.T - TC_1069_1102.port_b.T; TC_1069_1102.port_a.Q_flow = TC_1069_1102.Q_flow; TC_1069_1102.port_b.Q_flow = -TC_1069_1102.Q_flow; TC_1070_1071.Q_flow = TC_1070_1071.G * TC_1070_1071.dT; TC_1070_1071.dT = TC_1070_1071.port_a.T - TC_1070_1071.port_b.T; TC_1070_1071.port_a.Q_flow = TC_1070_1071.Q_flow; TC_1070_1071.port_b.Q_flow = -TC_1070_1071.Q_flow; TC_1070_1081.Q_flow = TC_1070_1081.G * TC_1070_1081.dT; TC_1070_1081.dT = TC_1070_1081.port_a.T - TC_1070_1081.port_b.T; TC_1070_1081.port_a.Q_flow = TC_1070_1081.Q_flow; TC_1070_1081.port_b.Q_flow = -TC_1070_1081.Q_flow; TC_1070_1103.Q_flow = TC_1070_1103.G * TC_1070_1103.dT; TC_1070_1103.dT = TC_1070_1103.port_a.T - TC_1070_1103.port_b.T; TC_1070_1103.port_a.Q_flow = TC_1070_1103.Q_flow; TC_1070_1103.port_b.Q_flow = -TC_1070_1103.Q_flow; TC_1071_1072.Q_flow = TC_1071_1072.G * TC_1071_1072.dT; TC_1071_1072.dT = TC_1071_1072.port_a.T - TC_1071_1072.port_b.T; TC_1071_1072.port_a.Q_flow = TC_1071_1072.Q_flow; TC_1071_1072.port_b.Q_flow = -TC_1071_1072.Q_flow; TC_1071_1082.Q_flow = TC_1071_1082.G * TC_1071_1082.dT; TC_1071_1082.dT = TC_1071_1082.port_a.T - TC_1071_1082.port_b.T; TC_1071_1082.port_a.Q_flow = TC_1071_1082.Q_flow; TC_1071_1082.port_b.Q_flow = -TC_1071_1082.Q_flow; TC_1071_1104.Q_flow = TC_1071_1104.G * TC_1071_1104.dT; TC_1071_1104.dT = TC_1071_1104.port_a.T - TC_1071_1104.port_b.T; TC_1071_1104.port_a.Q_flow = TC_1071_1104.Q_flow; TC_1071_1104.port_b.Q_flow = -TC_1071_1104.Q_flow; TC_1072_1073.Q_flow = TC_1072_1073.G * TC_1072_1073.dT; TC_1072_1073.dT = TC_1072_1073.port_a.T - TC_1072_1073.port_b.T; TC_1072_1073.port_a.Q_flow = TC_1072_1073.Q_flow; TC_1072_1073.port_b.Q_flow = -TC_1072_1073.Q_flow; TC_1072_1083.Q_flow = TC_1072_1083.G * TC_1072_1083.dT; TC_1072_1083.dT = TC_1072_1083.port_a.T - TC_1072_1083.port_b.T; TC_1072_1083.port_a.Q_flow = TC_1072_1083.Q_flow; TC_1072_1083.port_b.Q_flow = -TC_1072_1083.Q_flow; TC_1072_1105.Q_flow = TC_1072_1105.G * TC_1072_1105.dT; TC_1072_1105.dT = TC_1072_1105.port_a.T - TC_1072_1105.port_b.T; TC_1072_1105.port_a.Q_flow = TC_1072_1105.Q_flow; TC_1072_1105.port_b.Q_flow = -TC_1072_1105.Q_flow; TC_1073_1074.Q_flow = TC_1073_1074.G * TC_1073_1074.dT; TC_1073_1074.dT = TC_1073_1074.port_a.T - TC_1073_1074.port_b.T; TC_1073_1074.port_a.Q_flow = TC_1073_1074.Q_flow; TC_1073_1074.port_b.Q_flow = -TC_1073_1074.Q_flow; TC_1073_1084.Q_flow = TC_1073_1084.G * TC_1073_1084.dT; TC_1073_1084.dT = TC_1073_1084.port_a.T - TC_1073_1084.port_b.T; TC_1073_1084.port_a.Q_flow = TC_1073_1084.Q_flow; TC_1073_1084.port_b.Q_flow = -TC_1073_1084.Q_flow; TC_1073_1106.Q_flow = TC_1073_1106.G * TC_1073_1106.dT; TC_1073_1106.dT = TC_1073_1106.port_a.T - TC_1073_1106.port_b.T; TC_1073_1106.port_a.Q_flow = TC_1073_1106.Q_flow; TC_1073_1106.port_b.Q_flow = -TC_1073_1106.Q_flow; TC_1074_1075.Q_flow = TC_1074_1075.G * TC_1074_1075.dT; TC_1074_1075.dT = TC_1074_1075.port_a.T - TC_1074_1075.port_b.T; TC_1074_1075.port_a.Q_flow = TC_1074_1075.Q_flow; TC_1074_1075.port_b.Q_flow = -TC_1074_1075.Q_flow; TC_1074_1085.Q_flow = TC_1074_1085.G * TC_1074_1085.dT; TC_1074_1085.dT = TC_1074_1085.port_a.T - TC_1074_1085.port_b.T; TC_1074_1085.port_a.Q_flow = TC_1074_1085.Q_flow; TC_1074_1085.port_b.Q_flow = -TC_1074_1085.Q_flow; TC_1074_1107.Q_flow = TC_1074_1107.G * TC_1074_1107.dT; TC_1074_1107.dT = TC_1074_1107.port_a.T - TC_1074_1107.port_b.T; TC_1074_1107.port_a.Q_flow = TC_1074_1107.Q_flow; TC_1074_1107.port_b.Q_flow = -TC_1074_1107.Q_flow; TC_1075_1076.Q_flow = TC_1075_1076.G * TC_1075_1076.dT; TC_1075_1076.dT = TC_1075_1076.port_a.T - TC_1075_1076.port_b.T; TC_1075_1076.port_a.Q_flow = TC_1075_1076.Q_flow; TC_1075_1076.port_b.Q_flow = -TC_1075_1076.Q_flow; TC_1075_1086.Q_flow = TC_1075_1086.G * TC_1075_1086.dT; TC_1075_1086.dT = TC_1075_1086.port_a.T - TC_1075_1086.port_b.T; TC_1075_1086.port_a.Q_flow = TC_1075_1086.Q_flow; TC_1075_1086.port_b.Q_flow = -TC_1075_1086.Q_flow; TC_1075_1108.Q_flow = TC_1075_1108.G * TC_1075_1108.dT; TC_1075_1108.dT = TC_1075_1108.port_a.T - TC_1075_1108.port_b.T; TC_1075_1108.port_a.Q_flow = TC_1075_1108.Q_flow; TC_1075_1108.port_b.Q_flow = -TC_1075_1108.Q_flow; TC_1076_1087.Q_flow = TC_1076_1087.G * TC_1076_1087.dT; TC_1076_1087.dT = TC_1076_1087.port_a.T - TC_1076_1087.port_b.T; TC_1076_1087.port_a.Q_flow = TC_1076_1087.Q_flow; TC_1076_1087.port_b.Q_flow = -TC_1076_1087.Q_flow; TC_1076_1109.Q_flow = TC_1076_1109.G * TC_1076_1109.dT; TC_1076_1109.dT = TC_1076_1109.port_a.T - TC_1076_1109.port_b.T; TC_1076_1109.port_a.Q_flow = TC_1076_1109.Q_flow; TC_1076_1109.port_b.Q_flow = -TC_1076_1109.Q_flow; TC_1077_1078.Q_flow = TC_1077_1078.G * TC_1077_1078.dT; TC_1077_1078.dT = TC_1077_1078.port_a.T - TC_1077_1078.port_b.T; TC_1077_1078.port_a.Q_flow = TC_1077_1078.Q_flow; TC_1077_1078.port_b.Q_flow = -TC_1077_1078.Q_flow; TC_1077_1088.Q_flow = TC_1077_1088.G * TC_1077_1088.dT; TC_1077_1088.dT = TC_1077_1088.port_a.T - TC_1077_1088.port_b.T; TC_1077_1088.port_a.Q_flow = TC_1077_1088.Q_flow; TC_1077_1088.port_b.Q_flow = -TC_1077_1088.Q_flow; TC_1077_1110.Q_flow = TC_1077_1110.G * TC_1077_1110.dT; TC_1077_1110.dT = TC_1077_1110.port_a.T - TC_1077_1110.port_b.T; TC_1077_1110.port_a.Q_flow = TC_1077_1110.Q_flow; TC_1077_1110.port_b.Q_flow = -TC_1077_1110.Q_flow; TC_1078_1079.Q_flow = TC_1078_1079.G * TC_1078_1079.dT; TC_1078_1079.dT = TC_1078_1079.port_a.T - TC_1078_1079.port_b.T; TC_1078_1079.port_a.Q_flow = TC_1078_1079.Q_flow; TC_1078_1079.port_b.Q_flow = -TC_1078_1079.Q_flow; TC_1078_1089.Q_flow = TC_1078_1089.G * TC_1078_1089.dT; TC_1078_1089.dT = TC_1078_1089.port_a.T - TC_1078_1089.port_b.T; TC_1078_1089.port_a.Q_flow = TC_1078_1089.Q_flow; TC_1078_1089.port_b.Q_flow = -TC_1078_1089.Q_flow; TC_1078_1608.Q_flow = TC_1078_1608.G * TC_1078_1608.dT; TC_1078_1608.dT = TC_1078_1608.port_a.T - TC_1078_1608.port_b.T; TC_1078_1608.port_a.Q_flow = TC_1078_1608.Q_flow; TC_1078_1608.port_b.Q_flow = -TC_1078_1608.Q_flow; TC_1079_1080.Q_flow = TC_1079_1080.G * TC_1079_1080.dT; TC_1079_1080.dT = TC_1079_1080.port_a.T - TC_1079_1080.port_b.T; TC_1079_1080.port_a.Q_flow = TC_1079_1080.Q_flow; TC_1079_1080.port_b.Q_flow = -TC_1079_1080.Q_flow; TC_1079_1090.Q_flow = TC_1079_1090.G * TC_1079_1090.dT; TC_1079_1090.dT = TC_1079_1090.port_a.T - TC_1079_1090.port_b.T; TC_1079_1090.port_a.Q_flow = TC_1079_1090.Q_flow; TC_1079_1090.port_b.Q_flow = -TC_1079_1090.Q_flow; TC_1079_1609.Q_flow = TC_1079_1609.G * TC_1079_1609.dT; TC_1079_1609.dT = TC_1079_1609.port_a.T - TC_1079_1609.port_b.T; TC_1079_1609.port_a.Q_flow = TC_1079_1609.Q_flow; TC_1079_1609.port_b.Q_flow = -TC_1079_1609.Q_flow; TC_1080_1081.Q_flow = TC_1080_1081.G * TC_1080_1081.dT; TC_1080_1081.dT = TC_1080_1081.port_a.T - TC_1080_1081.port_b.T; TC_1080_1081.port_a.Q_flow = TC_1080_1081.Q_flow; TC_1080_1081.port_b.Q_flow = -TC_1080_1081.Q_flow; TC_1080_1091.Q_flow = TC_1080_1091.G * TC_1080_1091.dT; TC_1080_1091.dT = TC_1080_1091.port_a.T - TC_1080_1091.port_b.T; TC_1080_1091.port_a.Q_flow = TC_1080_1091.Q_flow; TC_1080_1091.port_b.Q_flow = -TC_1080_1091.Q_flow; TC_1080_1610.Q_flow = TC_1080_1610.G * TC_1080_1610.dT; TC_1080_1610.dT = TC_1080_1610.port_a.T - TC_1080_1610.port_b.T; TC_1080_1610.port_a.Q_flow = TC_1080_1610.Q_flow; TC_1080_1610.port_b.Q_flow = -TC_1080_1610.Q_flow; TC_1081_1082.Q_flow = TC_1081_1082.G * TC_1081_1082.dT; TC_1081_1082.dT = TC_1081_1082.port_a.T - TC_1081_1082.port_b.T; TC_1081_1082.port_a.Q_flow = TC_1081_1082.Q_flow; TC_1081_1082.port_b.Q_flow = -TC_1081_1082.Q_flow; TC_1081_1611.Q_flow = TC_1081_1611.G * TC_1081_1611.dT; TC_1081_1611.dT = TC_1081_1611.port_a.T - TC_1081_1611.port_b.T; TC_1081_1611.port_a.Q_flow = TC_1081_1611.Q_flow; TC_1081_1611.port_b.Q_flow = -TC_1081_1611.Q_flow; TC_1081_1635.Q_flow = TC_1081_1635.G * TC_1081_1635.dT; TC_1081_1635.dT = TC_1081_1635.port_a.T - TC_1081_1635.port_b.T; TC_1081_1635.port_a.Q_flow = TC_1081_1635.Q_flow; TC_1081_1635.port_b.Q_flow = -TC_1081_1635.Q_flow; TC_1082_1083.Q_flow = TC_1082_1083.G * TC_1082_1083.dT; TC_1082_1083.dT = TC_1082_1083.port_a.T - TC_1082_1083.port_b.T; TC_1082_1083.port_a.Q_flow = TC_1082_1083.Q_flow; TC_1082_1083.port_b.Q_flow = -TC_1082_1083.Q_flow; TC_1082_1612.Q_flow = TC_1082_1612.G * TC_1082_1612.dT; TC_1082_1612.dT = TC_1082_1612.port_a.T - TC_1082_1612.port_b.T; TC_1082_1612.port_a.Q_flow = TC_1082_1612.Q_flow; TC_1082_1612.port_b.Q_flow = -TC_1082_1612.Q_flow; TC_1082_1636.Q_flow = TC_1082_1636.G * TC_1082_1636.dT; TC_1082_1636.dT = TC_1082_1636.port_a.T - TC_1082_1636.port_b.T; TC_1082_1636.port_a.Q_flow = TC_1082_1636.Q_flow; TC_1082_1636.port_b.Q_flow = -TC_1082_1636.Q_flow; TC_1083_1084.Q_flow = TC_1083_1084.G * TC_1083_1084.dT; TC_1083_1084.dT = TC_1083_1084.port_a.T - TC_1083_1084.port_b.T; TC_1083_1084.port_a.Q_flow = TC_1083_1084.Q_flow; TC_1083_1084.port_b.Q_flow = -TC_1083_1084.Q_flow; TC_1083_1613.Q_flow = TC_1083_1613.G * TC_1083_1613.dT; TC_1083_1613.dT = TC_1083_1613.port_a.T - TC_1083_1613.port_b.T; TC_1083_1613.port_a.Q_flow = TC_1083_1613.Q_flow; TC_1083_1613.port_b.Q_flow = -TC_1083_1613.Q_flow; TC_1083_1637.Q_flow = TC_1083_1637.G * TC_1083_1637.dT; TC_1083_1637.dT = TC_1083_1637.port_a.T - TC_1083_1637.port_b.T; TC_1083_1637.port_a.Q_flow = TC_1083_1637.Q_flow; TC_1083_1637.port_b.Q_flow = -TC_1083_1637.Q_flow; TC_1084_1085.Q_flow = TC_1084_1085.G * TC_1084_1085.dT; TC_1084_1085.dT = TC_1084_1085.port_a.T - TC_1084_1085.port_b.T; TC_1084_1085.port_a.Q_flow = TC_1084_1085.Q_flow; TC_1084_1085.port_b.Q_flow = -TC_1084_1085.Q_flow; TC_1084_1614.Q_flow = TC_1084_1614.G * TC_1084_1614.dT; TC_1084_1614.dT = TC_1084_1614.port_a.T - TC_1084_1614.port_b.T; TC_1084_1614.port_a.Q_flow = TC_1084_1614.Q_flow; TC_1084_1614.port_b.Q_flow = -TC_1084_1614.Q_flow; TC_1084_1638.Q_flow = TC_1084_1638.G * TC_1084_1638.dT; TC_1084_1638.dT = TC_1084_1638.port_a.T - TC_1084_1638.port_b.T; TC_1084_1638.port_a.Q_flow = TC_1084_1638.Q_flow; TC_1084_1638.port_b.Q_flow = -TC_1084_1638.Q_flow; TC_1085_1086.Q_flow = TC_1085_1086.G * TC_1085_1086.dT; TC_1085_1086.dT = TC_1085_1086.port_a.T - TC_1085_1086.port_b.T; TC_1085_1086.port_a.Q_flow = TC_1085_1086.Q_flow; TC_1085_1086.port_b.Q_flow = -TC_1085_1086.Q_flow; TC_1085_1092.Q_flow = TC_1085_1092.G * TC_1085_1092.dT; TC_1085_1092.dT = TC_1085_1092.port_a.T - TC_1085_1092.port_b.T; TC_1085_1092.port_a.Q_flow = TC_1085_1092.Q_flow; TC_1085_1092.port_b.Q_flow = -TC_1085_1092.Q_flow; TC_1085_1615.Q_flow = TC_1085_1615.G * TC_1085_1615.dT; TC_1085_1615.dT = TC_1085_1615.port_a.T - TC_1085_1615.port_b.T; TC_1085_1615.port_a.Q_flow = TC_1085_1615.Q_flow; TC_1085_1615.port_b.Q_flow = -TC_1085_1615.Q_flow; TC_1086_1087.Q_flow = TC_1086_1087.G * TC_1086_1087.dT; TC_1086_1087.dT = TC_1086_1087.port_a.T - TC_1086_1087.port_b.T; TC_1086_1087.port_a.Q_flow = TC_1086_1087.Q_flow; TC_1086_1087.port_b.Q_flow = -TC_1086_1087.Q_flow; TC_1086_1093.Q_flow = TC_1086_1093.G * TC_1086_1093.dT; TC_1086_1093.dT = TC_1086_1093.port_a.T - TC_1086_1093.port_b.T; TC_1086_1093.port_a.Q_flow = TC_1086_1093.Q_flow; TC_1086_1093.port_b.Q_flow = -TC_1086_1093.Q_flow; TC_1086_1616.Q_flow = TC_1086_1616.G * TC_1086_1616.dT; TC_1086_1616.dT = TC_1086_1616.port_a.T - TC_1086_1616.port_b.T; TC_1086_1616.port_a.Q_flow = TC_1086_1616.Q_flow; TC_1086_1616.port_b.Q_flow = -TC_1086_1616.Q_flow; TC_1087_1094.Q_flow = TC_1087_1094.G * TC_1087_1094.dT; TC_1087_1094.dT = TC_1087_1094.port_a.T - TC_1087_1094.port_b.T; TC_1087_1094.port_a.Q_flow = TC_1087_1094.Q_flow; TC_1087_1094.port_b.Q_flow = -TC_1087_1094.Q_flow; TC_1087_1111.Q_flow = TC_1087_1111.G * TC_1087_1111.dT; TC_1087_1111.dT = TC_1087_1111.port_a.T - TC_1087_1111.port_b.T; TC_1087_1111.port_a.Q_flow = TC_1087_1111.Q_flow; TC_1087_1111.port_b.Q_flow = -TC_1087_1111.Q_flow; TC_1088_1089.Q_flow = TC_1088_1089.G * TC_1088_1089.dT; TC_1088_1089.dT = TC_1088_1089.port_a.T - TC_1088_1089.port_b.T; TC_1088_1089.port_a.Q_flow = TC_1088_1089.Q_flow; TC_1088_1089.port_b.Q_flow = -TC_1088_1089.Q_flow; TC_1088_1095.Q_flow = TC_1088_1095.G * TC_1088_1095.dT; TC_1088_1095.dT = TC_1088_1095.port_a.T - TC_1088_1095.port_b.T; TC_1088_1095.port_a.Q_flow = TC_1088_1095.Q_flow; TC_1088_1095.port_b.Q_flow = -TC_1088_1095.Q_flow; TC_1088_1112.Q_flow = TC_1088_1112.G * TC_1088_1112.dT; TC_1088_1112.dT = TC_1088_1112.port_a.T - TC_1088_1112.port_b.T; TC_1088_1112.port_a.Q_flow = TC_1088_1112.Q_flow; TC_1088_1112.port_b.Q_flow = -TC_1088_1112.Q_flow; TC_1089_1090.Q_flow = TC_1089_1090.G * TC_1089_1090.dT; TC_1089_1090.dT = TC_1089_1090.port_a.T - TC_1089_1090.port_b.T; TC_1089_1090.port_a.Q_flow = TC_1089_1090.Q_flow; TC_1089_1090.port_b.Q_flow = -TC_1089_1090.Q_flow; TC_1089_1096.Q_flow = TC_1089_1096.G * TC_1089_1096.dT; TC_1089_1096.dT = TC_1089_1096.port_a.T - TC_1089_1096.port_b.T; TC_1089_1096.port_a.Q_flow = TC_1089_1096.Q_flow; TC_1089_1096.port_b.Q_flow = -TC_1089_1096.Q_flow; TC_1089_1617.Q_flow = TC_1089_1617.G * TC_1089_1617.dT; TC_1089_1617.dT = TC_1089_1617.port_a.T - TC_1089_1617.port_b.T; TC_1089_1617.port_a.Q_flow = TC_1089_1617.Q_flow; TC_1089_1617.port_b.Q_flow = -TC_1089_1617.Q_flow; TC_1090_1091.Q_flow = TC_1090_1091.G * TC_1090_1091.dT; TC_1090_1091.dT = TC_1090_1091.port_a.T - TC_1090_1091.port_b.T; TC_1090_1091.port_a.Q_flow = TC_1090_1091.Q_flow; TC_1090_1091.port_b.Q_flow = -TC_1090_1091.Q_flow; TC_1090_1097.Q_flow = TC_1090_1097.G * TC_1090_1097.dT; TC_1090_1097.dT = TC_1090_1097.port_a.T - TC_1090_1097.port_b.T; TC_1090_1097.port_a.Q_flow = TC_1090_1097.Q_flow; TC_1090_1097.port_b.Q_flow = -TC_1090_1097.Q_flow; TC_1090_1618.Q_flow = TC_1090_1618.G * TC_1090_1618.dT; TC_1090_1618.dT = TC_1090_1618.port_a.T - TC_1090_1618.port_b.T; TC_1090_1618.port_a.Q_flow = TC_1090_1618.Q_flow; TC_1090_1618.port_b.Q_flow = -TC_1090_1618.Q_flow; TC_1091_1098.Q_flow = TC_1091_1098.G * TC_1091_1098.dT; TC_1091_1098.dT = TC_1091_1098.port_a.T - TC_1091_1098.port_b.T; TC_1091_1098.port_a.Q_flow = TC_1091_1098.Q_flow; TC_1091_1098.port_b.Q_flow = -TC_1091_1098.Q_flow; TC_1091_1619.Q_flow = TC_1091_1619.G * TC_1091_1619.dT; TC_1091_1619.dT = TC_1091_1619.port_a.T - TC_1091_1619.port_b.T; TC_1091_1619.port_a.Q_flow = TC_1091_1619.Q_flow; TC_1091_1619.port_b.Q_flow = -TC_1091_1619.Q_flow; TC_1091_1635.Q_flow = TC_1091_1635.G * TC_1091_1635.dT; TC_1091_1635.dT = TC_1091_1635.port_a.T - TC_1091_1635.port_b.T; TC_1091_1635.port_a.Q_flow = TC_1091_1635.Q_flow; TC_1091_1635.port_b.Q_flow = -TC_1091_1635.Q_flow; TC_1092_1093.Q_flow = TC_1092_1093.G * TC_1092_1093.dT; TC_1092_1093.dT = TC_1092_1093.port_a.T - TC_1092_1093.port_b.T; TC_1092_1093.port_a.Q_flow = TC_1092_1093.Q_flow; TC_1092_1093.port_b.Q_flow = -TC_1092_1093.Q_flow; TC_1092_1624.Q_flow = TC_1092_1624.G * TC_1092_1624.dT; TC_1092_1624.dT = TC_1092_1624.port_a.T - TC_1092_1624.port_b.T; TC_1092_1624.port_a.Q_flow = TC_1092_1624.Q_flow; TC_1092_1624.port_b.Q_flow = -TC_1092_1624.Q_flow; TC_1092_1638.Q_flow = TC_1092_1638.G * TC_1092_1638.dT; TC_1092_1638.dT = TC_1092_1638.port_a.T - TC_1092_1638.port_b.T; TC_1092_1638.port_a.Q_flow = TC_1092_1638.Q_flow; TC_1092_1638.port_b.Q_flow = -TC_1092_1638.Q_flow; TC_1093_1094.Q_flow = TC_1093_1094.G * TC_1093_1094.dT; TC_1093_1094.dT = TC_1093_1094.port_a.T - TC_1093_1094.port_b.T; TC_1093_1094.port_a.Q_flow = TC_1093_1094.Q_flow; TC_1093_1094.port_b.Q_flow = -TC_1093_1094.Q_flow; TC_1093_1625.Q_flow = TC_1093_1625.G * TC_1093_1625.dT; TC_1093_1625.dT = TC_1093_1625.port_a.T - TC_1093_1625.port_b.T; TC_1093_1625.port_a.Q_flow = TC_1093_1625.Q_flow; TC_1093_1625.port_b.Q_flow = -TC_1093_1625.Q_flow; TC_1094_1113.Q_flow = TC_1094_1113.G * TC_1094_1113.dT; TC_1094_1113.dT = TC_1094_1113.port_a.T - TC_1094_1113.port_b.T; TC_1094_1113.port_a.Q_flow = TC_1094_1113.Q_flow; TC_1094_1113.port_b.Q_flow = -TC_1094_1113.Q_flow; TC_1095_1096.Q_flow = TC_1095_1096.G * TC_1095_1096.dT; TC_1095_1096.dT = TC_1095_1096.port_a.T - TC_1095_1096.port_b.T; TC_1095_1096.port_a.Q_flow = TC_1095_1096.Q_flow; TC_1095_1096.port_b.Q_flow = -TC_1095_1096.Q_flow; TC_1095_1114.Q_flow = TC_1095_1114.G * TC_1095_1114.dT; TC_1095_1114.dT = TC_1095_1114.port_a.T - TC_1095_1114.port_b.T; TC_1095_1114.port_a.Q_flow = TC_1095_1114.Q_flow; TC_1095_1114.port_b.Q_flow = -TC_1095_1114.Q_flow; TC_1096_1097.Q_flow = TC_1096_1097.G * TC_1096_1097.dT; TC_1096_1097.dT = TC_1096_1097.port_a.T - TC_1096_1097.port_b.T; TC_1096_1097.port_a.Q_flow = TC_1096_1097.Q_flow; TC_1096_1097.port_b.Q_flow = -TC_1096_1097.Q_flow; TC_1096_1626.Q_flow = TC_1096_1626.G * TC_1096_1626.dT; TC_1096_1626.dT = TC_1096_1626.port_a.T - TC_1096_1626.port_b.T; TC_1096_1626.port_a.Q_flow = TC_1096_1626.Q_flow; TC_1096_1626.port_b.Q_flow = -TC_1096_1626.Q_flow; TC_1097_1098.Q_flow = TC_1097_1098.G * TC_1097_1098.dT; TC_1097_1098.dT = TC_1097_1098.port_a.T - TC_1097_1098.port_b.T; TC_1097_1098.port_a.Q_flow = TC_1097_1098.Q_flow; TC_1097_1098.port_b.Q_flow = -TC_1097_1098.Q_flow; TC_1097_1627.Q_flow = TC_1097_1627.G * TC_1097_1627.dT; TC_1097_1627.dT = TC_1097_1627.port_a.T - TC_1097_1627.port_b.T; TC_1097_1627.port_a.Q_flow = TC_1097_1627.Q_flow; TC_1097_1627.port_b.Q_flow = -TC_1097_1627.Q_flow; TC_1098_1628.Q_flow = TC_1098_1628.G * TC_1098_1628.dT; TC_1098_1628.dT = TC_1098_1628.port_a.T - TC_1098_1628.port_b.T; TC_1098_1628.port_a.Q_flow = TC_1098_1628.Q_flow; TC_1098_1628.port_b.Q_flow = -TC_1098_1628.Q_flow; TC_1098_1639.Q_flow = TC_1098_1639.G * TC_1098_1639.dT; TC_1098_1639.dT = TC_1098_1639.port_a.T - TC_1098_1639.port_b.T; TC_1098_1639.port_a.Q_flow = TC_1098_1639.Q_flow; TC_1098_1639.port_b.Q_flow = -TC_1098_1639.Q_flow; TC_1099_1100.Q_flow = TC_1099_1100.G * TC_1099_1100.dT; TC_1099_1100.dT = TC_1099_1100.port_a.T - TC_1099_1100.port_b.T; TC_1099_1100.port_a.Q_flow = TC_1099_1100.Q_flow; TC_1099_1100.port_b.Q_flow = -TC_1099_1100.Q_flow; TC_1099_1110.Q_flow = TC_1099_1110.G * TC_1099_1110.dT; TC_1099_1110.dT = TC_1099_1110.port_a.T - TC_1099_1110.port_b.T; TC_1099_1110.port_a.Q_flow = TC_1099_1110.Q_flow; TC_1099_1110.port_b.Q_flow = -TC_1099_1110.Q_flow; TC_1099_1145.Q_flow = TC_1099_1145.G * TC_1099_1145.dT; TC_1099_1145.dT = TC_1099_1145.port_a.T - TC_1099_1145.port_b.T; TC_1099_1145.port_a.Q_flow = TC_1099_1145.Q_flow; TC_1099_1145.port_b.Q_flow = -TC_1099_1145.Q_flow; TC_1100_1101.Q_flow = TC_1100_1101.G * TC_1100_1101.dT; TC_1100_1101.dT = TC_1100_1101.port_a.T - TC_1100_1101.port_b.T; TC_1100_1101.port_a.Q_flow = TC_1100_1101.Q_flow; TC_1100_1101.port_b.Q_flow = -TC_1100_1101.Q_flow; TC_1100_1146.Q_flow = TC_1100_1146.G * TC_1100_1146.dT; TC_1100_1146.dT = TC_1100_1146.port_a.T - TC_1100_1146.port_b.T; TC_1100_1146.port_a.Q_flow = TC_1100_1146.Q_flow; TC_1100_1146.port_b.Q_flow = -TC_1100_1146.Q_flow; TC_1100_1608.Q_flow = TC_1100_1608.G * TC_1100_1608.dT; TC_1100_1608.dT = TC_1100_1608.port_a.T - TC_1100_1608.port_b.T; TC_1100_1608.port_a.Q_flow = TC_1100_1608.Q_flow; TC_1100_1608.port_b.Q_flow = -TC_1100_1608.Q_flow; TC_1101_1102.Q_flow = TC_1101_1102.G * TC_1101_1102.dT; TC_1101_1102.dT = TC_1101_1102.port_a.T - TC_1101_1102.port_b.T; TC_1101_1102.port_a.Q_flow = TC_1101_1102.Q_flow; TC_1101_1102.port_b.Q_flow = -TC_1101_1102.Q_flow; TC_1101_1147.Q_flow = TC_1101_1147.G * TC_1101_1147.dT; TC_1101_1147.dT = TC_1101_1147.port_a.T - TC_1101_1147.port_b.T; TC_1101_1147.port_a.Q_flow = TC_1101_1147.Q_flow; TC_1101_1147.port_b.Q_flow = -TC_1101_1147.Q_flow; TC_1101_1609.Q_flow = TC_1101_1609.G * TC_1101_1609.dT; TC_1101_1609.dT = TC_1101_1609.port_a.T - TC_1101_1609.port_b.T; TC_1101_1609.port_a.Q_flow = TC_1101_1609.Q_flow; TC_1101_1609.port_b.Q_flow = -TC_1101_1609.Q_flow; TC_1102_1103.Q_flow = TC_1102_1103.G * TC_1102_1103.dT; TC_1102_1103.dT = TC_1102_1103.port_a.T - TC_1102_1103.port_b.T; TC_1102_1103.port_a.Q_flow = TC_1102_1103.Q_flow; TC_1102_1103.port_b.Q_flow = -TC_1102_1103.Q_flow; TC_1102_1148.Q_flow = TC_1102_1148.G * TC_1102_1148.dT; TC_1102_1148.dT = TC_1102_1148.port_a.T - TC_1102_1148.port_b.T; TC_1102_1148.port_a.Q_flow = TC_1102_1148.Q_flow; TC_1102_1148.port_b.Q_flow = -TC_1102_1148.Q_flow; TC_1102_1610.Q_flow = TC_1102_1610.G * TC_1102_1610.dT; TC_1102_1610.dT = TC_1102_1610.port_a.T - TC_1102_1610.port_b.T; TC_1102_1610.port_a.Q_flow = TC_1102_1610.Q_flow; TC_1102_1610.port_b.Q_flow = -TC_1102_1610.Q_flow; TC_1103_1104.Q_flow = TC_1103_1104.G * TC_1103_1104.dT; TC_1103_1104.dT = TC_1103_1104.port_a.T - TC_1103_1104.port_b.T; TC_1103_1104.port_a.Q_flow = TC_1103_1104.Q_flow; TC_1103_1104.port_b.Q_flow = -TC_1103_1104.Q_flow; TC_1103_1149.Q_flow = TC_1103_1149.G * TC_1103_1149.dT; TC_1103_1149.dT = TC_1103_1149.port_a.T - TC_1103_1149.port_b.T; TC_1103_1149.port_a.Q_flow = TC_1103_1149.Q_flow; TC_1103_1149.port_b.Q_flow = -TC_1103_1149.Q_flow; TC_1103_1611.Q_flow = TC_1103_1611.G * TC_1103_1611.dT; TC_1103_1611.dT = TC_1103_1611.port_a.T - TC_1103_1611.port_b.T; TC_1103_1611.port_a.Q_flow = TC_1103_1611.Q_flow; TC_1103_1611.port_b.Q_flow = -TC_1103_1611.Q_flow; TC_1104_1105.Q_flow = TC_1104_1105.G * TC_1104_1105.dT; TC_1104_1105.dT = TC_1104_1105.port_a.T - TC_1104_1105.port_b.T; TC_1104_1105.port_a.Q_flow = TC_1104_1105.Q_flow; TC_1104_1105.port_b.Q_flow = -TC_1104_1105.Q_flow; TC_1104_1150.Q_flow = TC_1104_1150.G * TC_1104_1150.dT; TC_1104_1150.dT = TC_1104_1150.port_a.T - TC_1104_1150.port_b.T; TC_1104_1150.port_a.Q_flow = TC_1104_1150.Q_flow; TC_1104_1150.port_b.Q_flow = -TC_1104_1150.Q_flow; TC_1104_1612.Q_flow = TC_1104_1612.G * TC_1104_1612.dT; TC_1104_1612.dT = TC_1104_1612.port_a.T - TC_1104_1612.port_b.T; TC_1104_1612.port_a.Q_flow = TC_1104_1612.Q_flow; TC_1104_1612.port_b.Q_flow = -TC_1104_1612.Q_flow; TC_1105_1106.Q_flow = TC_1105_1106.G * TC_1105_1106.dT; TC_1105_1106.dT = TC_1105_1106.port_a.T - TC_1105_1106.port_b.T; TC_1105_1106.port_a.Q_flow = TC_1105_1106.Q_flow; TC_1105_1106.port_b.Q_flow = -TC_1105_1106.Q_flow; TC_1105_1151.Q_flow = TC_1105_1151.G * TC_1105_1151.dT; TC_1105_1151.dT = TC_1105_1151.port_a.T - TC_1105_1151.port_b.T; TC_1105_1151.port_a.Q_flow = TC_1105_1151.Q_flow; TC_1105_1151.port_b.Q_flow = -TC_1105_1151.Q_flow; TC_1105_1613.Q_flow = TC_1105_1613.G * TC_1105_1613.dT; TC_1105_1613.dT = TC_1105_1613.port_a.T - TC_1105_1613.port_b.T; TC_1105_1613.port_a.Q_flow = TC_1105_1613.Q_flow; TC_1105_1613.port_b.Q_flow = -TC_1105_1613.Q_flow; TC_1106_1107.Q_flow = TC_1106_1107.G * TC_1106_1107.dT; TC_1106_1107.dT = TC_1106_1107.port_a.T - TC_1106_1107.port_b.T; TC_1106_1107.port_a.Q_flow = TC_1106_1107.Q_flow; TC_1106_1107.port_b.Q_flow = -TC_1106_1107.Q_flow; TC_1106_1152.Q_flow = TC_1106_1152.G * TC_1106_1152.dT; TC_1106_1152.dT = TC_1106_1152.port_a.T - TC_1106_1152.port_b.T; TC_1106_1152.port_a.Q_flow = TC_1106_1152.Q_flow; TC_1106_1152.port_b.Q_flow = -TC_1106_1152.Q_flow; TC_1106_1614.Q_flow = TC_1106_1614.G * TC_1106_1614.dT; TC_1106_1614.dT = TC_1106_1614.port_a.T - TC_1106_1614.port_b.T; TC_1106_1614.port_a.Q_flow = TC_1106_1614.Q_flow; TC_1106_1614.port_b.Q_flow = -TC_1106_1614.Q_flow; TC_1107_1108.Q_flow = TC_1107_1108.G * TC_1107_1108.dT; TC_1107_1108.dT = TC_1107_1108.port_a.T - TC_1107_1108.port_b.T; TC_1107_1108.port_a.Q_flow = TC_1107_1108.Q_flow; TC_1107_1108.port_b.Q_flow = -TC_1107_1108.Q_flow; TC_1107_1153.Q_flow = TC_1107_1153.G * TC_1107_1153.dT; TC_1107_1153.dT = TC_1107_1153.port_a.T - TC_1107_1153.port_b.T; TC_1107_1153.port_a.Q_flow = TC_1107_1153.Q_flow; TC_1107_1153.port_b.Q_flow = -TC_1107_1153.Q_flow; TC_1107_1615.Q_flow = TC_1107_1615.G * TC_1107_1615.dT; TC_1107_1615.dT = TC_1107_1615.port_a.T - TC_1107_1615.port_b.T; TC_1107_1615.port_a.Q_flow = TC_1107_1615.Q_flow; TC_1107_1615.port_b.Q_flow = -TC_1107_1615.Q_flow; TC_1108_1109.Q_flow = TC_1108_1109.G * TC_1108_1109.dT; TC_1108_1109.dT = TC_1108_1109.port_a.T - TC_1108_1109.port_b.T; TC_1108_1109.port_a.Q_flow = TC_1108_1109.Q_flow; TC_1108_1109.port_b.Q_flow = -TC_1108_1109.Q_flow; TC_1108_1154.Q_flow = TC_1108_1154.G * TC_1108_1154.dT; TC_1108_1154.dT = TC_1108_1154.port_a.T - TC_1108_1154.port_b.T; TC_1108_1154.port_a.Q_flow = TC_1108_1154.Q_flow; TC_1108_1154.port_b.Q_flow = -TC_1108_1154.Q_flow; TC_1108_1616.Q_flow = TC_1108_1616.G * TC_1108_1616.dT; TC_1108_1616.dT = TC_1108_1616.port_a.T - TC_1108_1616.port_b.T; TC_1108_1616.port_a.Q_flow = TC_1108_1616.Q_flow; TC_1108_1616.port_b.Q_flow = -TC_1108_1616.Q_flow; TC_1109_1111.Q_flow = TC_1109_1111.G * TC_1109_1111.dT; TC_1109_1111.dT = TC_1109_1111.port_a.T - TC_1109_1111.port_b.T; TC_1109_1111.port_a.Q_flow = TC_1109_1111.Q_flow; TC_1109_1111.port_b.Q_flow = -TC_1109_1111.Q_flow; TC_1109_1155.Q_flow = TC_1109_1155.G * TC_1109_1155.dT; TC_1109_1155.dT = TC_1109_1155.port_a.T - TC_1109_1155.port_b.T; TC_1109_1155.port_a.Q_flow = TC_1109_1155.Q_flow; TC_1109_1155.port_b.Q_flow = -TC_1109_1155.Q_flow; TC_1110_1112.Q_flow = TC_1110_1112.G * TC_1110_1112.dT; TC_1110_1112.dT = TC_1110_1112.port_a.T - TC_1110_1112.port_b.T; TC_1110_1112.port_a.Q_flow = TC_1110_1112.Q_flow; TC_1110_1112.port_b.Q_flow = -TC_1110_1112.Q_flow; TC_1110_1156.Q_flow = TC_1110_1156.G * TC_1110_1156.dT; TC_1110_1156.dT = TC_1110_1156.port_a.T - TC_1110_1156.port_b.T; TC_1110_1156.port_a.Q_flow = TC_1110_1156.Q_flow; TC_1110_1156.port_b.Q_flow = -TC_1110_1156.Q_flow; TC_1110_1608.Q_flow = TC_1110_1608.G * TC_1110_1608.dT; TC_1110_1608.dT = TC_1110_1608.port_a.T - TC_1110_1608.port_b.T; TC_1110_1608.port_a.Q_flow = TC_1110_1608.Q_flow; TC_1110_1608.port_b.Q_flow = -TC_1110_1608.Q_flow; TC_1111_1113.Q_flow = TC_1111_1113.G * TC_1111_1113.dT; TC_1111_1113.dT = TC_1111_1113.port_a.T - TC_1111_1113.port_b.T; TC_1111_1113.port_a.Q_flow = TC_1111_1113.Q_flow; TC_1111_1113.port_b.Q_flow = -TC_1111_1113.Q_flow; TC_1111_1166.Q_flow = TC_1111_1166.G * TC_1111_1166.dT; TC_1111_1166.dT = TC_1111_1166.port_a.T - TC_1111_1166.port_b.T; TC_1111_1166.port_a.Q_flow = TC_1111_1166.Q_flow; TC_1111_1166.port_b.Q_flow = -TC_1111_1166.Q_flow; TC_1111_1616.Q_flow = TC_1111_1616.G * TC_1111_1616.dT; TC_1111_1616.dT = TC_1111_1616.port_a.T - TC_1111_1616.port_b.T; TC_1111_1616.port_a.Q_flow = TC_1111_1616.Q_flow; TC_1111_1616.port_b.Q_flow = -TC_1111_1616.Q_flow; TC_1112_1114.Q_flow = TC_1112_1114.G * TC_1112_1114.dT; TC_1112_1114.dT = TC_1112_1114.port_a.T - TC_1112_1114.port_b.T; TC_1112_1114.port_a.Q_flow = TC_1112_1114.Q_flow; TC_1112_1114.port_b.Q_flow = -TC_1112_1114.Q_flow; TC_1112_1167.Q_flow = TC_1112_1167.G * TC_1112_1167.dT; TC_1112_1167.dT = TC_1112_1167.port_a.T - TC_1112_1167.port_b.T; TC_1112_1167.port_a.Q_flow = TC_1112_1167.Q_flow; TC_1112_1167.port_b.Q_flow = -TC_1112_1167.Q_flow; TC_1112_1617.Q_flow = TC_1112_1617.G * TC_1112_1617.dT; TC_1112_1617.dT = TC_1112_1617.port_a.T - TC_1112_1617.port_b.T; TC_1112_1617.port_a.Q_flow = TC_1112_1617.Q_flow; TC_1112_1617.port_b.Q_flow = -TC_1112_1617.Q_flow; TC_1113_1115.Q_flow = TC_1113_1115.G * TC_1113_1115.dT; TC_1113_1115.dT = TC_1113_1115.port_a.T - TC_1113_1115.port_b.T; TC_1113_1115.port_a.Q_flow = TC_1113_1115.Q_flow; TC_1113_1115.port_b.Q_flow = -TC_1113_1115.Q_flow; TC_1113_1173.Q_flow = TC_1113_1173.G * TC_1113_1173.dT; TC_1113_1173.dT = TC_1113_1173.port_a.T - TC_1113_1173.port_b.T; TC_1113_1173.port_a.Q_flow = TC_1113_1173.Q_flow; TC_1113_1173.port_b.Q_flow = -TC_1113_1173.Q_flow; TC_1113_1625.Q_flow = TC_1113_1625.G * TC_1113_1625.dT; TC_1113_1625.dT = TC_1113_1625.port_a.T - TC_1113_1625.port_b.T; TC_1113_1625.port_a.Q_flow = TC_1113_1625.Q_flow; TC_1113_1625.port_b.Q_flow = -TC_1113_1625.Q_flow; TC_1114_1116.Q_flow = TC_1114_1116.G * TC_1114_1116.dT; TC_1114_1116.dT = TC_1114_1116.port_a.T - TC_1114_1116.port_b.T; TC_1114_1116.port_a.Q_flow = TC_1114_1116.Q_flow; TC_1114_1116.port_b.Q_flow = -TC_1114_1116.Q_flow; TC_1114_1174.Q_flow = TC_1114_1174.G * TC_1114_1174.dT; TC_1114_1174.dT = TC_1114_1174.port_a.T - TC_1114_1174.port_b.T; TC_1114_1174.port_a.Q_flow = TC_1114_1174.Q_flow; TC_1114_1174.port_b.Q_flow = -TC_1114_1174.Q_flow; TC_1114_1626.Q_flow = TC_1114_1626.G * TC_1114_1626.dT; TC_1114_1626.dT = TC_1114_1626.port_a.T - TC_1114_1626.port_b.T; TC_1114_1626.port_a.Q_flow = TC_1114_1626.Q_flow; TC_1114_1626.port_b.Q_flow = -TC_1114_1626.Q_flow; TC_1115_1117.Q_flow = TC_1115_1117.G * TC_1115_1117.dT; TC_1115_1117.dT = TC_1115_1117.port_a.T - TC_1115_1117.port_b.T; TC_1115_1117.port_a.Q_flow = TC_1115_1117.Q_flow; TC_1115_1117.port_b.Q_flow = -TC_1115_1117.Q_flow; TC_1115_1180.Q_flow = TC_1115_1180.G * TC_1115_1180.dT; TC_1115_1180.dT = TC_1115_1180.port_a.T - TC_1115_1180.port_b.T; TC_1115_1180.port_a.Q_flow = TC_1115_1180.Q_flow; TC_1115_1180.port_b.Q_flow = -TC_1115_1180.Q_flow; TC_1115_1634.Q_flow = TC_1115_1634.G * TC_1115_1634.dT; TC_1115_1634.dT = TC_1115_1634.port_a.T - TC_1115_1634.port_b.T; TC_1115_1634.port_a.Q_flow = TC_1115_1634.Q_flow; TC_1115_1634.port_b.Q_flow = -TC_1115_1634.Q_flow; TC_1116_1118.Q_flow = TC_1116_1118.G * TC_1116_1118.dT; TC_1116_1118.dT = TC_1116_1118.port_a.T - TC_1116_1118.port_b.T; TC_1116_1118.port_a.Q_flow = TC_1116_1118.Q_flow; TC_1116_1118.port_b.Q_flow = -TC_1116_1118.Q_flow; TC_1116_1181.Q_flow = TC_1116_1181.G * TC_1116_1181.dT; TC_1116_1181.dT = TC_1116_1181.port_a.T - TC_1116_1181.port_b.T; TC_1116_1181.port_a.Q_flow = TC_1116_1181.Q_flow; TC_1116_1181.port_b.Q_flow = -TC_1116_1181.Q_flow; TC_1116_1563.Q_flow = TC_1116_1563.G * TC_1116_1563.dT; TC_1116_1563.dT = TC_1116_1563.port_a.T - TC_1116_1563.port_b.T; TC_1116_1563.port_a.Q_flow = TC_1116_1563.Q_flow; TC_1116_1563.port_b.Q_flow = -TC_1116_1563.Q_flow; TC_1117_1119.Q_flow = TC_1117_1119.G * TC_1117_1119.dT; TC_1117_1119.dT = TC_1117_1119.port_a.T - TC_1117_1119.port_b.T; TC_1117_1119.port_a.Q_flow = TC_1117_1119.Q_flow; TC_1117_1119.port_b.Q_flow = -TC_1117_1119.Q_flow; TC_1117_1187.Q_flow = TC_1117_1187.G * TC_1117_1187.dT; TC_1117_1187.dT = TC_1117_1187.port_a.T - TC_1117_1187.port_b.T; TC_1117_1187.port_a.Q_flow = TC_1117_1187.Q_flow; TC_1117_1187.port_b.Q_flow = -TC_1117_1187.Q_flow; TC_1117_1571.Q_flow = TC_1117_1571.G * TC_1117_1571.dT; TC_1117_1571.dT = TC_1117_1571.port_a.T - TC_1117_1571.port_b.T; TC_1117_1571.port_a.Q_flow = TC_1117_1571.Q_flow; TC_1117_1571.port_b.Q_flow = -TC_1117_1571.Q_flow; TC_1118_1120.Q_flow = TC_1118_1120.G * TC_1118_1120.dT; TC_1118_1120.dT = TC_1118_1120.port_a.T - TC_1118_1120.port_b.T; TC_1118_1120.port_a.Q_flow = TC_1118_1120.Q_flow; TC_1118_1120.port_b.Q_flow = -TC_1118_1120.Q_flow; TC_1118_1188.Q_flow = TC_1118_1188.G * TC_1118_1188.dT; TC_1118_1188.dT = TC_1118_1188.port_a.T - TC_1118_1188.port_b.T; TC_1118_1188.port_a.Q_flow = TC_1118_1188.Q_flow; TC_1118_1188.port_b.Q_flow = -TC_1118_1188.Q_flow; TC_1118_1572.Q_flow = TC_1118_1572.G * TC_1118_1572.dT; TC_1118_1572.dT = TC_1118_1572.port_a.T - TC_1118_1572.port_b.T; TC_1118_1572.port_a.Q_flow = TC_1118_1572.Q_flow; TC_1118_1572.port_b.Q_flow = -TC_1118_1572.Q_flow; TC_1119_1121.Q_flow = TC_1119_1121.G * TC_1119_1121.dT; TC_1119_1121.dT = TC_1119_1121.port_a.T - TC_1119_1121.port_b.T; TC_1119_1121.port_a.Q_flow = TC_1119_1121.Q_flow; TC_1119_1121.port_b.Q_flow = -TC_1119_1121.Q_flow; TC_1119_1198.Q_flow = TC_1119_1198.G * TC_1119_1198.dT; TC_1119_1198.dT = TC_1119_1198.port_a.T - TC_1119_1198.port_b.T; TC_1119_1198.port_a.Q_flow = TC_1119_1198.Q_flow; TC_1119_1198.port_b.Q_flow = -TC_1119_1198.Q_flow; TC_1119_1580.Q_flow = TC_1119_1580.G * TC_1119_1580.dT; TC_1119_1580.dT = TC_1119_1580.port_a.T - TC_1119_1580.port_b.T; TC_1119_1580.port_a.Q_flow = TC_1119_1580.Q_flow; TC_1119_1580.port_b.Q_flow = -TC_1119_1580.Q_flow; TC_1120_1122.Q_flow = TC_1120_1122.G * TC_1120_1122.dT; TC_1120_1122.dT = TC_1120_1122.port_a.T - TC_1120_1122.port_b.T; TC_1120_1122.port_a.Q_flow = TC_1120_1122.Q_flow; TC_1120_1122.port_b.Q_flow = -TC_1120_1122.Q_flow; TC_1120_1199.Q_flow = TC_1120_1199.G * TC_1120_1199.dT; TC_1120_1199.dT = TC_1120_1199.port_a.T - TC_1120_1199.port_b.T; TC_1120_1199.port_a.Q_flow = TC_1120_1199.Q_flow; TC_1120_1199.port_b.Q_flow = -TC_1120_1199.Q_flow; TC_1120_1581.Q_flow = TC_1120_1581.G * TC_1120_1581.dT; TC_1120_1581.dT = TC_1120_1581.port_a.T - TC_1120_1581.port_b.T; TC_1120_1581.port_a.Q_flow = TC_1120_1581.Q_flow; TC_1120_1581.port_b.Q_flow = -TC_1120_1581.Q_flow; TC_1121_1123.Q_flow = TC_1121_1123.G * TC_1121_1123.dT; TC_1121_1123.dT = TC_1121_1123.port_a.T - TC_1121_1123.port_b.T; TC_1121_1123.port_a.Q_flow = TC_1121_1123.Q_flow; TC_1121_1123.port_b.Q_flow = -TC_1121_1123.Q_flow; TC_1121_1206.Q_flow = TC_1121_1206.G * TC_1121_1206.dT; TC_1121_1206.dT = TC_1121_1206.port_a.T - TC_1121_1206.port_b.T; TC_1121_1206.port_a.Q_flow = TC_1121_1206.Q_flow; TC_1121_1206.port_b.Q_flow = -TC_1121_1206.Q_flow; TC_1121_1589.Q_flow = TC_1121_1589.G * TC_1121_1589.dT; TC_1121_1589.dT = TC_1121_1589.port_a.T - TC_1121_1589.port_b.T; TC_1121_1589.port_a.Q_flow = TC_1121_1589.Q_flow; TC_1121_1589.port_b.Q_flow = -TC_1121_1589.Q_flow; TC_1122_1124.Q_flow = TC_1122_1124.G * TC_1122_1124.dT; TC_1122_1124.dT = TC_1122_1124.port_a.T - TC_1122_1124.port_b.T; TC_1122_1124.port_a.Q_flow = TC_1122_1124.Q_flow; TC_1122_1124.port_b.Q_flow = -TC_1122_1124.Q_flow; TC_1122_1207.Q_flow = TC_1122_1207.G * TC_1122_1207.dT; TC_1122_1207.dT = TC_1122_1207.port_a.T - TC_1122_1207.port_b.T; TC_1122_1207.port_a.Q_flow = TC_1122_1207.Q_flow; TC_1122_1207.port_b.Q_flow = -TC_1122_1207.Q_flow; TC_1122_1590.Q_flow = TC_1122_1590.G * TC_1122_1590.dT; TC_1122_1590.dT = TC_1122_1590.port_a.T - TC_1122_1590.port_b.T; TC_1122_1590.port_a.Q_flow = TC_1122_1590.Q_flow; TC_1122_1590.port_b.Q_flow = -TC_1122_1590.Q_flow; TC_1123_1125.Q_flow = TC_1123_1125.G * TC_1123_1125.dT; TC_1123_1125.dT = TC_1123_1125.port_a.T - TC_1123_1125.port_b.T; TC_1123_1125.port_a.Q_flow = TC_1123_1125.Q_flow; TC_1123_1125.port_b.Q_flow = -TC_1123_1125.Q_flow; TC_1123_1214.Q_flow = TC_1123_1214.G * TC_1123_1214.dT; TC_1123_1214.dT = TC_1123_1214.port_a.T - TC_1123_1214.port_b.T; TC_1123_1214.port_a.Q_flow = TC_1123_1214.Q_flow; TC_1123_1214.port_b.Q_flow = -TC_1123_1214.Q_flow; TC_1123_1598.Q_flow = TC_1123_1598.G * TC_1123_1598.dT; TC_1123_1598.dT = TC_1123_1598.port_a.T - TC_1123_1598.port_b.T; TC_1123_1598.port_a.Q_flow = TC_1123_1598.Q_flow; TC_1123_1598.port_b.Q_flow = -TC_1123_1598.Q_flow; TC_1124_1126.Q_flow = TC_1124_1126.G * TC_1124_1126.dT; TC_1124_1126.dT = TC_1124_1126.port_a.T - TC_1124_1126.port_b.T; TC_1124_1126.port_a.Q_flow = TC_1124_1126.Q_flow; TC_1124_1126.port_b.Q_flow = -TC_1124_1126.Q_flow; TC_1124_1215.Q_flow = TC_1124_1215.G * TC_1124_1215.dT; TC_1124_1215.dT = TC_1124_1215.port_a.T - TC_1124_1215.port_b.T; TC_1124_1215.port_a.Q_flow = TC_1124_1215.Q_flow; TC_1124_1215.port_b.Q_flow = -TC_1124_1215.Q_flow; TC_1124_1599.Q_flow = TC_1124_1599.G * TC_1124_1599.dT; TC_1124_1599.dT = TC_1124_1599.port_a.T - TC_1124_1599.port_b.T; TC_1124_1599.port_a.Q_flow = TC_1124_1599.Q_flow; TC_1124_1599.port_b.Q_flow = -TC_1124_1599.Q_flow; TC_1125_1127.Q_flow = TC_1125_1127.G * TC_1125_1127.dT; TC_1125_1127.dT = TC_1125_1127.port_a.T - TC_1125_1127.port_b.T; TC_1125_1127.port_a.Q_flow = TC_1125_1127.Q_flow; TC_1125_1127.port_b.Q_flow = -TC_1125_1127.Q_flow; TC_1125_1222.Q_flow = TC_1125_1222.G * TC_1125_1222.dT; TC_1125_1222.dT = TC_1125_1222.port_a.T - TC_1125_1222.port_b.T; TC_1125_1222.port_a.Q_flow = TC_1125_1222.Q_flow; TC_1125_1222.port_b.Q_flow = -TC_1125_1222.Q_flow; TC_1125_1607.Q_flow = TC_1125_1607.G * TC_1125_1607.dT; TC_1125_1607.dT = TC_1125_1607.port_a.T - TC_1125_1607.port_b.T; TC_1125_1607.port_a.Q_flow = TC_1125_1607.Q_flow; TC_1125_1607.port_b.Q_flow = -TC_1125_1607.Q_flow; TC_1126_1128.Q_flow = TC_1126_1128.G * TC_1126_1128.dT; TC_1126_1128.dT = TC_1126_1128.port_a.T - TC_1126_1128.port_b.T; TC_1126_1128.port_a.Q_flow = TC_1126_1128.Q_flow; TC_1126_1128.port_b.Q_flow = -TC_1126_1128.Q_flow; TC_1126_1223.Q_flow = TC_1126_1223.G * TC_1126_1223.dT; TC_1126_1223.dT = TC_1126_1223.port_a.T - TC_1126_1223.port_b.T; TC_1126_1223.port_a.Q_flow = TC_1126_1223.Q_flow; TC_1126_1223.port_b.Q_flow = -TC_1126_1223.Q_flow; TC_1126_1527.Q_flow = TC_1126_1527.G * TC_1126_1527.dT; TC_1126_1527.dT = TC_1126_1527.port_a.T - TC_1126_1527.port_b.T; TC_1126_1527.port_a.Q_flow = TC_1126_1527.Q_flow; TC_1126_1527.port_b.Q_flow = -TC_1126_1527.Q_flow; TC_1127_1129.Q_flow = TC_1127_1129.G * TC_1127_1129.dT; TC_1127_1129.dT = TC_1127_1129.port_a.T - TC_1127_1129.port_b.T; TC_1127_1129.port_a.Q_flow = TC_1127_1129.Q_flow; TC_1127_1129.port_b.Q_flow = -TC_1127_1129.Q_flow; TC_1127_1230.Q_flow = TC_1127_1230.G * TC_1127_1230.dT; TC_1127_1230.dT = TC_1127_1230.port_a.T - TC_1127_1230.port_b.T; TC_1127_1230.port_a.Q_flow = TC_1127_1230.Q_flow; TC_1127_1230.port_b.Q_flow = -TC_1127_1230.Q_flow; TC_1127_1535.Q_flow = TC_1127_1535.G * TC_1127_1535.dT; TC_1127_1535.dT = TC_1127_1535.port_a.T - TC_1127_1535.port_b.T; TC_1127_1535.port_a.Q_flow = TC_1127_1535.Q_flow; TC_1127_1535.port_b.Q_flow = -TC_1127_1535.Q_flow; TC_1128_1130.Q_flow = TC_1128_1130.G * TC_1128_1130.dT; TC_1128_1130.dT = TC_1128_1130.port_a.T - TC_1128_1130.port_b.T; TC_1128_1130.port_a.Q_flow = TC_1128_1130.Q_flow; TC_1128_1130.port_b.Q_flow = -TC_1128_1130.Q_flow; TC_1128_1231.Q_flow = TC_1128_1231.G * TC_1128_1231.dT; TC_1128_1231.dT = TC_1128_1231.port_a.T - TC_1128_1231.port_b.T; TC_1128_1231.port_a.Q_flow = TC_1128_1231.Q_flow; TC_1128_1231.port_b.Q_flow = -TC_1128_1231.Q_flow; TC_1128_1536.Q_flow = TC_1128_1536.G * TC_1128_1536.dT; TC_1128_1536.dT = TC_1128_1536.port_a.T - TC_1128_1536.port_b.T; TC_1128_1536.port_a.Q_flow = TC_1128_1536.Q_flow; TC_1128_1536.port_b.Q_flow = -TC_1128_1536.Q_flow; TC_1129_1131.Q_flow = TC_1129_1131.G * TC_1129_1131.dT; TC_1129_1131.dT = TC_1129_1131.port_a.T - TC_1129_1131.port_b.T; TC_1129_1131.port_a.Q_flow = TC_1129_1131.Q_flow; TC_1129_1131.port_b.Q_flow = -TC_1129_1131.Q_flow; TC_1129_1238.Q_flow = TC_1129_1238.G * TC_1129_1238.dT; TC_1129_1238.dT = TC_1129_1238.port_a.T - TC_1129_1238.port_b.T; TC_1129_1238.port_a.Q_flow = TC_1129_1238.Q_flow; TC_1129_1238.port_b.Q_flow = -TC_1129_1238.Q_flow; TC_1129_1544.Q_flow = TC_1129_1544.G * TC_1129_1544.dT; TC_1129_1544.dT = TC_1129_1544.port_a.T - TC_1129_1544.port_b.T; TC_1129_1544.port_a.Q_flow = TC_1129_1544.Q_flow; TC_1129_1544.port_b.Q_flow = -TC_1129_1544.Q_flow; TC_1130_1132.Q_flow = TC_1130_1132.G * TC_1130_1132.dT; TC_1130_1132.dT = TC_1130_1132.port_a.T - TC_1130_1132.port_b.T; TC_1130_1132.port_a.Q_flow = TC_1130_1132.Q_flow; TC_1130_1132.port_b.Q_flow = -TC_1130_1132.Q_flow; TC_1130_1239.Q_flow = TC_1130_1239.G * TC_1130_1239.dT; TC_1130_1239.dT = TC_1130_1239.port_a.T - TC_1130_1239.port_b.T; TC_1130_1239.port_a.Q_flow = TC_1130_1239.Q_flow; TC_1130_1239.port_b.Q_flow = -TC_1130_1239.Q_flow; TC_1130_1545.Q_flow = TC_1130_1545.G * TC_1130_1545.dT; TC_1130_1545.dT = TC_1130_1545.port_a.T - TC_1130_1545.port_b.T; TC_1130_1545.port_a.Q_flow = TC_1130_1545.Q_flow; TC_1130_1545.port_b.Q_flow = -TC_1130_1545.Q_flow; TC_1131_1133.Q_flow = TC_1131_1133.G * TC_1131_1133.dT; TC_1131_1133.dT = TC_1131_1133.port_a.T - TC_1131_1133.port_b.T; TC_1131_1133.port_a.Q_flow = TC_1131_1133.Q_flow; TC_1131_1133.port_b.Q_flow = -TC_1131_1133.Q_flow; TC_1131_1246.Q_flow = TC_1131_1246.G * TC_1131_1246.dT; TC_1131_1246.dT = TC_1131_1246.port_a.T - TC_1131_1246.port_b.T; TC_1131_1246.port_a.Q_flow = TC_1131_1246.Q_flow; TC_1131_1246.port_b.Q_flow = -TC_1131_1246.Q_flow; TC_1131_1553.Q_flow = TC_1131_1553.G * TC_1131_1553.dT; TC_1131_1553.dT = TC_1131_1553.port_a.T - TC_1131_1553.port_b.T; TC_1131_1553.port_a.Q_flow = TC_1131_1553.Q_flow; TC_1131_1553.port_b.Q_flow = -TC_1131_1553.Q_flow; TC_1132_1134.Q_flow = TC_1132_1134.G * TC_1132_1134.dT; TC_1132_1134.dT = TC_1132_1134.port_a.T - TC_1132_1134.port_b.T; TC_1132_1134.port_a.Q_flow = TC_1132_1134.Q_flow; TC_1132_1134.port_b.Q_flow = -TC_1132_1134.Q_flow; TC_1132_1247.Q_flow = TC_1132_1247.G * TC_1132_1247.dT; TC_1132_1247.dT = TC_1132_1247.port_a.T - TC_1132_1247.port_b.T; TC_1132_1247.port_a.Q_flow = TC_1132_1247.Q_flow; TC_1132_1247.port_b.Q_flow = -TC_1132_1247.Q_flow; TC_1132_1554.Q_flow = TC_1132_1554.G * TC_1132_1554.dT; TC_1132_1554.dT = TC_1132_1554.port_a.T - TC_1132_1554.port_b.T; TC_1132_1554.port_a.Q_flow = TC_1132_1554.Q_flow; TC_1132_1554.port_b.Q_flow = -TC_1132_1554.Q_flow; TC_1133_1144.Q_flow = TC_1133_1144.G * TC_1133_1144.dT; TC_1133_1144.dT = TC_1133_1144.port_a.T - TC_1133_1144.port_b.T; TC_1133_1144.port_a.Q_flow = TC_1133_1144.Q_flow; TC_1133_1144.port_b.Q_flow = -TC_1133_1144.Q_flow; TC_1133_1257.Q_flow = TC_1133_1257.G * TC_1133_1257.dT; TC_1133_1257.dT = TC_1133_1257.port_a.T - TC_1133_1257.port_b.T; TC_1133_1257.port_a.Q_flow = TC_1133_1257.Q_flow; TC_1133_1257.port_b.Q_flow = -TC_1133_1257.Q_flow; TC_1133_1562.Q_flow = TC_1133_1562.G * TC_1133_1562.dT; TC_1133_1562.dT = TC_1133_1562.port_a.T - TC_1133_1562.port_b.T; TC_1133_1562.port_a.Q_flow = TC_1133_1562.Q_flow; TC_1133_1562.port_b.Q_flow = -TC_1133_1562.Q_flow; TC_1134_1135.Q_flow = TC_1134_1135.G * TC_1134_1135.dT; TC_1134_1135.dT = TC_1134_1135.port_a.T - TC_1134_1135.port_b.T; TC_1134_1135.port_a.Q_flow = TC_1134_1135.Q_flow; TC_1134_1135.port_b.Q_flow = -TC_1134_1135.Q_flow; TC_1134_1258.Q_flow = TC_1134_1258.G * TC_1134_1258.dT; TC_1134_1258.dT = TC_1134_1258.port_a.T - TC_1134_1258.port_b.T; TC_1134_1258.port_a.Q_flow = TC_1134_1258.Q_flow; TC_1134_1258.port_b.Q_flow = -TC_1134_1258.Q_flow; TC_1135_1136.Q_flow = TC_1135_1136.G * TC_1135_1136.dT; TC_1135_1136.dT = TC_1135_1136.port_a.T - TC_1135_1136.port_b.T; TC_1135_1136.port_a.Q_flow = TC_1135_1136.Q_flow; TC_1135_1136.port_b.Q_flow = -TC_1135_1136.Q_flow; TC_1135_1259.Q_flow = TC_1135_1259.G * TC_1135_1259.dT; TC_1135_1259.dT = TC_1135_1259.port_a.T - TC_1135_1259.port_b.T; TC_1135_1259.port_a.Q_flow = TC_1135_1259.Q_flow; TC_1135_1259.port_b.Q_flow = -TC_1135_1259.Q_flow; TC_1135_1554.Q_flow = TC_1135_1554.G * TC_1135_1554.dT; TC_1135_1554.dT = TC_1135_1554.port_a.T - TC_1135_1554.port_b.T; TC_1135_1554.port_a.Q_flow = TC_1135_1554.Q_flow; TC_1135_1554.port_b.Q_flow = -TC_1135_1554.Q_flow; TC_1136_1137.Q_flow = TC_1136_1137.G * TC_1136_1137.dT; TC_1136_1137.dT = TC_1136_1137.port_a.T - TC_1136_1137.port_b.T; TC_1136_1137.port_a.Q_flow = TC_1136_1137.Q_flow; TC_1136_1137.port_b.Q_flow = -TC_1136_1137.Q_flow; TC_1136_1260.Q_flow = TC_1136_1260.G * TC_1136_1260.dT; TC_1136_1260.dT = TC_1136_1260.port_a.T - TC_1136_1260.port_b.T; TC_1136_1260.port_a.Q_flow = TC_1136_1260.Q_flow; TC_1136_1260.port_b.Q_flow = -TC_1136_1260.Q_flow; TC_1136_1555.Q_flow = TC_1136_1555.G * TC_1136_1555.dT; TC_1136_1555.dT = TC_1136_1555.port_a.T - TC_1136_1555.port_b.T; TC_1136_1555.port_a.Q_flow = TC_1136_1555.Q_flow; TC_1136_1555.port_b.Q_flow = -TC_1136_1555.Q_flow; TC_1137_1138.Q_flow = TC_1137_1138.G * TC_1137_1138.dT; TC_1137_1138.dT = TC_1137_1138.port_a.T - TC_1137_1138.port_b.T; TC_1137_1138.port_a.Q_flow = TC_1137_1138.Q_flow; TC_1137_1138.port_b.Q_flow = -TC_1137_1138.Q_flow; TC_1137_1261.Q_flow = TC_1137_1261.G * TC_1137_1261.dT; TC_1137_1261.dT = TC_1137_1261.port_a.T - TC_1137_1261.port_b.T; TC_1137_1261.port_a.Q_flow = TC_1137_1261.Q_flow; TC_1137_1261.port_b.Q_flow = -TC_1137_1261.Q_flow; TC_1137_1556.Q_flow = TC_1137_1556.G * TC_1137_1556.dT; TC_1137_1556.dT = TC_1137_1556.port_a.T - TC_1137_1556.port_b.T; TC_1137_1556.port_a.Q_flow = TC_1137_1556.Q_flow; TC_1137_1556.port_b.Q_flow = -TC_1137_1556.Q_flow; TC_1138_1139.Q_flow = TC_1138_1139.G * TC_1138_1139.dT; TC_1138_1139.dT = TC_1138_1139.port_a.T - TC_1138_1139.port_b.T; TC_1138_1139.port_a.Q_flow = TC_1138_1139.Q_flow; TC_1138_1139.port_b.Q_flow = -TC_1138_1139.Q_flow; TC_1138_1262.Q_flow = TC_1138_1262.G * TC_1138_1262.dT; TC_1138_1262.dT = TC_1138_1262.port_a.T - TC_1138_1262.port_b.T; TC_1138_1262.port_a.Q_flow = TC_1138_1262.Q_flow; TC_1138_1262.port_b.Q_flow = -TC_1138_1262.Q_flow; TC_1138_1557.Q_flow = TC_1138_1557.G * TC_1138_1557.dT; TC_1138_1557.dT = TC_1138_1557.port_a.T - TC_1138_1557.port_b.T; TC_1138_1557.port_a.Q_flow = TC_1138_1557.Q_flow; TC_1138_1557.port_b.Q_flow = -TC_1138_1557.Q_flow; TC_1139_1140.Q_flow = TC_1139_1140.G * TC_1139_1140.dT; TC_1139_1140.dT = TC_1139_1140.port_a.T - TC_1139_1140.port_b.T; TC_1139_1140.port_a.Q_flow = TC_1139_1140.Q_flow; TC_1139_1140.port_b.Q_flow = -TC_1139_1140.Q_flow; TC_1139_1263.Q_flow = TC_1139_1263.G * TC_1139_1263.dT; TC_1139_1263.dT = TC_1139_1263.port_a.T - TC_1139_1263.port_b.T; TC_1139_1263.port_a.Q_flow = TC_1139_1263.Q_flow; TC_1139_1263.port_b.Q_flow = -TC_1139_1263.Q_flow; TC_1139_1558.Q_flow = TC_1139_1558.G * TC_1139_1558.dT; TC_1139_1558.dT = TC_1139_1558.port_a.T - TC_1139_1558.port_b.T; TC_1139_1558.port_a.Q_flow = TC_1139_1558.Q_flow; TC_1139_1558.port_b.Q_flow = -TC_1139_1558.Q_flow; TC_1140_1141.Q_flow = TC_1140_1141.G * TC_1140_1141.dT; TC_1140_1141.dT = TC_1140_1141.port_a.T - TC_1140_1141.port_b.T; TC_1140_1141.port_a.Q_flow = TC_1140_1141.Q_flow; TC_1140_1141.port_b.Q_flow = -TC_1140_1141.Q_flow; TC_1140_1264.Q_flow = TC_1140_1264.G * TC_1140_1264.dT; TC_1140_1264.dT = TC_1140_1264.port_a.T - TC_1140_1264.port_b.T; TC_1140_1264.port_a.Q_flow = TC_1140_1264.Q_flow; TC_1140_1264.port_b.Q_flow = -TC_1140_1264.Q_flow; TC_1140_1559.Q_flow = TC_1140_1559.G * TC_1140_1559.dT; TC_1140_1559.dT = TC_1140_1559.port_a.T - TC_1140_1559.port_b.T; TC_1140_1559.port_a.Q_flow = TC_1140_1559.Q_flow; TC_1140_1559.port_b.Q_flow = -TC_1140_1559.Q_flow; TC_1141_1142.Q_flow = TC_1141_1142.G * TC_1141_1142.dT; TC_1141_1142.dT = TC_1141_1142.port_a.T - TC_1141_1142.port_b.T; TC_1141_1142.port_a.Q_flow = TC_1141_1142.Q_flow; TC_1141_1142.port_b.Q_flow = -TC_1141_1142.Q_flow; TC_1141_1265.Q_flow = TC_1141_1265.G * TC_1141_1265.dT; TC_1141_1265.dT = TC_1141_1265.port_a.T - TC_1141_1265.port_b.T; TC_1141_1265.port_a.Q_flow = TC_1141_1265.Q_flow; TC_1141_1265.port_b.Q_flow = -TC_1141_1265.Q_flow; TC_1141_1560.Q_flow = TC_1141_1560.G * TC_1141_1560.dT; TC_1141_1560.dT = TC_1141_1560.port_a.T - TC_1141_1560.port_b.T; TC_1141_1560.port_a.Q_flow = TC_1141_1560.Q_flow; TC_1141_1560.port_b.Q_flow = -TC_1141_1560.Q_flow; TC_1142_1143.Q_flow = TC_1142_1143.G * TC_1142_1143.dT; TC_1142_1143.dT = TC_1142_1143.port_a.T - TC_1142_1143.port_b.T; TC_1142_1143.port_a.Q_flow = TC_1142_1143.Q_flow; TC_1142_1143.port_b.Q_flow = -TC_1142_1143.Q_flow; TC_1142_1266.Q_flow = TC_1142_1266.G * TC_1142_1266.dT; TC_1142_1266.dT = TC_1142_1266.port_a.T - TC_1142_1266.port_b.T; TC_1142_1266.port_a.Q_flow = TC_1142_1266.Q_flow; TC_1142_1266.port_b.Q_flow = -TC_1142_1266.Q_flow; TC_1142_1561.Q_flow = TC_1142_1561.G * TC_1142_1561.dT; TC_1142_1561.dT = TC_1142_1561.port_a.T - TC_1142_1561.port_b.T; TC_1142_1561.port_a.Q_flow = TC_1142_1561.Q_flow; TC_1142_1561.port_b.Q_flow = -TC_1142_1561.Q_flow; TC_1143_1144.Q_flow = TC_1143_1144.G * TC_1143_1144.dT; TC_1143_1144.dT = TC_1143_1144.port_a.T - TC_1143_1144.port_b.T; TC_1143_1144.port_a.Q_flow = TC_1143_1144.Q_flow; TC_1143_1144.port_b.Q_flow = -TC_1143_1144.Q_flow; TC_1143_1267.Q_flow = TC_1143_1267.G * TC_1143_1267.dT; TC_1143_1267.dT = TC_1143_1267.port_a.T - TC_1143_1267.port_b.T; TC_1143_1267.port_a.Q_flow = TC_1143_1267.Q_flow; TC_1143_1267.port_b.Q_flow = -TC_1143_1267.Q_flow; TC_1143_1562.Q_flow = TC_1143_1562.G * TC_1143_1562.dT; TC_1143_1562.dT = TC_1143_1562.port_a.T - TC_1143_1562.port_b.T; TC_1143_1562.port_a.Q_flow = TC_1143_1562.Q_flow; TC_1143_1562.port_b.Q_flow = -TC_1143_1562.Q_flow; TC_1144_1268.Q_flow = TC_1144_1268.G * TC_1144_1268.dT; TC_1144_1268.dT = TC_1144_1268.port_a.T - TC_1144_1268.port_b.T; TC_1144_1268.port_a.Q_flow = TC_1144_1268.Q_flow; TC_1144_1268.port_b.Q_flow = -TC_1144_1268.Q_flow; TC_1145_1146.Q_flow = TC_1145_1146.G * TC_1145_1146.dT; TC_1145_1146.dT = TC_1145_1146.port_a.T - TC_1145_1146.port_b.T; TC_1145_1146.port_a.Q_flow = TC_1145_1146.Q_flow; TC_1145_1146.port_b.Q_flow = -TC_1145_1146.Q_flow; TC_1145_1156.Q_flow = TC_1145_1156.G * TC_1145_1156.dT; TC_1145_1156.dT = TC_1145_1156.port_a.T - TC_1145_1156.port_b.T; TC_1145_1156.port_a.Q_flow = TC_1145_1156.Q_flow; TC_1145_1156.port_b.Q_flow = -TC_1145_1156.Q_flow; TC_1145_1269.Q_flow = TC_1145_1269.G * TC_1145_1269.dT; TC_1145_1269.dT = TC_1145_1269.port_a.T - TC_1145_1269.port_b.T; TC_1145_1269.port_a.Q_flow = TC_1145_1269.Q_flow; TC_1145_1269.port_b.Q_flow = -TC_1145_1269.Q_flow; TC_1146_1147.Q_flow = TC_1146_1147.G * TC_1146_1147.dT; TC_1146_1147.dT = TC_1146_1147.port_a.T - TC_1146_1147.port_b.T; TC_1146_1147.port_a.Q_flow = TC_1146_1147.Q_flow; TC_1146_1147.port_b.Q_flow = -TC_1146_1147.Q_flow; TC_1146_1157.Q_flow = TC_1146_1157.G * TC_1146_1157.dT; TC_1146_1157.dT = TC_1146_1157.port_a.T - TC_1146_1157.port_b.T; TC_1146_1157.port_a.Q_flow = TC_1146_1157.Q_flow; TC_1146_1157.port_b.Q_flow = -TC_1146_1157.Q_flow; TC_1146_1270.Q_flow = TC_1146_1270.G * TC_1146_1270.dT; TC_1146_1270.dT = TC_1146_1270.port_a.T - TC_1146_1270.port_b.T; TC_1146_1270.port_a.Q_flow = TC_1146_1270.Q_flow; TC_1146_1270.port_b.Q_flow = -TC_1146_1270.Q_flow; TC_1147_1148.Q_flow = TC_1147_1148.G * TC_1147_1148.dT; TC_1147_1148.dT = TC_1147_1148.port_a.T - TC_1147_1148.port_b.T; TC_1147_1148.port_a.Q_flow = TC_1147_1148.Q_flow; TC_1147_1148.port_b.Q_flow = -TC_1147_1148.Q_flow; TC_1147_1158.Q_flow = TC_1147_1158.G * TC_1147_1158.dT; TC_1147_1158.dT = TC_1147_1158.port_a.T - TC_1147_1158.port_b.T; TC_1147_1158.port_a.Q_flow = TC_1147_1158.Q_flow; TC_1147_1158.port_b.Q_flow = -TC_1147_1158.Q_flow; TC_1147_1271.Q_flow = TC_1147_1271.G * TC_1147_1271.dT; TC_1147_1271.dT = TC_1147_1271.port_a.T - TC_1147_1271.port_b.T; TC_1147_1271.port_a.Q_flow = TC_1147_1271.Q_flow; TC_1147_1271.port_b.Q_flow = -TC_1147_1271.Q_flow; TC_1148_1149.Q_flow = TC_1148_1149.G * TC_1148_1149.dT; TC_1148_1149.dT = TC_1148_1149.port_a.T - TC_1148_1149.port_b.T; TC_1148_1149.port_a.Q_flow = TC_1148_1149.Q_flow; TC_1148_1149.port_b.Q_flow = -TC_1148_1149.Q_flow; TC_1148_1159.Q_flow = TC_1148_1159.G * TC_1148_1159.dT; TC_1148_1159.dT = TC_1148_1159.port_a.T - TC_1148_1159.port_b.T; TC_1148_1159.port_a.Q_flow = TC_1148_1159.Q_flow; TC_1148_1159.port_b.Q_flow = -TC_1148_1159.Q_flow; TC_1148_1272.Q_flow = TC_1148_1272.G * TC_1148_1272.dT; TC_1148_1272.dT = TC_1148_1272.port_a.T - TC_1148_1272.port_b.T; TC_1148_1272.port_a.Q_flow = TC_1148_1272.Q_flow; TC_1148_1272.port_b.Q_flow = -TC_1148_1272.Q_flow; TC_1149_1150.Q_flow = TC_1149_1150.G * TC_1149_1150.dT; TC_1149_1150.dT = TC_1149_1150.port_a.T - TC_1149_1150.port_b.T; TC_1149_1150.port_a.Q_flow = TC_1149_1150.Q_flow; TC_1149_1150.port_b.Q_flow = -TC_1149_1150.Q_flow; TC_1149_1160.Q_flow = TC_1149_1160.G * TC_1149_1160.dT; TC_1149_1160.dT = TC_1149_1160.port_a.T - TC_1149_1160.port_b.T; TC_1149_1160.port_a.Q_flow = TC_1149_1160.Q_flow; TC_1149_1160.port_b.Q_flow = -TC_1149_1160.Q_flow; TC_1149_1273.Q_flow = TC_1149_1273.G * TC_1149_1273.dT; TC_1149_1273.dT = TC_1149_1273.port_a.T - TC_1149_1273.port_b.T; TC_1149_1273.port_a.Q_flow = TC_1149_1273.Q_flow; TC_1149_1273.port_b.Q_flow = -TC_1149_1273.Q_flow; TC_1150_1151.Q_flow = TC_1150_1151.G * TC_1150_1151.dT; TC_1150_1151.dT = TC_1150_1151.port_a.T - TC_1150_1151.port_b.T; TC_1150_1151.port_a.Q_flow = TC_1150_1151.Q_flow; TC_1150_1151.port_b.Q_flow = -TC_1150_1151.Q_flow; TC_1150_1161.Q_flow = TC_1150_1161.G * TC_1150_1161.dT; TC_1150_1161.dT = TC_1150_1161.port_a.T - TC_1150_1161.port_b.T; TC_1150_1161.port_a.Q_flow = TC_1150_1161.Q_flow; TC_1150_1161.port_b.Q_flow = -TC_1150_1161.Q_flow; TC_1150_1274.Q_flow = TC_1150_1274.G * TC_1150_1274.dT; TC_1150_1274.dT = TC_1150_1274.port_a.T - TC_1150_1274.port_b.T; TC_1150_1274.port_a.Q_flow = TC_1150_1274.Q_flow; TC_1150_1274.port_b.Q_flow = -TC_1150_1274.Q_flow; TC_1151_1152.Q_flow = TC_1151_1152.G * TC_1151_1152.dT; TC_1151_1152.dT = TC_1151_1152.port_a.T - TC_1151_1152.port_b.T; TC_1151_1152.port_a.Q_flow = TC_1151_1152.Q_flow; TC_1151_1152.port_b.Q_flow = -TC_1151_1152.Q_flow; TC_1151_1162.Q_flow = TC_1151_1162.G * TC_1151_1162.dT; TC_1151_1162.dT = TC_1151_1162.port_a.T - TC_1151_1162.port_b.T; TC_1151_1162.port_a.Q_flow = TC_1151_1162.Q_flow; TC_1151_1162.port_b.Q_flow = -TC_1151_1162.Q_flow; TC_1151_1275.Q_flow = TC_1151_1275.G * TC_1151_1275.dT; TC_1151_1275.dT = TC_1151_1275.port_a.T - TC_1151_1275.port_b.T; TC_1151_1275.port_a.Q_flow = TC_1151_1275.Q_flow; TC_1151_1275.port_b.Q_flow = -TC_1151_1275.Q_flow; TC_1152_1153.Q_flow = TC_1152_1153.G * TC_1152_1153.dT; TC_1152_1153.dT = TC_1152_1153.port_a.T - TC_1152_1153.port_b.T; TC_1152_1153.port_a.Q_flow = TC_1152_1153.Q_flow; TC_1152_1153.port_b.Q_flow = -TC_1152_1153.Q_flow; TC_1152_1163.Q_flow = TC_1152_1163.G * TC_1152_1163.dT; TC_1152_1163.dT = TC_1152_1163.port_a.T - TC_1152_1163.port_b.T; TC_1152_1163.port_a.Q_flow = TC_1152_1163.Q_flow; TC_1152_1163.port_b.Q_flow = -TC_1152_1163.Q_flow; TC_1152_1276.Q_flow = TC_1152_1276.G * TC_1152_1276.dT; TC_1152_1276.dT = TC_1152_1276.port_a.T - TC_1152_1276.port_b.T; TC_1152_1276.port_a.Q_flow = TC_1152_1276.Q_flow; TC_1152_1276.port_b.Q_flow = -TC_1152_1276.Q_flow; TC_1153_1154.Q_flow = TC_1153_1154.G * TC_1153_1154.dT; TC_1153_1154.dT = TC_1153_1154.port_a.T - TC_1153_1154.port_b.T; TC_1153_1154.port_a.Q_flow = TC_1153_1154.Q_flow; TC_1153_1154.port_b.Q_flow = -TC_1153_1154.Q_flow; TC_1153_1164.Q_flow = TC_1153_1164.G * TC_1153_1164.dT; TC_1153_1164.dT = TC_1153_1164.port_a.T - TC_1153_1164.port_b.T; TC_1153_1164.port_a.Q_flow = TC_1153_1164.Q_flow; TC_1153_1164.port_b.Q_flow = -TC_1153_1164.Q_flow; TC_1153_1277.Q_flow = TC_1153_1277.G * TC_1153_1277.dT; TC_1153_1277.dT = TC_1153_1277.port_a.T - TC_1153_1277.port_b.T; TC_1153_1277.port_a.Q_flow = TC_1153_1277.Q_flow; TC_1153_1277.port_b.Q_flow = -TC_1153_1277.Q_flow; TC_1154_1155.Q_flow = TC_1154_1155.G * TC_1154_1155.dT; TC_1154_1155.dT = TC_1154_1155.port_a.T - TC_1154_1155.port_b.T; TC_1154_1155.port_a.Q_flow = TC_1154_1155.Q_flow; TC_1154_1155.port_b.Q_flow = -TC_1154_1155.Q_flow; TC_1154_1165.Q_flow = TC_1154_1165.G * TC_1154_1165.dT; TC_1154_1165.dT = TC_1154_1165.port_a.T - TC_1154_1165.port_b.T; TC_1154_1165.port_a.Q_flow = TC_1154_1165.Q_flow; TC_1154_1165.port_b.Q_flow = -TC_1154_1165.Q_flow; TC_1154_1278.Q_flow = TC_1154_1278.G * TC_1154_1278.dT; TC_1154_1278.dT = TC_1154_1278.port_a.T - TC_1154_1278.port_b.T; TC_1154_1278.port_a.Q_flow = TC_1154_1278.Q_flow; TC_1154_1278.port_b.Q_flow = -TC_1154_1278.Q_flow; TC_1155_1166.Q_flow = TC_1155_1166.G * TC_1155_1166.dT; TC_1155_1166.dT = TC_1155_1166.port_a.T - TC_1155_1166.port_b.T; TC_1155_1166.port_a.Q_flow = TC_1155_1166.Q_flow; TC_1155_1166.port_b.Q_flow = -TC_1155_1166.Q_flow; TC_1155_1279.Q_flow = TC_1155_1279.G * TC_1155_1279.dT; TC_1155_1279.dT = TC_1155_1279.port_a.T - TC_1155_1279.port_b.T; TC_1155_1279.port_a.Q_flow = TC_1155_1279.Q_flow; TC_1155_1279.port_b.Q_flow = -TC_1155_1279.Q_flow; TC_1156_1157.Q_flow = TC_1156_1157.G * TC_1156_1157.dT; TC_1156_1157.dT = TC_1156_1157.port_a.T - TC_1156_1157.port_b.T; TC_1156_1157.port_a.Q_flow = TC_1156_1157.Q_flow; TC_1156_1157.port_b.Q_flow = -TC_1156_1157.Q_flow; TC_1156_1167.Q_flow = TC_1156_1167.G * TC_1156_1167.dT; TC_1156_1167.dT = TC_1156_1167.port_a.T - TC_1156_1167.port_b.T; TC_1156_1167.port_a.Q_flow = TC_1156_1167.Q_flow; TC_1156_1167.port_b.Q_flow = -TC_1156_1167.Q_flow; TC_1156_1280.Q_flow = TC_1156_1280.G * TC_1156_1280.dT; TC_1156_1280.dT = TC_1156_1280.port_a.T - TC_1156_1280.port_b.T; TC_1156_1280.port_a.Q_flow = TC_1156_1280.Q_flow; TC_1156_1280.port_b.Q_flow = -TC_1156_1280.Q_flow; TC_1157_1158.Q_flow = TC_1157_1158.G * TC_1157_1158.dT; TC_1157_1158.dT = TC_1157_1158.port_a.T - TC_1157_1158.port_b.T; TC_1157_1158.port_a.Q_flow = TC_1157_1158.Q_flow; TC_1157_1158.port_b.Q_flow = -TC_1157_1158.Q_flow; TC_1157_1168.Q_flow = TC_1157_1168.G * TC_1157_1168.dT; TC_1157_1168.dT = TC_1157_1168.port_a.T - TC_1157_1168.port_b.T; TC_1157_1168.port_a.Q_flow = TC_1157_1168.Q_flow; TC_1157_1168.port_b.Q_flow = -TC_1157_1168.Q_flow; TC_1157_1281.Q_flow = TC_1157_1281.G * TC_1157_1281.dT; TC_1157_1281.dT = TC_1157_1281.port_a.T - TC_1157_1281.port_b.T; TC_1157_1281.port_a.Q_flow = TC_1157_1281.Q_flow; TC_1157_1281.port_b.Q_flow = -TC_1157_1281.Q_flow; TC_1157_1608.Q_flow = TC_1157_1608.G * TC_1157_1608.dT; TC_1157_1608.dT = TC_1157_1608.port_a.T - TC_1157_1608.port_b.T; TC_1157_1608.port_a.Q_flow = TC_1157_1608.Q_flow; TC_1157_1608.port_b.Q_flow = -TC_1157_1608.Q_flow; TC_1158_1159.Q_flow = TC_1158_1159.G * TC_1158_1159.dT; TC_1158_1159.dT = TC_1158_1159.port_a.T - TC_1158_1159.port_b.T; TC_1158_1159.port_a.Q_flow = TC_1158_1159.Q_flow; TC_1158_1159.port_b.Q_flow = -TC_1158_1159.Q_flow; TC_1158_1282.Q_flow = TC_1158_1282.G * TC_1158_1282.dT; TC_1158_1282.dT = TC_1158_1282.port_a.T - TC_1158_1282.port_b.T; TC_1158_1282.port_a.Q_flow = TC_1158_1282.Q_flow; TC_1158_1282.port_b.Q_flow = -TC_1158_1282.Q_flow; TC_1158_1497.Q_flow = TC_1158_1497.G * TC_1158_1497.dT; TC_1158_1497.dT = TC_1158_1497.port_a.T - TC_1158_1497.port_b.T; TC_1158_1497.port_a.Q_flow = TC_1158_1497.Q_flow; TC_1158_1497.port_b.Q_flow = -TC_1158_1497.Q_flow; TC_1158_1609.Q_flow = TC_1158_1609.G * TC_1158_1609.dT; TC_1158_1609.dT = TC_1158_1609.port_a.T - TC_1158_1609.port_b.T; TC_1158_1609.port_a.Q_flow = TC_1158_1609.Q_flow; TC_1158_1609.port_b.Q_flow = -TC_1158_1609.Q_flow; TC_1159_1160.Q_flow = TC_1159_1160.G * TC_1159_1160.dT; TC_1159_1160.dT = TC_1159_1160.port_a.T - TC_1159_1160.port_b.T; TC_1159_1160.port_a.Q_flow = TC_1159_1160.Q_flow; TC_1159_1160.port_b.Q_flow = -TC_1159_1160.Q_flow; TC_1159_1283.Q_flow = TC_1159_1283.G * TC_1159_1283.dT; TC_1159_1283.dT = TC_1159_1283.port_a.T - TC_1159_1283.port_b.T; TC_1159_1283.port_a.Q_flow = TC_1159_1283.Q_flow; TC_1159_1283.port_b.Q_flow = -TC_1159_1283.Q_flow; TC_1159_1498.Q_flow = TC_1159_1498.G * TC_1159_1498.dT; TC_1159_1498.dT = TC_1159_1498.port_a.T - TC_1159_1498.port_b.T; TC_1159_1498.port_a.Q_flow = TC_1159_1498.Q_flow; TC_1159_1498.port_b.Q_flow = -TC_1159_1498.Q_flow; TC_1159_1610.Q_flow = TC_1159_1610.G * TC_1159_1610.dT; TC_1159_1610.dT = TC_1159_1610.port_a.T - TC_1159_1610.port_b.T; TC_1159_1610.port_a.Q_flow = TC_1159_1610.Q_flow; TC_1159_1610.port_b.Q_flow = -TC_1159_1610.Q_flow; TC_1160_1161.Q_flow = TC_1160_1161.G * TC_1160_1161.dT; TC_1160_1161.dT = TC_1160_1161.port_a.T - TC_1160_1161.port_b.T; TC_1160_1161.port_a.Q_flow = TC_1160_1161.Q_flow; TC_1160_1161.port_b.Q_flow = -TC_1160_1161.Q_flow; TC_1160_1284.Q_flow = TC_1160_1284.G * TC_1160_1284.dT; TC_1160_1284.dT = TC_1160_1284.port_a.T - TC_1160_1284.port_b.T; TC_1160_1284.port_a.Q_flow = TC_1160_1284.Q_flow; TC_1160_1284.port_b.Q_flow = -TC_1160_1284.Q_flow; TC_1160_1499.Q_flow = TC_1160_1499.G * TC_1160_1499.dT; TC_1160_1499.dT = TC_1160_1499.port_a.T - TC_1160_1499.port_b.T; TC_1160_1499.port_a.Q_flow = TC_1160_1499.Q_flow; TC_1160_1499.port_b.Q_flow = -TC_1160_1499.Q_flow; TC_1160_1611.Q_flow = TC_1160_1611.G * TC_1160_1611.dT; TC_1160_1611.dT = TC_1160_1611.port_a.T - TC_1160_1611.port_b.T; TC_1160_1611.port_a.Q_flow = TC_1160_1611.Q_flow; TC_1160_1611.port_b.Q_flow = -TC_1160_1611.Q_flow; TC_1161_1162.Q_flow = TC_1161_1162.G * TC_1161_1162.dT; TC_1161_1162.dT = TC_1161_1162.port_a.T - TC_1161_1162.port_b.T; TC_1161_1162.port_a.Q_flow = TC_1161_1162.Q_flow; TC_1161_1162.port_b.Q_flow = -TC_1161_1162.Q_flow; TC_1161_1285.Q_flow = TC_1161_1285.G * TC_1161_1285.dT; TC_1161_1285.dT = TC_1161_1285.port_a.T - TC_1161_1285.port_b.T; TC_1161_1285.port_a.Q_flow = TC_1161_1285.Q_flow; TC_1161_1285.port_b.Q_flow = -TC_1161_1285.Q_flow; TC_1161_1500.Q_flow = TC_1161_1500.G * TC_1161_1500.dT; TC_1161_1500.dT = TC_1161_1500.port_a.T - TC_1161_1500.port_b.T; TC_1161_1500.port_a.Q_flow = TC_1161_1500.Q_flow; TC_1161_1500.port_b.Q_flow = -TC_1161_1500.Q_flow; TC_1161_1612.Q_flow = TC_1161_1612.G * TC_1161_1612.dT; TC_1161_1612.dT = TC_1161_1612.port_a.T - TC_1161_1612.port_b.T; TC_1161_1612.port_a.Q_flow = TC_1161_1612.Q_flow; TC_1161_1612.port_b.Q_flow = -TC_1161_1612.Q_flow; TC_1162_1163.Q_flow = TC_1162_1163.G * TC_1162_1163.dT; TC_1162_1163.dT = TC_1162_1163.port_a.T - TC_1162_1163.port_b.T; TC_1162_1163.port_a.Q_flow = TC_1162_1163.Q_flow; TC_1162_1163.port_b.Q_flow = -TC_1162_1163.Q_flow; TC_1162_1169.Q_flow = TC_1162_1169.G * TC_1162_1169.dT; TC_1162_1169.dT = TC_1162_1169.port_a.T - TC_1162_1169.port_b.T; TC_1162_1169.port_a.Q_flow = TC_1162_1169.Q_flow; TC_1162_1169.port_b.Q_flow = -TC_1162_1169.Q_flow; TC_1162_1286.Q_flow = TC_1162_1286.G * TC_1162_1286.dT; TC_1162_1286.dT = TC_1162_1286.port_a.T - TC_1162_1286.port_b.T; TC_1162_1286.port_a.Q_flow = TC_1162_1286.Q_flow; TC_1162_1286.port_b.Q_flow = -TC_1162_1286.Q_flow; TC_1162_1613.Q_flow = TC_1162_1613.G * TC_1162_1613.dT; TC_1162_1613.dT = TC_1162_1613.port_a.T - TC_1162_1613.port_b.T; TC_1162_1613.port_a.Q_flow = TC_1162_1613.Q_flow; TC_1162_1613.port_b.Q_flow = -TC_1162_1613.Q_flow; TC_1163_1164.Q_flow = TC_1163_1164.G * TC_1163_1164.dT; TC_1163_1164.dT = TC_1163_1164.port_a.T - TC_1163_1164.port_b.T; TC_1163_1164.port_a.Q_flow = TC_1163_1164.Q_flow; TC_1163_1164.port_b.Q_flow = -TC_1163_1164.Q_flow; TC_1163_1170.Q_flow = TC_1163_1170.G * TC_1163_1170.dT; TC_1163_1170.dT = TC_1163_1170.port_a.T - TC_1163_1170.port_b.T; TC_1163_1170.port_a.Q_flow = TC_1163_1170.Q_flow; TC_1163_1170.port_b.Q_flow = -TC_1163_1170.Q_flow; TC_1163_1287.Q_flow = TC_1163_1287.G * TC_1163_1287.dT; TC_1163_1287.dT = TC_1163_1287.port_a.T - TC_1163_1287.port_b.T; TC_1163_1287.port_a.Q_flow = TC_1163_1287.Q_flow; TC_1163_1287.port_b.Q_flow = -TC_1163_1287.Q_flow; TC_1163_1614.Q_flow = TC_1163_1614.G * TC_1163_1614.dT; TC_1163_1614.dT = TC_1163_1614.port_a.T - TC_1163_1614.port_b.T; TC_1163_1614.port_a.Q_flow = TC_1163_1614.Q_flow; TC_1163_1614.port_b.Q_flow = -TC_1163_1614.Q_flow; TC_1164_1165.Q_flow = TC_1164_1165.G * TC_1164_1165.dT; TC_1164_1165.dT = TC_1164_1165.port_a.T - TC_1164_1165.port_b.T; TC_1164_1165.port_a.Q_flow = TC_1164_1165.Q_flow; TC_1164_1165.port_b.Q_flow = -TC_1164_1165.Q_flow; TC_1164_1171.Q_flow = TC_1164_1171.G * TC_1164_1171.dT; TC_1164_1171.dT = TC_1164_1171.port_a.T - TC_1164_1171.port_b.T; TC_1164_1171.port_a.Q_flow = TC_1164_1171.Q_flow; TC_1164_1171.port_b.Q_flow = -TC_1164_1171.Q_flow; TC_1164_1288.Q_flow = TC_1164_1288.G * TC_1164_1288.dT; TC_1164_1288.dT = TC_1164_1288.port_a.T - TC_1164_1288.port_b.T; TC_1164_1288.port_a.Q_flow = TC_1164_1288.Q_flow; TC_1164_1288.port_b.Q_flow = -TC_1164_1288.Q_flow; TC_1164_1615.Q_flow = TC_1164_1615.G * TC_1164_1615.dT; TC_1164_1615.dT = TC_1164_1615.port_a.T - TC_1164_1615.port_b.T; TC_1164_1615.port_a.Q_flow = TC_1164_1615.Q_flow; TC_1164_1615.port_b.Q_flow = -TC_1164_1615.Q_flow; TC_1165_1166.Q_flow = TC_1165_1166.G * TC_1165_1166.dT; TC_1165_1166.dT = TC_1165_1166.port_a.T - TC_1165_1166.port_b.T; TC_1165_1166.port_a.Q_flow = TC_1165_1166.Q_flow; TC_1165_1166.port_b.Q_flow = -TC_1165_1166.Q_flow; TC_1165_1172.Q_flow = TC_1165_1172.G * TC_1165_1172.dT; TC_1165_1172.dT = TC_1165_1172.port_a.T - TC_1165_1172.port_b.T; TC_1165_1172.port_a.Q_flow = TC_1165_1172.Q_flow; TC_1165_1172.port_b.Q_flow = -TC_1165_1172.Q_flow; TC_1165_1289.Q_flow = TC_1165_1289.G * TC_1165_1289.dT; TC_1165_1289.dT = TC_1165_1289.port_a.T - TC_1165_1289.port_b.T; TC_1165_1289.port_a.Q_flow = TC_1165_1289.Q_flow; TC_1165_1289.port_b.Q_flow = -TC_1165_1289.Q_flow; TC_1165_1616.Q_flow = TC_1165_1616.G * TC_1165_1616.dT; TC_1165_1616.dT = TC_1165_1616.port_a.T - TC_1165_1616.port_b.T; TC_1165_1616.port_a.Q_flow = TC_1165_1616.Q_flow; TC_1165_1616.port_b.Q_flow = -TC_1165_1616.Q_flow; TC_1166_1173.Q_flow = TC_1166_1173.G * TC_1166_1173.dT; TC_1166_1173.dT = TC_1166_1173.port_a.T - TC_1166_1173.port_b.T; TC_1166_1173.port_a.Q_flow = TC_1166_1173.Q_flow; TC_1166_1173.port_b.Q_flow = -TC_1166_1173.Q_flow; TC_1166_1290.Q_flow = TC_1166_1290.G * TC_1166_1290.dT; TC_1166_1290.dT = TC_1166_1290.port_a.T - TC_1166_1290.port_b.T; TC_1166_1290.port_a.Q_flow = TC_1166_1290.Q_flow; TC_1166_1290.port_b.Q_flow = -TC_1166_1290.Q_flow; TC_1167_1168.Q_flow = TC_1167_1168.G * TC_1167_1168.dT; TC_1167_1168.dT = TC_1167_1168.port_a.T - TC_1167_1168.port_b.T; TC_1167_1168.port_a.Q_flow = TC_1167_1168.Q_flow; TC_1167_1168.port_b.Q_flow = -TC_1167_1168.Q_flow; TC_1167_1174.Q_flow = TC_1167_1174.G * TC_1167_1174.dT; TC_1167_1174.dT = TC_1167_1174.port_a.T - TC_1167_1174.port_b.T; TC_1167_1174.port_a.Q_flow = TC_1167_1174.Q_flow; TC_1167_1174.port_b.Q_flow = -TC_1167_1174.Q_flow; TC_1167_1291.Q_flow = TC_1167_1291.G * TC_1167_1291.dT; TC_1167_1291.dT = TC_1167_1291.port_a.T - TC_1167_1291.port_b.T; TC_1167_1291.port_a.Q_flow = TC_1167_1291.Q_flow; TC_1167_1291.port_b.Q_flow = -TC_1167_1291.Q_flow; TC_1168_1175.Q_flow = TC_1168_1175.G * TC_1168_1175.dT; TC_1168_1175.dT = TC_1168_1175.port_a.T - TC_1168_1175.port_b.T; TC_1168_1175.port_a.Q_flow = TC_1168_1175.Q_flow; TC_1168_1175.port_b.Q_flow = -TC_1168_1175.Q_flow; TC_1168_1292.Q_flow = TC_1168_1292.G * TC_1168_1292.dT; TC_1168_1292.dT = TC_1168_1292.port_a.T - TC_1168_1292.port_b.T; TC_1168_1292.port_a.Q_flow = TC_1168_1292.Q_flow; TC_1168_1292.port_b.Q_flow = -TC_1168_1292.Q_flow; TC_1168_1497.Q_flow = TC_1168_1497.G * TC_1168_1497.dT; TC_1168_1497.dT = TC_1168_1497.port_a.T - TC_1168_1497.port_b.T; TC_1168_1497.port_a.Q_flow = TC_1168_1497.Q_flow; TC_1168_1497.port_b.Q_flow = -TC_1168_1497.Q_flow; TC_1168_1617.Q_flow = TC_1168_1617.G * TC_1168_1617.dT; TC_1168_1617.dT = TC_1168_1617.port_a.T - TC_1168_1617.port_b.T; TC_1168_1617.port_a.Q_flow = TC_1168_1617.Q_flow; TC_1168_1617.port_b.Q_flow = -TC_1168_1617.Q_flow; TC_1169_1170.Q_flow = TC_1169_1170.G * TC_1169_1170.dT; TC_1169_1170.dT = TC_1169_1170.port_a.T - TC_1169_1170.port_b.T; TC_1169_1170.port_a.Q_flow = TC_1169_1170.Q_flow; TC_1169_1170.port_b.Q_flow = -TC_1169_1170.Q_flow; TC_1169_1176.Q_flow = TC_1169_1176.G * TC_1169_1176.dT; TC_1169_1176.dT = TC_1169_1176.port_a.T - TC_1169_1176.port_b.T; TC_1169_1176.port_a.Q_flow = TC_1169_1176.Q_flow; TC_1169_1176.port_b.Q_flow = -TC_1169_1176.Q_flow; TC_1169_1297.Q_flow = TC_1169_1297.G * TC_1169_1297.dT; TC_1169_1297.dT = TC_1169_1297.port_a.T - TC_1169_1297.port_b.T; TC_1169_1297.port_a.Q_flow = TC_1169_1297.Q_flow; TC_1169_1297.port_b.Q_flow = -TC_1169_1297.Q_flow; TC_1169_1500.Q_flow = TC_1169_1500.G * TC_1169_1500.dT; TC_1169_1500.dT = TC_1169_1500.port_a.T - TC_1169_1500.port_b.T; TC_1169_1500.port_a.Q_flow = TC_1169_1500.Q_flow; TC_1169_1500.port_b.Q_flow = -TC_1169_1500.Q_flow; TC_1169_1622.Q_flow = TC_1169_1622.G * TC_1169_1622.dT; TC_1169_1622.dT = TC_1169_1622.port_a.T - TC_1169_1622.port_b.T; TC_1169_1622.port_a.Q_flow = TC_1169_1622.Q_flow; TC_1169_1622.port_b.Q_flow = -TC_1169_1622.Q_flow; TC_1170_1171.Q_flow = TC_1170_1171.G * TC_1170_1171.dT; TC_1170_1171.dT = TC_1170_1171.port_a.T - TC_1170_1171.port_b.T; TC_1170_1171.port_a.Q_flow = TC_1170_1171.Q_flow; TC_1170_1171.port_b.Q_flow = -TC_1170_1171.Q_flow; TC_1170_1177.Q_flow = TC_1170_1177.G * TC_1170_1177.dT; TC_1170_1177.dT = TC_1170_1177.port_a.T - TC_1170_1177.port_b.T; TC_1170_1177.port_a.Q_flow = TC_1170_1177.Q_flow; TC_1170_1177.port_b.Q_flow = -TC_1170_1177.Q_flow; TC_1170_1298.Q_flow = TC_1170_1298.G * TC_1170_1298.dT; TC_1170_1298.dT = TC_1170_1298.port_a.T - TC_1170_1298.port_b.T; TC_1170_1298.port_a.Q_flow = TC_1170_1298.Q_flow; TC_1170_1298.port_b.Q_flow = -TC_1170_1298.Q_flow; TC_1170_1623.Q_flow = TC_1170_1623.G * TC_1170_1623.dT; TC_1170_1623.dT = TC_1170_1623.port_a.T - TC_1170_1623.port_b.T; TC_1170_1623.port_a.Q_flow = TC_1170_1623.Q_flow; TC_1170_1623.port_b.Q_flow = -TC_1170_1623.Q_flow; TC_1171_1172.Q_flow = TC_1171_1172.G * TC_1171_1172.dT; TC_1171_1172.dT = TC_1171_1172.port_a.T - TC_1171_1172.port_b.T; TC_1171_1172.port_a.Q_flow = TC_1171_1172.Q_flow; TC_1171_1172.port_b.Q_flow = -TC_1171_1172.Q_flow; TC_1171_1178.Q_flow = TC_1171_1178.G * TC_1171_1178.dT; TC_1171_1178.dT = TC_1171_1178.port_a.T - TC_1171_1178.port_b.T; TC_1171_1178.port_a.Q_flow = TC_1171_1178.Q_flow; TC_1171_1178.port_b.Q_flow = -TC_1171_1178.Q_flow; TC_1171_1299.Q_flow = TC_1171_1299.G * TC_1171_1299.dT; TC_1171_1299.dT = TC_1171_1299.port_a.T - TC_1171_1299.port_b.T; TC_1171_1299.port_a.Q_flow = TC_1171_1299.Q_flow; TC_1171_1299.port_b.Q_flow = -TC_1171_1299.Q_flow; TC_1171_1624.Q_flow = TC_1171_1624.G * TC_1171_1624.dT; TC_1171_1624.dT = TC_1171_1624.port_a.T - TC_1171_1624.port_b.T; TC_1171_1624.port_a.Q_flow = TC_1171_1624.Q_flow; TC_1171_1624.port_b.Q_flow = -TC_1171_1624.Q_flow; TC_1172_1173.Q_flow = TC_1172_1173.G * TC_1172_1173.dT; TC_1172_1173.dT = TC_1172_1173.port_a.T - TC_1172_1173.port_b.T; TC_1172_1173.port_a.Q_flow = TC_1172_1173.Q_flow; TC_1172_1173.port_b.Q_flow = -TC_1172_1173.Q_flow; TC_1172_1179.Q_flow = TC_1172_1179.G * TC_1172_1179.dT; TC_1172_1179.dT = TC_1172_1179.port_a.T - TC_1172_1179.port_b.T; TC_1172_1179.port_a.Q_flow = TC_1172_1179.Q_flow; TC_1172_1179.port_b.Q_flow = -TC_1172_1179.Q_flow; TC_1172_1300.Q_flow = TC_1172_1300.G * TC_1172_1300.dT; TC_1172_1300.dT = TC_1172_1300.port_a.T - TC_1172_1300.port_b.T; TC_1172_1300.port_a.Q_flow = TC_1172_1300.Q_flow; TC_1172_1300.port_b.Q_flow = -TC_1172_1300.Q_flow; TC_1172_1625.Q_flow = TC_1172_1625.G * TC_1172_1625.dT; TC_1172_1625.dT = TC_1172_1625.port_a.T - TC_1172_1625.port_b.T; TC_1172_1625.port_a.Q_flow = TC_1172_1625.Q_flow; TC_1172_1625.port_b.Q_flow = -TC_1172_1625.Q_flow; TC_1173_1180.Q_flow = TC_1173_1180.G * TC_1173_1180.dT; TC_1173_1180.dT = TC_1173_1180.port_a.T - TC_1173_1180.port_b.T; TC_1173_1180.port_a.Q_flow = TC_1173_1180.Q_flow; TC_1173_1180.port_b.Q_flow = -TC_1173_1180.Q_flow; TC_1173_1301.Q_flow = TC_1173_1301.G * TC_1173_1301.dT; TC_1173_1301.dT = TC_1173_1301.port_a.T - TC_1173_1301.port_b.T; TC_1173_1301.port_a.Q_flow = TC_1173_1301.Q_flow; TC_1173_1301.port_b.Q_flow = -TC_1173_1301.Q_flow; TC_1174_1175.Q_flow = TC_1174_1175.G * TC_1174_1175.dT; TC_1174_1175.dT = TC_1174_1175.port_a.T - TC_1174_1175.port_b.T; TC_1174_1175.port_a.Q_flow = TC_1174_1175.Q_flow; TC_1174_1175.port_b.Q_flow = -TC_1174_1175.Q_flow; TC_1174_1181.Q_flow = TC_1174_1181.G * TC_1174_1181.dT; TC_1174_1181.dT = TC_1174_1181.port_a.T - TC_1174_1181.port_b.T; TC_1174_1181.port_a.Q_flow = TC_1174_1181.Q_flow; TC_1174_1181.port_b.Q_flow = -TC_1174_1181.Q_flow; TC_1174_1302.Q_flow = TC_1174_1302.G * TC_1174_1302.dT; TC_1174_1302.dT = TC_1174_1302.port_a.T - TC_1174_1302.port_b.T; TC_1174_1302.port_a.Q_flow = TC_1174_1302.Q_flow; TC_1174_1302.port_b.Q_flow = -TC_1174_1302.Q_flow; TC_1175_1182.Q_flow = TC_1175_1182.G * TC_1175_1182.dT; TC_1175_1182.dT = TC_1175_1182.port_a.T - TC_1175_1182.port_b.T; TC_1175_1182.port_a.Q_flow = TC_1175_1182.Q_flow; TC_1175_1182.port_b.Q_flow = -TC_1175_1182.Q_flow; TC_1175_1303.Q_flow = TC_1175_1303.G * TC_1175_1303.dT; TC_1175_1303.dT = TC_1175_1303.port_a.T - TC_1175_1303.port_b.T; TC_1175_1303.port_a.Q_flow = TC_1175_1303.Q_flow; TC_1175_1303.port_b.Q_flow = -TC_1175_1303.Q_flow; TC_1175_1501.Q_flow = TC_1175_1501.G * TC_1175_1501.dT; TC_1175_1501.dT = TC_1175_1501.port_a.T - TC_1175_1501.port_b.T; TC_1175_1501.port_a.Q_flow = TC_1175_1501.Q_flow; TC_1175_1501.port_b.Q_flow = -TC_1175_1501.Q_flow; TC_1175_1626.Q_flow = TC_1175_1626.G * TC_1175_1626.dT; TC_1175_1626.dT = TC_1175_1626.port_a.T - TC_1175_1626.port_b.T; TC_1175_1626.port_a.Q_flow = TC_1175_1626.Q_flow; TC_1175_1626.port_b.Q_flow = -TC_1175_1626.Q_flow; TC_1176_1177.Q_flow = TC_1176_1177.G * TC_1176_1177.dT; TC_1176_1177.dT = TC_1176_1177.port_a.T - TC_1176_1177.port_b.T; TC_1176_1177.port_a.Q_flow = TC_1176_1177.Q_flow; TC_1176_1177.port_b.Q_flow = -TC_1176_1177.Q_flow; TC_1176_1183.Q_flow = TC_1176_1183.G * TC_1176_1183.dT; TC_1176_1183.dT = TC_1176_1183.port_a.T - TC_1176_1183.port_b.T; TC_1176_1183.port_a.Q_flow = TC_1176_1183.Q_flow; TC_1176_1183.port_b.Q_flow = -TC_1176_1183.Q_flow; TC_1176_1308.Q_flow = TC_1176_1308.G * TC_1176_1308.dT; TC_1176_1308.dT = TC_1176_1308.port_a.T - TC_1176_1308.port_b.T; TC_1176_1308.port_a.Q_flow = TC_1176_1308.Q_flow; TC_1176_1308.port_b.Q_flow = -TC_1176_1308.Q_flow; TC_1176_1504.Q_flow = TC_1176_1504.G * TC_1176_1504.dT; TC_1176_1504.dT = TC_1176_1504.port_a.T - TC_1176_1504.port_b.T; TC_1176_1504.port_a.Q_flow = TC_1176_1504.Q_flow; TC_1176_1504.port_b.Q_flow = -TC_1176_1504.Q_flow; TC_1176_1631.Q_flow = TC_1176_1631.G * TC_1176_1631.dT; TC_1176_1631.dT = TC_1176_1631.port_a.T - TC_1176_1631.port_b.T; TC_1176_1631.port_a.Q_flow = TC_1176_1631.Q_flow; TC_1176_1631.port_b.Q_flow = -TC_1176_1631.Q_flow; TC_1177_1178.Q_flow = TC_1177_1178.G * TC_1177_1178.dT; TC_1177_1178.dT = TC_1177_1178.port_a.T - TC_1177_1178.port_b.T; TC_1177_1178.port_a.Q_flow = TC_1177_1178.Q_flow; TC_1177_1178.port_b.Q_flow = -TC_1177_1178.Q_flow; TC_1177_1184.Q_flow = TC_1177_1184.G * TC_1177_1184.dT; TC_1177_1184.dT = TC_1177_1184.port_a.T - TC_1177_1184.port_b.T; TC_1177_1184.port_a.Q_flow = TC_1177_1184.Q_flow; TC_1177_1184.port_b.Q_flow = -TC_1177_1184.Q_flow; TC_1177_1309.Q_flow = TC_1177_1309.G * TC_1177_1309.dT; TC_1177_1309.dT = TC_1177_1309.port_a.T - TC_1177_1309.port_b.T; TC_1177_1309.port_a.Q_flow = TC_1177_1309.Q_flow; TC_1177_1309.port_b.Q_flow = -TC_1177_1309.Q_flow; TC_1177_1632.Q_flow = TC_1177_1632.G * TC_1177_1632.dT; TC_1177_1632.dT = TC_1177_1632.port_a.T - TC_1177_1632.port_b.T; TC_1177_1632.port_a.Q_flow = TC_1177_1632.Q_flow; TC_1177_1632.port_b.Q_flow = -TC_1177_1632.Q_flow; TC_1178_1179.Q_flow = TC_1178_1179.G * TC_1178_1179.dT; TC_1178_1179.dT = TC_1178_1179.port_a.T - TC_1178_1179.port_b.T; TC_1178_1179.port_a.Q_flow = TC_1178_1179.Q_flow; TC_1178_1179.port_b.Q_flow = -TC_1178_1179.Q_flow; TC_1178_1185.Q_flow = TC_1178_1185.G * TC_1178_1185.dT; TC_1178_1185.dT = TC_1178_1185.port_a.T - TC_1178_1185.port_b.T; TC_1178_1185.port_a.Q_flow = TC_1178_1185.Q_flow; TC_1178_1185.port_b.Q_flow = -TC_1178_1185.Q_flow; TC_1178_1310.Q_flow = TC_1178_1310.G * TC_1178_1310.dT; TC_1178_1310.dT = TC_1178_1310.port_a.T - TC_1178_1310.port_b.T; TC_1178_1310.port_a.Q_flow = TC_1178_1310.Q_flow; TC_1178_1310.port_b.Q_flow = -TC_1178_1310.Q_flow; TC_1178_1633.Q_flow = TC_1178_1633.G * TC_1178_1633.dT; TC_1178_1633.dT = TC_1178_1633.port_a.T - TC_1178_1633.port_b.T; TC_1178_1633.port_a.Q_flow = TC_1178_1633.Q_flow; TC_1178_1633.port_b.Q_flow = -TC_1178_1633.Q_flow; TC_1179_1180.Q_flow = TC_1179_1180.G * TC_1179_1180.dT; TC_1179_1180.dT = TC_1179_1180.port_a.T - TC_1179_1180.port_b.T; TC_1179_1180.port_a.Q_flow = TC_1179_1180.Q_flow; TC_1179_1180.port_b.Q_flow = -TC_1179_1180.Q_flow; TC_1179_1186.Q_flow = TC_1179_1186.G * TC_1179_1186.dT; TC_1179_1186.dT = TC_1179_1186.port_a.T - TC_1179_1186.port_b.T; TC_1179_1186.port_a.Q_flow = TC_1179_1186.Q_flow; TC_1179_1186.port_b.Q_flow = -TC_1179_1186.Q_flow; TC_1179_1311.Q_flow = TC_1179_1311.G * TC_1179_1311.dT; TC_1179_1311.dT = TC_1179_1311.port_a.T - TC_1179_1311.port_b.T; TC_1179_1311.port_a.Q_flow = TC_1179_1311.Q_flow; TC_1179_1311.port_b.Q_flow = -TC_1179_1311.Q_flow; TC_1179_1634.Q_flow = TC_1179_1634.G * TC_1179_1634.dT; TC_1179_1634.dT = TC_1179_1634.port_a.T - TC_1179_1634.port_b.T; TC_1179_1634.port_a.Q_flow = TC_1179_1634.Q_flow; TC_1179_1634.port_b.Q_flow = -TC_1179_1634.Q_flow; TC_1180_1187.Q_flow = TC_1180_1187.G * TC_1180_1187.dT; TC_1180_1187.dT = TC_1180_1187.port_a.T - TC_1180_1187.port_b.T; TC_1180_1187.port_a.Q_flow = TC_1180_1187.Q_flow; TC_1180_1187.port_b.Q_flow = -TC_1180_1187.Q_flow; TC_1180_1312.Q_flow = TC_1180_1312.G * TC_1180_1312.dT; TC_1180_1312.dT = TC_1180_1312.port_a.T - TC_1180_1312.port_b.T; TC_1180_1312.port_a.Q_flow = TC_1180_1312.Q_flow; TC_1180_1312.port_b.Q_flow = -TC_1180_1312.Q_flow; TC_1181_1182.Q_flow = TC_1181_1182.G * TC_1181_1182.dT; TC_1181_1182.dT = TC_1181_1182.port_a.T - TC_1181_1182.port_b.T; TC_1181_1182.port_a.Q_flow = TC_1181_1182.Q_flow; TC_1181_1182.port_b.Q_flow = -TC_1181_1182.Q_flow; TC_1181_1188.Q_flow = TC_1181_1188.G * TC_1181_1188.dT; TC_1181_1188.dT = TC_1181_1188.port_a.T - TC_1181_1188.port_b.T; TC_1181_1188.port_a.Q_flow = TC_1181_1188.Q_flow; TC_1181_1188.port_b.Q_flow = -TC_1181_1188.Q_flow; TC_1181_1313.Q_flow = TC_1181_1313.G * TC_1181_1313.dT; TC_1181_1313.dT = TC_1181_1313.port_a.T - TC_1181_1313.port_b.T; TC_1181_1313.port_a.Q_flow = TC_1181_1313.Q_flow; TC_1181_1313.port_b.Q_flow = -TC_1181_1313.Q_flow; TC_1182_1189.Q_flow = TC_1182_1189.G * TC_1182_1189.dT; TC_1182_1189.dT = TC_1182_1189.port_a.T - TC_1182_1189.port_b.T; TC_1182_1189.port_a.Q_flow = TC_1182_1189.Q_flow; TC_1182_1189.port_b.Q_flow = -TC_1182_1189.Q_flow; TC_1182_1314.Q_flow = TC_1182_1314.G * TC_1182_1314.dT; TC_1182_1314.dT = TC_1182_1314.port_a.T - TC_1182_1314.port_b.T; TC_1182_1314.port_a.Q_flow = TC_1182_1314.Q_flow; TC_1182_1314.port_b.Q_flow = -TC_1182_1314.Q_flow; TC_1182_1505.Q_flow = TC_1182_1505.G * TC_1182_1505.dT; TC_1182_1505.dT = TC_1182_1505.port_a.T - TC_1182_1505.port_b.T; TC_1182_1505.port_a.Q_flow = TC_1182_1505.Q_flow; TC_1182_1505.port_b.Q_flow = -TC_1182_1505.Q_flow; TC_1182_1563.Q_flow = TC_1182_1563.G * TC_1182_1563.dT; TC_1182_1563.dT = TC_1182_1563.port_a.T - TC_1182_1563.port_b.T; TC_1182_1563.port_a.Q_flow = TC_1182_1563.Q_flow; TC_1182_1563.port_b.Q_flow = -TC_1182_1563.Q_flow; TC_1183_1184.Q_flow = TC_1183_1184.G * TC_1183_1184.dT; TC_1183_1184.dT = TC_1183_1184.port_a.T - TC_1183_1184.port_b.T; TC_1183_1184.port_a.Q_flow = TC_1183_1184.Q_flow; TC_1183_1184.port_b.Q_flow = -TC_1183_1184.Q_flow; TC_1183_1194.Q_flow = TC_1183_1194.G * TC_1183_1194.dT; TC_1183_1194.dT = TC_1183_1194.port_a.T - TC_1183_1194.port_b.T; TC_1183_1194.port_a.Q_flow = TC_1183_1194.Q_flow; TC_1183_1194.port_b.Q_flow = -TC_1183_1194.Q_flow; TC_1183_1319.Q_flow = TC_1183_1319.G * TC_1183_1319.dT; TC_1183_1319.dT = TC_1183_1319.port_a.T - TC_1183_1319.port_b.T; TC_1183_1319.port_a.Q_flow = TC_1183_1319.Q_flow; TC_1183_1319.port_b.Q_flow = -TC_1183_1319.Q_flow; TC_1183_1508.Q_flow = TC_1183_1508.G * TC_1183_1508.dT; TC_1183_1508.dT = TC_1183_1508.port_a.T - TC_1183_1508.port_b.T; TC_1183_1508.port_a.Q_flow = TC_1183_1508.Q_flow; TC_1183_1508.port_b.Q_flow = -TC_1183_1508.Q_flow; TC_1183_1568.Q_flow = TC_1183_1568.G * TC_1183_1568.dT; TC_1183_1568.dT = TC_1183_1568.port_a.T - TC_1183_1568.port_b.T; TC_1183_1568.port_a.Q_flow = TC_1183_1568.Q_flow; TC_1183_1568.port_b.Q_flow = -TC_1183_1568.Q_flow; TC_1184_1185.Q_flow = TC_1184_1185.G * TC_1184_1185.dT; TC_1184_1185.dT = TC_1184_1185.port_a.T - TC_1184_1185.port_b.T; TC_1184_1185.port_a.Q_flow = TC_1184_1185.Q_flow; TC_1184_1185.port_b.Q_flow = -TC_1184_1185.Q_flow; TC_1184_1195.Q_flow = TC_1184_1195.G * TC_1184_1195.dT; TC_1184_1195.dT = TC_1184_1195.port_a.T - TC_1184_1195.port_b.T; TC_1184_1195.port_a.Q_flow = TC_1184_1195.Q_flow; TC_1184_1195.port_b.Q_flow = -TC_1184_1195.Q_flow; TC_1184_1320.Q_flow = TC_1184_1320.G * TC_1184_1320.dT; TC_1184_1320.dT = TC_1184_1320.port_a.T - TC_1184_1320.port_b.T; TC_1184_1320.port_a.Q_flow = TC_1184_1320.Q_flow; TC_1184_1320.port_b.Q_flow = -TC_1184_1320.Q_flow; TC_1184_1569.Q_flow = TC_1184_1569.G * TC_1184_1569.dT; TC_1184_1569.dT = TC_1184_1569.port_a.T - TC_1184_1569.port_b.T; TC_1184_1569.port_a.Q_flow = TC_1184_1569.Q_flow; TC_1184_1569.port_b.Q_flow = -TC_1184_1569.Q_flow; TC_1185_1186.Q_flow = TC_1185_1186.G * TC_1185_1186.dT; TC_1185_1186.dT = TC_1185_1186.port_a.T - TC_1185_1186.port_b.T; TC_1185_1186.port_a.Q_flow = TC_1185_1186.Q_flow; TC_1185_1186.port_b.Q_flow = -TC_1185_1186.Q_flow; TC_1185_1196.Q_flow = TC_1185_1196.G * TC_1185_1196.dT; TC_1185_1196.dT = TC_1185_1196.port_a.T - TC_1185_1196.port_b.T; TC_1185_1196.port_a.Q_flow = TC_1185_1196.Q_flow; TC_1185_1196.port_b.Q_flow = -TC_1185_1196.Q_flow; TC_1185_1321.Q_flow = TC_1185_1321.G * TC_1185_1321.dT; TC_1185_1321.dT = TC_1185_1321.port_a.T - TC_1185_1321.port_b.T; TC_1185_1321.port_a.Q_flow = TC_1185_1321.Q_flow; TC_1185_1321.port_b.Q_flow = -TC_1185_1321.Q_flow; TC_1185_1570.Q_flow = TC_1185_1570.G * TC_1185_1570.dT; TC_1185_1570.dT = TC_1185_1570.port_a.T - TC_1185_1570.port_b.T; TC_1185_1570.port_a.Q_flow = TC_1185_1570.Q_flow; TC_1185_1570.port_b.Q_flow = -TC_1185_1570.Q_flow; TC_1186_1187.Q_flow = TC_1186_1187.G * TC_1186_1187.dT; TC_1186_1187.dT = TC_1186_1187.port_a.T - TC_1186_1187.port_b.T; TC_1186_1187.port_a.Q_flow = TC_1186_1187.Q_flow; TC_1186_1187.port_b.Q_flow = -TC_1186_1187.Q_flow; TC_1186_1197.Q_flow = TC_1186_1197.G * TC_1186_1197.dT; TC_1186_1197.dT = TC_1186_1197.port_a.T - TC_1186_1197.port_b.T; TC_1186_1197.port_a.Q_flow = TC_1186_1197.Q_flow; TC_1186_1197.port_b.Q_flow = -TC_1186_1197.Q_flow; TC_1186_1322.Q_flow = TC_1186_1322.G * TC_1186_1322.dT; TC_1186_1322.dT = TC_1186_1322.port_a.T - TC_1186_1322.port_b.T; TC_1186_1322.port_a.Q_flow = TC_1186_1322.Q_flow; TC_1186_1322.port_b.Q_flow = -TC_1186_1322.Q_flow; TC_1186_1571.Q_flow = TC_1186_1571.G * TC_1186_1571.dT; TC_1186_1571.dT = TC_1186_1571.port_a.T - TC_1186_1571.port_b.T; TC_1186_1571.port_a.Q_flow = TC_1186_1571.Q_flow; TC_1186_1571.port_b.Q_flow = -TC_1186_1571.Q_flow; TC_1187_1198.Q_flow = TC_1187_1198.G * TC_1187_1198.dT; TC_1187_1198.dT = TC_1187_1198.port_a.T - TC_1187_1198.port_b.T; TC_1187_1198.port_a.Q_flow = TC_1187_1198.Q_flow; TC_1187_1198.port_b.Q_flow = -TC_1187_1198.Q_flow; TC_1187_1323.Q_flow = TC_1187_1323.G * TC_1187_1323.dT; TC_1187_1323.dT = TC_1187_1323.port_a.T - TC_1187_1323.port_b.T; TC_1187_1323.port_a.Q_flow = TC_1187_1323.Q_flow; TC_1187_1323.port_b.Q_flow = -TC_1187_1323.Q_flow; TC_1188_1189.Q_flow = TC_1188_1189.G * TC_1188_1189.dT; TC_1188_1189.dT = TC_1188_1189.port_a.T - TC_1188_1189.port_b.T; TC_1188_1189.port_a.Q_flow = TC_1188_1189.Q_flow; TC_1188_1189.port_b.Q_flow = -TC_1188_1189.Q_flow; TC_1188_1199.Q_flow = TC_1188_1199.G * TC_1188_1199.dT; TC_1188_1199.dT = TC_1188_1199.port_a.T - TC_1188_1199.port_b.T; TC_1188_1199.port_a.Q_flow = TC_1188_1199.Q_flow; TC_1188_1199.port_b.Q_flow = -TC_1188_1199.Q_flow; TC_1188_1324.Q_flow = TC_1188_1324.G * TC_1188_1324.dT; TC_1188_1324.dT = TC_1188_1324.port_a.T - TC_1188_1324.port_b.T; TC_1188_1324.port_a.Q_flow = TC_1188_1324.Q_flow; TC_1188_1324.port_b.Q_flow = -TC_1188_1324.Q_flow; TC_1189_1190.Q_flow = TC_1189_1190.G * TC_1189_1190.dT; TC_1189_1190.dT = TC_1189_1190.port_a.T - TC_1189_1190.port_b.T; TC_1189_1190.port_a.Q_flow = TC_1189_1190.Q_flow; TC_1189_1190.port_b.Q_flow = -TC_1189_1190.Q_flow; TC_1189_1200.Q_flow = TC_1189_1200.G * TC_1189_1200.dT; TC_1189_1200.dT = TC_1189_1200.port_a.T - TC_1189_1200.port_b.T; TC_1189_1200.port_a.Q_flow = TC_1189_1200.Q_flow; TC_1189_1200.port_b.Q_flow = -TC_1189_1200.Q_flow; TC_1189_1325.Q_flow = TC_1189_1325.G * TC_1189_1325.dT; TC_1189_1325.dT = TC_1189_1325.port_a.T - TC_1189_1325.port_b.T; TC_1189_1325.port_a.Q_flow = TC_1189_1325.Q_flow; TC_1189_1325.port_b.Q_flow = -TC_1189_1325.Q_flow; TC_1189_1572.Q_flow = TC_1189_1572.G * TC_1189_1572.dT; TC_1189_1572.dT = TC_1189_1572.port_a.T - TC_1189_1572.port_b.T; TC_1189_1572.port_a.Q_flow = TC_1189_1572.Q_flow; TC_1189_1572.port_b.Q_flow = -TC_1189_1572.Q_flow; TC_1190_1191.Q_flow = TC_1190_1191.G * TC_1190_1191.dT; TC_1190_1191.dT = TC_1190_1191.port_a.T - TC_1190_1191.port_b.T; TC_1190_1191.port_a.Q_flow = TC_1190_1191.Q_flow; TC_1190_1191.port_b.Q_flow = -TC_1190_1191.Q_flow; TC_1190_1201.Q_flow = TC_1190_1201.G * TC_1190_1201.dT; TC_1190_1201.dT = TC_1190_1201.port_a.T - TC_1190_1201.port_b.T; TC_1190_1201.port_a.Q_flow = TC_1190_1201.Q_flow; TC_1190_1201.port_b.Q_flow = -TC_1190_1201.Q_flow; TC_1190_1326.Q_flow = TC_1190_1326.G * TC_1190_1326.dT; TC_1190_1326.dT = TC_1190_1326.port_a.T - TC_1190_1326.port_b.T; TC_1190_1326.port_a.Q_flow = TC_1190_1326.Q_flow; TC_1190_1326.port_b.Q_flow = -TC_1190_1326.Q_flow; TC_1190_1505.Q_flow = TC_1190_1505.G * TC_1190_1505.dT; TC_1190_1505.dT = TC_1190_1505.port_a.T - TC_1190_1505.port_b.T; TC_1190_1505.port_a.Q_flow = TC_1190_1505.Q_flow; TC_1190_1505.port_b.Q_flow = -TC_1190_1505.Q_flow; TC_1190_1573.Q_flow = TC_1190_1573.G * TC_1190_1573.dT; TC_1190_1573.dT = TC_1190_1573.port_a.T - TC_1190_1573.port_b.T; TC_1190_1573.port_a.Q_flow = TC_1190_1573.Q_flow; TC_1190_1573.port_b.Q_flow = -TC_1190_1573.Q_flow; TC_1191_1192.Q_flow = TC_1191_1192.G * TC_1191_1192.dT; TC_1191_1192.dT = TC_1191_1192.port_a.T - TC_1191_1192.port_b.T; TC_1191_1192.port_a.Q_flow = TC_1191_1192.Q_flow; TC_1191_1192.port_b.Q_flow = -TC_1191_1192.Q_flow; TC_1191_1202.Q_flow = TC_1191_1202.G * TC_1191_1202.dT; TC_1191_1202.dT = TC_1191_1202.port_a.T - TC_1191_1202.port_b.T; TC_1191_1202.port_a.Q_flow = TC_1191_1202.Q_flow; TC_1191_1202.port_b.Q_flow = -TC_1191_1202.Q_flow; TC_1191_1327.Q_flow = TC_1191_1327.G * TC_1191_1327.dT; TC_1191_1327.dT = TC_1191_1327.port_a.T - TC_1191_1327.port_b.T; TC_1191_1327.port_a.Q_flow = TC_1191_1327.Q_flow; TC_1191_1327.port_b.Q_flow = -TC_1191_1327.Q_flow; TC_1191_1506.Q_flow = TC_1191_1506.G * TC_1191_1506.dT; TC_1191_1506.dT = TC_1191_1506.port_a.T - TC_1191_1506.port_b.T; TC_1191_1506.port_a.Q_flow = TC_1191_1506.Q_flow; TC_1191_1506.port_b.Q_flow = -TC_1191_1506.Q_flow; TC_1191_1574.Q_flow = TC_1191_1574.G * TC_1191_1574.dT; TC_1191_1574.dT = TC_1191_1574.port_a.T - TC_1191_1574.port_b.T; TC_1191_1574.port_a.Q_flow = TC_1191_1574.Q_flow; TC_1191_1574.port_b.Q_flow = -TC_1191_1574.Q_flow; TC_1192_1193.Q_flow = TC_1192_1193.G * TC_1192_1193.dT; TC_1192_1193.dT = TC_1192_1193.port_a.T - TC_1192_1193.port_b.T; TC_1192_1193.port_a.Q_flow = TC_1192_1193.Q_flow; TC_1192_1193.port_b.Q_flow = -TC_1192_1193.Q_flow; TC_1192_1203.Q_flow = TC_1192_1203.G * TC_1192_1203.dT; TC_1192_1203.dT = TC_1192_1203.port_a.T - TC_1192_1203.port_b.T; TC_1192_1203.port_a.Q_flow = TC_1192_1203.Q_flow; TC_1192_1203.port_b.Q_flow = -TC_1192_1203.Q_flow; TC_1192_1328.Q_flow = TC_1192_1328.G * TC_1192_1328.dT; TC_1192_1328.dT = TC_1192_1328.port_a.T - TC_1192_1328.port_b.T; TC_1192_1328.port_a.Q_flow = TC_1192_1328.Q_flow; TC_1192_1328.port_b.Q_flow = -TC_1192_1328.Q_flow; TC_1192_1507.Q_flow = TC_1192_1507.G * TC_1192_1507.dT; TC_1192_1507.dT = TC_1192_1507.port_a.T - TC_1192_1507.port_b.T; TC_1192_1507.port_a.Q_flow = TC_1192_1507.Q_flow; TC_1192_1507.port_b.Q_flow = -TC_1192_1507.Q_flow; TC_1192_1575.Q_flow = TC_1192_1575.G * TC_1192_1575.dT; TC_1192_1575.dT = TC_1192_1575.port_a.T - TC_1192_1575.port_b.T; TC_1192_1575.port_a.Q_flow = TC_1192_1575.Q_flow; TC_1192_1575.port_b.Q_flow = -TC_1192_1575.Q_flow; TC_1193_1194.Q_flow = TC_1193_1194.G * TC_1193_1194.dT; TC_1193_1194.dT = TC_1193_1194.port_a.T - TC_1193_1194.port_b.T; TC_1193_1194.port_a.Q_flow = TC_1193_1194.Q_flow; TC_1193_1194.port_b.Q_flow = -TC_1193_1194.Q_flow; TC_1193_1204.Q_flow = TC_1193_1204.G * TC_1193_1204.dT; TC_1193_1204.dT = TC_1193_1204.port_a.T - TC_1193_1204.port_b.T; TC_1193_1204.port_a.Q_flow = TC_1193_1204.Q_flow; TC_1193_1204.port_b.Q_flow = -TC_1193_1204.Q_flow; TC_1193_1329.Q_flow = TC_1193_1329.G * TC_1193_1329.dT; TC_1193_1329.dT = TC_1193_1329.port_a.T - TC_1193_1329.port_b.T; TC_1193_1329.port_a.Q_flow = TC_1193_1329.Q_flow; TC_1193_1329.port_b.Q_flow = -TC_1193_1329.Q_flow; TC_1193_1508.Q_flow = TC_1193_1508.G * TC_1193_1508.dT; TC_1193_1508.dT = TC_1193_1508.port_a.T - TC_1193_1508.port_b.T; TC_1193_1508.port_a.Q_flow = TC_1193_1508.Q_flow; TC_1193_1508.port_b.Q_flow = -TC_1193_1508.Q_flow; TC_1193_1576.Q_flow = TC_1193_1576.G * TC_1193_1576.dT; TC_1193_1576.dT = TC_1193_1576.port_a.T - TC_1193_1576.port_b.T; TC_1193_1576.port_a.Q_flow = TC_1193_1576.Q_flow; TC_1193_1576.port_b.Q_flow = -TC_1193_1576.Q_flow; TC_1194_1195.Q_flow = TC_1194_1195.G * TC_1194_1195.dT; TC_1194_1195.dT = TC_1194_1195.port_a.T - TC_1194_1195.port_b.T; TC_1194_1195.port_a.Q_flow = TC_1194_1195.Q_flow; TC_1194_1195.port_b.Q_flow = -TC_1194_1195.Q_flow; TC_1194_1330.Q_flow = TC_1194_1330.G * TC_1194_1330.dT; TC_1194_1330.dT = TC_1194_1330.port_a.T - TC_1194_1330.port_b.T; TC_1194_1330.port_a.Q_flow = TC_1194_1330.Q_flow; TC_1194_1330.port_b.Q_flow = -TC_1194_1330.Q_flow; TC_1194_1509.Q_flow = TC_1194_1509.G * TC_1194_1509.dT; TC_1194_1509.dT = TC_1194_1509.port_a.T - TC_1194_1509.port_b.T; TC_1194_1509.port_a.Q_flow = TC_1194_1509.Q_flow; TC_1194_1509.port_b.Q_flow = -TC_1194_1509.Q_flow; TC_1194_1577.Q_flow = TC_1194_1577.G * TC_1194_1577.dT; TC_1194_1577.dT = TC_1194_1577.port_a.T - TC_1194_1577.port_b.T; TC_1194_1577.port_a.Q_flow = TC_1194_1577.Q_flow; TC_1194_1577.port_b.Q_flow = -TC_1194_1577.Q_flow; TC_1195_1196.Q_flow = TC_1195_1196.G * TC_1195_1196.dT; TC_1195_1196.dT = TC_1195_1196.port_a.T - TC_1195_1196.port_b.T; TC_1195_1196.port_a.Q_flow = TC_1195_1196.Q_flow; TC_1195_1196.port_b.Q_flow = -TC_1195_1196.Q_flow; TC_1195_1331.Q_flow = TC_1195_1331.G * TC_1195_1331.dT; TC_1195_1331.dT = TC_1195_1331.port_a.T - TC_1195_1331.port_b.T; TC_1195_1331.port_a.Q_flow = TC_1195_1331.Q_flow; TC_1195_1331.port_b.Q_flow = -TC_1195_1331.Q_flow; TC_1195_1510.Q_flow = TC_1195_1510.G * TC_1195_1510.dT; TC_1195_1510.dT = TC_1195_1510.port_a.T - TC_1195_1510.port_b.T; TC_1195_1510.port_a.Q_flow = TC_1195_1510.Q_flow; TC_1195_1510.port_b.Q_flow = -TC_1195_1510.Q_flow; TC_1195_1578.Q_flow = TC_1195_1578.G * TC_1195_1578.dT; TC_1195_1578.dT = TC_1195_1578.port_a.T - TC_1195_1578.port_b.T; TC_1195_1578.port_a.Q_flow = TC_1195_1578.Q_flow; TC_1195_1578.port_b.Q_flow = -TC_1195_1578.Q_flow; TC_1196_1197.Q_flow = TC_1196_1197.G * TC_1196_1197.dT; TC_1196_1197.dT = TC_1196_1197.port_a.T - TC_1196_1197.port_b.T; TC_1196_1197.port_a.Q_flow = TC_1196_1197.Q_flow; TC_1196_1197.port_b.Q_flow = -TC_1196_1197.Q_flow; TC_1196_1332.Q_flow = TC_1196_1332.G * TC_1196_1332.dT; TC_1196_1332.dT = TC_1196_1332.port_a.T - TC_1196_1332.port_b.T; TC_1196_1332.port_a.Q_flow = TC_1196_1332.Q_flow; TC_1196_1332.port_b.Q_flow = -TC_1196_1332.Q_flow; TC_1196_1511.Q_flow = TC_1196_1511.G * TC_1196_1511.dT; TC_1196_1511.dT = TC_1196_1511.port_a.T - TC_1196_1511.port_b.T; TC_1196_1511.port_a.Q_flow = TC_1196_1511.Q_flow; TC_1196_1511.port_b.Q_flow = -TC_1196_1511.Q_flow; TC_1196_1579.Q_flow = TC_1196_1579.G * TC_1196_1579.dT; TC_1196_1579.dT = TC_1196_1579.port_a.T - TC_1196_1579.port_b.T; TC_1196_1579.port_a.Q_flow = TC_1196_1579.Q_flow; TC_1196_1579.port_b.Q_flow = -TC_1196_1579.Q_flow; TC_1197_1198.Q_flow = TC_1197_1198.G * TC_1197_1198.dT; TC_1197_1198.dT = TC_1197_1198.port_a.T - TC_1197_1198.port_b.T; TC_1197_1198.port_a.Q_flow = TC_1197_1198.Q_flow; TC_1197_1198.port_b.Q_flow = -TC_1197_1198.Q_flow; TC_1197_1205.Q_flow = TC_1197_1205.G * TC_1197_1205.dT; TC_1197_1205.dT = TC_1197_1205.port_a.T - TC_1197_1205.port_b.T; TC_1197_1205.port_a.Q_flow = TC_1197_1205.Q_flow; TC_1197_1205.port_b.Q_flow = -TC_1197_1205.Q_flow; TC_1197_1333.Q_flow = TC_1197_1333.G * TC_1197_1333.dT; TC_1197_1333.dT = TC_1197_1333.port_a.T - TC_1197_1333.port_b.T; TC_1197_1333.port_a.Q_flow = TC_1197_1333.Q_flow; TC_1197_1333.port_b.Q_flow = -TC_1197_1333.Q_flow; TC_1197_1580.Q_flow = TC_1197_1580.G * TC_1197_1580.dT; TC_1197_1580.dT = TC_1197_1580.port_a.T - TC_1197_1580.port_b.T; TC_1197_1580.port_a.Q_flow = TC_1197_1580.Q_flow; TC_1197_1580.port_b.Q_flow = -TC_1197_1580.Q_flow; TC_1198_1206.Q_flow = TC_1198_1206.G * TC_1198_1206.dT; TC_1198_1206.dT = TC_1198_1206.port_a.T - TC_1198_1206.port_b.T; TC_1198_1206.port_a.Q_flow = TC_1198_1206.Q_flow; TC_1198_1206.port_b.Q_flow = -TC_1198_1206.Q_flow; TC_1198_1334.Q_flow = TC_1198_1334.G * TC_1198_1334.dT; TC_1198_1334.dT = TC_1198_1334.port_a.T - TC_1198_1334.port_b.T; TC_1198_1334.port_a.Q_flow = TC_1198_1334.Q_flow; TC_1198_1334.port_b.Q_flow = -TC_1198_1334.Q_flow; TC_1199_1200.Q_flow = TC_1199_1200.G * TC_1199_1200.dT; TC_1199_1200.dT = TC_1199_1200.port_a.T - TC_1199_1200.port_b.T; TC_1199_1200.port_a.Q_flow = TC_1199_1200.Q_flow; TC_1199_1200.port_b.Q_flow = -TC_1199_1200.Q_flow; TC_1199_1207.Q_flow = TC_1199_1207.G * TC_1199_1207.dT; TC_1199_1207.dT = TC_1199_1207.port_a.T - TC_1199_1207.port_b.T; TC_1199_1207.port_a.Q_flow = TC_1199_1207.Q_flow; TC_1199_1207.port_b.Q_flow = -TC_1199_1207.Q_flow; TC_1199_1335.Q_flow = TC_1199_1335.G * TC_1199_1335.dT; TC_1199_1335.dT = TC_1199_1335.port_a.T - TC_1199_1335.port_b.T; TC_1199_1335.port_a.Q_flow = TC_1199_1335.Q_flow; TC_1199_1335.port_b.Q_flow = -TC_1199_1335.Q_flow; TC_1200_1201.Q_flow = TC_1200_1201.G * TC_1200_1201.dT; TC_1200_1201.dT = TC_1200_1201.port_a.T - TC_1200_1201.port_b.T; TC_1200_1201.port_a.Q_flow = TC_1200_1201.Q_flow; TC_1200_1201.port_b.Q_flow = -TC_1200_1201.Q_flow; TC_1200_1208.Q_flow = TC_1200_1208.G * TC_1200_1208.dT; TC_1200_1208.dT = TC_1200_1208.port_a.T - TC_1200_1208.port_b.T; TC_1200_1208.port_a.Q_flow = TC_1200_1208.Q_flow; TC_1200_1208.port_b.Q_flow = -TC_1200_1208.Q_flow; TC_1200_1336.Q_flow = TC_1200_1336.G * TC_1200_1336.dT; TC_1200_1336.dT = TC_1200_1336.port_a.T - TC_1200_1336.port_b.T; TC_1200_1336.port_a.Q_flow = TC_1200_1336.Q_flow; TC_1200_1336.port_b.Q_flow = -TC_1200_1336.Q_flow; TC_1200_1581.Q_flow = TC_1200_1581.G * TC_1200_1581.dT; TC_1200_1581.dT = TC_1200_1581.port_a.T - TC_1200_1581.port_b.T; TC_1200_1581.port_a.Q_flow = TC_1200_1581.Q_flow; TC_1200_1581.port_b.Q_flow = -TC_1200_1581.Q_flow; TC_1201_1202.Q_flow = TC_1201_1202.G * TC_1201_1202.dT; TC_1201_1202.dT = TC_1201_1202.port_a.T - TC_1201_1202.port_b.T; TC_1201_1202.port_a.Q_flow = TC_1201_1202.Q_flow; TC_1201_1202.port_b.Q_flow = -TC_1201_1202.Q_flow; TC_1201_1209.Q_flow = TC_1201_1209.G * TC_1201_1209.dT; TC_1201_1209.dT = TC_1201_1209.port_a.T - TC_1201_1209.port_b.T; TC_1201_1209.port_a.Q_flow = TC_1201_1209.Q_flow; TC_1201_1209.port_b.Q_flow = -TC_1201_1209.Q_flow; TC_1201_1337.Q_flow = TC_1201_1337.G * TC_1201_1337.dT; TC_1201_1337.dT = TC_1201_1337.port_a.T - TC_1201_1337.port_b.T; TC_1201_1337.port_a.Q_flow = TC_1201_1337.Q_flow; TC_1201_1337.port_b.Q_flow = -TC_1201_1337.Q_flow; TC_1201_1582.Q_flow = TC_1201_1582.G * TC_1201_1582.dT; TC_1201_1582.dT = TC_1201_1582.port_a.T - TC_1201_1582.port_b.T; TC_1201_1582.port_a.Q_flow = TC_1201_1582.Q_flow; TC_1201_1582.port_b.Q_flow = -TC_1201_1582.Q_flow; TC_1202_1203.Q_flow = TC_1202_1203.G * TC_1202_1203.dT; TC_1202_1203.dT = TC_1202_1203.port_a.T - TC_1202_1203.port_b.T; TC_1202_1203.port_a.Q_flow = TC_1202_1203.Q_flow; TC_1202_1203.port_b.Q_flow = -TC_1202_1203.Q_flow; TC_1202_1210.Q_flow = TC_1202_1210.G * TC_1202_1210.dT; TC_1202_1210.dT = TC_1202_1210.port_a.T - TC_1202_1210.port_b.T; TC_1202_1210.port_a.Q_flow = TC_1202_1210.Q_flow; TC_1202_1210.port_b.Q_flow = -TC_1202_1210.Q_flow; TC_1202_1338.Q_flow = TC_1202_1338.G * TC_1202_1338.dT; TC_1202_1338.dT = TC_1202_1338.port_a.T - TC_1202_1338.port_b.T; TC_1202_1338.port_a.Q_flow = TC_1202_1338.Q_flow; TC_1202_1338.port_b.Q_flow = -TC_1202_1338.Q_flow; TC_1202_1583.Q_flow = TC_1202_1583.G * TC_1202_1583.dT; TC_1202_1583.dT = TC_1202_1583.port_a.T - TC_1202_1583.port_b.T; TC_1202_1583.port_a.Q_flow = TC_1202_1583.Q_flow; TC_1202_1583.port_b.Q_flow = -TC_1202_1583.Q_flow; TC_1203_1204.Q_flow = TC_1203_1204.G * TC_1203_1204.dT; TC_1203_1204.dT = TC_1203_1204.port_a.T - TC_1203_1204.port_b.T; TC_1203_1204.port_a.Q_flow = TC_1203_1204.Q_flow; TC_1203_1204.port_b.Q_flow = -TC_1203_1204.Q_flow; TC_1203_1211.Q_flow = TC_1203_1211.G * TC_1203_1211.dT; TC_1203_1211.dT = TC_1203_1211.port_a.T - TC_1203_1211.port_b.T; TC_1203_1211.port_a.Q_flow = TC_1203_1211.Q_flow; TC_1203_1211.port_b.Q_flow = -TC_1203_1211.Q_flow; TC_1203_1339.Q_flow = TC_1203_1339.G * TC_1203_1339.dT; TC_1203_1339.dT = TC_1203_1339.port_a.T - TC_1203_1339.port_b.T; TC_1203_1339.port_a.Q_flow = TC_1203_1339.Q_flow; TC_1203_1339.port_b.Q_flow = -TC_1203_1339.Q_flow; TC_1203_1584.Q_flow = TC_1203_1584.G * TC_1203_1584.dT; TC_1203_1584.dT = TC_1203_1584.port_a.T - TC_1203_1584.port_b.T; TC_1203_1584.port_a.Q_flow = TC_1203_1584.Q_flow; TC_1203_1584.port_b.Q_flow = -TC_1203_1584.Q_flow; TC_1204_1212.Q_flow = TC_1204_1212.G * TC_1204_1212.dT; TC_1204_1212.dT = TC_1204_1212.port_a.T - TC_1204_1212.port_b.T; TC_1204_1212.port_a.Q_flow = TC_1204_1212.Q_flow; TC_1204_1212.port_b.Q_flow = -TC_1204_1212.Q_flow; TC_1204_1340.Q_flow = TC_1204_1340.G * TC_1204_1340.dT; TC_1204_1340.dT = TC_1204_1340.port_a.T - TC_1204_1340.port_b.T; TC_1204_1340.port_a.Q_flow = TC_1204_1340.Q_flow; TC_1204_1340.port_b.Q_flow = -TC_1204_1340.Q_flow; TC_1204_1509.Q_flow = TC_1204_1509.G * TC_1204_1509.dT; TC_1204_1509.dT = TC_1204_1509.port_a.T - TC_1204_1509.port_b.T; TC_1204_1509.port_a.Q_flow = TC_1204_1509.Q_flow; TC_1204_1509.port_b.Q_flow = -TC_1204_1509.Q_flow; TC_1204_1585.Q_flow = TC_1204_1585.G * TC_1204_1585.dT; TC_1204_1585.dT = TC_1204_1585.port_a.T - TC_1204_1585.port_b.T; TC_1204_1585.port_a.Q_flow = TC_1204_1585.Q_flow; TC_1204_1585.port_b.Q_flow = -TC_1204_1585.Q_flow; TC_1205_1206.Q_flow = TC_1205_1206.G * TC_1205_1206.dT; TC_1205_1206.dT = TC_1205_1206.port_a.T - TC_1205_1206.port_b.T; TC_1205_1206.port_a.Q_flow = TC_1205_1206.Q_flow; TC_1205_1206.port_b.Q_flow = -TC_1205_1206.Q_flow; TC_1205_1213.Q_flow = TC_1205_1213.G * TC_1205_1213.dT; TC_1205_1213.dT = TC_1205_1213.port_a.T - TC_1205_1213.port_b.T; TC_1205_1213.port_a.Q_flow = TC_1205_1213.Q_flow; TC_1205_1213.port_b.Q_flow = -TC_1205_1213.Q_flow; TC_1205_1341.Q_flow = TC_1205_1341.G * TC_1205_1341.dT; TC_1205_1341.dT = TC_1205_1341.port_a.T - TC_1205_1341.port_b.T; TC_1205_1341.port_a.Q_flow = TC_1205_1341.Q_flow; TC_1205_1341.port_b.Q_flow = -TC_1205_1341.Q_flow; TC_1205_1511.Q_flow = TC_1205_1511.G * TC_1205_1511.dT; TC_1205_1511.dT = TC_1205_1511.port_a.T - TC_1205_1511.port_b.T; TC_1205_1511.port_a.Q_flow = TC_1205_1511.Q_flow; TC_1205_1511.port_b.Q_flow = -TC_1205_1511.Q_flow; TC_1205_1589.Q_flow = TC_1205_1589.G * TC_1205_1589.dT; TC_1205_1589.dT = TC_1205_1589.port_a.T - TC_1205_1589.port_b.T; TC_1205_1589.port_a.Q_flow = TC_1205_1589.Q_flow; TC_1205_1589.port_b.Q_flow = -TC_1205_1589.Q_flow; TC_1206_1214.Q_flow = TC_1206_1214.G * TC_1206_1214.dT; TC_1206_1214.dT = TC_1206_1214.port_a.T - TC_1206_1214.port_b.T; TC_1206_1214.port_a.Q_flow = TC_1206_1214.Q_flow; TC_1206_1214.port_b.Q_flow = -TC_1206_1214.Q_flow; TC_1206_1342.Q_flow = TC_1206_1342.G * TC_1206_1342.dT; TC_1206_1342.dT = TC_1206_1342.port_a.T - TC_1206_1342.port_b.T; TC_1206_1342.port_a.Q_flow = TC_1206_1342.Q_flow; TC_1206_1342.port_b.Q_flow = -TC_1206_1342.Q_flow; TC_1207_1208.Q_flow = TC_1207_1208.G * TC_1207_1208.dT; TC_1207_1208.dT = TC_1207_1208.port_a.T - TC_1207_1208.port_b.T; TC_1207_1208.port_a.Q_flow = TC_1207_1208.Q_flow; TC_1207_1208.port_b.Q_flow = -TC_1207_1208.Q_flow; TC_1207_1215.Q_flow = TC_1207_1215.G * TC_1207_1215.dT; TC_1207_1215.dT = TC_1207_1215.port_a.T - TC_1207_1215.port_b.T; TC_1207_1215.port_a.Q_flow = TC_1207_1215.Q_flow; TC_1207_1215.port_b.Q_flow = -TC_1207_1215.Q_flow; TC_1207_1343.Q_flow = TC_1207_1343.G * TC_1207_1343.dT; TC_1207_1343.dT = TC_1207_1343.port_a.T - TC_1207_1343.port_b.T; TC_1207_1343.port_a.Q_flow = TC_1207_1343.Q_flow; TC_1207_1343.port_b.Q_flow = -TC_1207_1343.Q_flow; TC_1208_1209.Q_flow = TC_1208_1209.G * TC_1208_1209.dT; TC_1208_1209.dT = TC_1208_1209.port_a.T - TC_1208_1209.port_b.T; TC_1208_1209.port_a.Q_flow = TC_1208_1209.Q_flow; TC_1208_1209.port_b.Q_flow = -TC_1208_1209.Q_flow; TC_1208_1216.Q_flow = TC_1208_1216.G * TC_1208_1216.dT; TC_1208_1216.dT = TC_1208_1216.port_a.T - TC_1208_1216.port_b.T; TC_1208_1216.port_a.Q_flow = TC_1208_1216.Q_flow; TC_1208_1216.port_b.Q_flow = -TC_1208_1216.Q_flow; TC_1208_1344.Q_flow = TC_1208_1344.G * TC_1208_1344.dT; TC_1208_1344.dT = TC_1208_1344.port_a.T - TC_1208_1344.port_b.T; TC_1208_1344.port_a.Q_flow = TC_1208_1344.Q_flow; TC_1208_1344.port_b.Q_flow = -TC_1208_1344.Q_flow; TC_1208_1590.Q_flow = TC_1208_1590.G * TC_1208_1590.dT; TC_1208_1590.dT = TC_1208_1590.port_a.T - TC_1208_1590.port_b.T; TC_1208_1590.port_a.Q_flow = TC_1208_1590.Q_flow; TC_1208_1590.port_b.Q_flow = -TC_1208_1590.Q_flow; TC_1209_1210.Q_flow = TC_1209_1210.G * TC_1209_1210.dT; TC_1209_1210.dT = TC_1209_1210.port_a.T - TC_1209_1210.port_b.T; TC_1209_1210.port_a.Q_flow = TC_1209_1210.Q_flow; TC_1209_1210.port_b.Q_flow = -TC_1209_1210.Q_flow; TC_1209_1217.Q_flow = TC_1209_1217.G * TC_1209_1217.dT; TC_1209_1217.dT = TC_1209_1217.port_a.T - TC_1209_1217.port_b.T; TC_1209_1217.port_a.Q_flow = TC_1209_1217.Q_flow; TC_1209_1217.port_b.Q_flow = -TC_1209_1217.Q_flow; TC_1209_1345.Q_flow = TC_1209_1345.G * TC_1209_1345.dT; TC_1209_1345.dT = TC_1209_1345.port_a.T - TC_1209_1345.port_b.T; TC_1209_1345.port_a.Q_flow = TC_1209_1345.Q_flow; TC_1209_1345.port_b.Q_flow = -TC_1209_1345.Q_flow; TC_1209_1591.Q_flow = TC_1209_1591.G * TC_1209_1591.dT; TC_1209_1591.dT = TC_1209_1591.port_a.T - TC_1209_1591.port_b.T; TC_1209_1591.port_a.Q_flow = TC_1209_1591.Q_flow; TC_1209_1591.port_b.Q_flow = -TC_1209_1591.Q_flow; TC_1210_1211.Q_flow = TC_1210_1211.G * TC_1210_1211.dT; TC_1210_1211.dT = TC_1210_1211.port_a.T - TC_1210_1211.port_b.T; TC_1210_1211.port_a.Q_flow = TC_1210_1211.Q_flow; TC_1210_1211.port_b.Q_flow = -TC_1210_1211.Q_flow; TC_1210_1218.Q_flow = TC_1210_1218.G * TC_1210_1218.dT; TC_1210_1218.dT = TC_1210_1218.port_a.T - TC_1210_1218.port_b.T; TC_1210_1218.port_a.Q_flow = TC_1210_1218.Q_flow; TC_1210_1218.port_b.Q_flow = -TC_1210_1218.Q_flow; TC_1210_1346.Q_flow = TC_1210_1346.G * TC_1210_1346.dT; TC_1210_1346.dT = TC_1210_1346.port_a.T - TC_1210_1346.port_b.T; TC_1210_1346.port_a.Q_flow = TC_1210_1346.Q_flow; TC_1210_1346.port_b.Q_flow = -TC_1210_1346.Q_flow; TC_1210_1592.Q_flow = TC_1210_1592.G * TC_1210_1592.dT; TC_1210_1592.dT = TC_1210_1592.port_a.T - TC_1210_1592.port_b.T; TC_1210_1592.port_a.Q_flow = TC_1210_1592.Q_flow; TC_1210_1592.port_b.Q_flow = -TC_1210_1592.Q_flow; TC_1211_1212.Q_flow = TC_1211_1212.G * TC_1211_1212.dT; TC_1211_1212.dT = TC_1211_1212.port_a.T - TC_1211_1212.port_b.T; TC_1211_1212.port_a.Q_flow = TC_1211_1212.Q_flow; TC_1211_1212.port_b.Q_flow = -TC_1211_1212.Q_flow; TC_1211_1219.Q_flow = TC_1211_1219.G * TC_1211_1219.dT; TC_1211_1219.dT = TC_1211_1219.port_a.T - TC_1211_1219.port_b.T; TC_1211_1219.port_a.Q_flow = TC_1211_1219.Q_flow; TC_1211_1219.port_b.Q_flow = -TC_1211_1219.Q_flow; TC_1211_1347.Q_flow = TC_1211_1347.G * TC_1211_1347.dT; TC_1211_1347.dT = TC_1211_1347.port_a.T - TC_1211_1347.port_b.T; TC_1211_1347.port_a.Q_flow = TC_1211_1347.Q_flow; TC_1211_1347.port_b.Q_flow = -TC_1211_1347.Q_flow; TC_1211_1593.Q_flow = TC_1211_1593.G * TC_1211_1593.dT; TC_1211_1593.dT = TC_1211_1593.port_a.T - TC_1211_1593.port_b.T; TC_1211_1593.port_a.Q_flow = TC_1211_1593.Q_flow; TC_1211_1593.port_b.Q_flow = -TC_1211_1593.Q_flow; TC_1212_1220.Q_flow = TC_1212_1220.G * TC_1212_1220.dT; TC_1212_1220.dT = TC_1212_1220.port_a.T - TC_1212_1220.port_b.T; TC_1212_1220.port_a.Q_flow = TC_1212_1220.Q_flow; TC_1212_1220.port_b.Q_flow = -TC_1212_1220.Q_flow; TC_1212_1348.Q_flow = TC_1212_1348.G * TC_1212_1348.dT; TC_1212_1348.dT = TC_1212_1348.port_a.T - TC_1212_1348.port_b.T; TC_1212_1348.port_a.Q_flow = TC_1212_1348.Q_flow; TC_1212_1348.port_b.Q_flow = -TC_1212_1348.Q_flow; TC_1212_1512.Q_flow = TC_1212_1512.G * TC_1212_1512.dT; TC_1212_1512.dT = TC_1212_1512.port_a.T - TC_1212_1512.port_b.T; TC_1212_1512.port_a.Q_flow = TC_1212_1512.Q_flow; TC_1212_1512.port_b.Q_flow = -TC_1212_1512.Q_flow; TC_1212_1594.Q_flow = TC_1212_1594.G * TC_1212_1594.dT; TC_1212_1594.dT = TC_1212_1594.port_a.T - TC_1212_1594.port_b.T; TC_1212_1594.port_a.Q_flow = TC_1212_1594.Q_flow; TC_1212_1594.port_b.Q_flow = -TC_1212_1594.Q_flow; TC_1213_1214.Q_flow = TC_1213_1214.G * TC_1213_1214.dT; TC_1213_1214.dT = TC_1213_1214.port_a.T - TC_1213_1214.port_b.T; TC_1213_1214.port_a.Q_flow = TC_1213_1214.Q_flow; TC_1213_1214.port_b.Q_flow = -TC_1213_1214.Q_flow; TC_1213_1221.Q_flow = TC_1213_1221.G * TC_1213_1221.dT; TC_1213_1221.dT = TC_1213_1221.port_a.T - TC_1213_1221.port_b.T; TC_1213_1221.port_a.Q_flow = TC_1213_1221.Q_flow; TC_1213_1221.port_b.Q_flow = -TC_1213_1221.Q_flow; TC_1213_1349.Q_flow = TC_1213_1349.G * TC_1213_1349.dT; TC_1213_1349.dT = TC_1213_1349.port_a.T - TC_1213_1349.port_b.T; TC_1213_1349.port_a.Q_flow = TC_1213_1349.Q_flow; TC_1213_1349.port_b.Q_flow = -TC_1213_1349.Q_flow; TC_1213_1514.Q_flow = TC_1213_1514.G * TC_1213_1514.dT; TC_1213_1514.dT = TC_1213_1514.port_a.T - TC_1213_1514.port_b.T; TC_1213_1514.port_a.Q_flow = TC_1213_1514.Q_flow; TC_1213_1514.port_b.Q_flow = -TC_1213_1514.Q_flow; TC_1213_1598.Q_flow = TC_1213_1598.G * TC_1213_1598.dT; TC_1213_1598.dT = TC_1213_1598.port_a.T - TC_1213_1598.port_b.T; TC_1213_1598.port_a.Q_flow = TC_1213_1598.Q_flow; TC_1213_1598.port_b.Q_flow = -TC_1213_1598.Q_flow; TC_1214_1222.Q_flow = TC_1214_1222.G * TC_1214_1222.dT; TC_1214_1222.dT = TC_1214_1222.port_a.T - TC_1214_1222.port_b.T; TC_1214_1222.port_a.Q_flow = TC_1214_1222.Q_flow; TC_1214_1222.port_b.Q_flow = -TC_1214_1222.Q_flow; TC_1214_1350.Q_flow = TC_1214_1350.G * TC_1214_1350.dT; TC_1214_1350.dT = TC_1214_1350.port_a.T - TC_1214_1350.port_b.T; TC_1214_1350.port_a.Q_flow = TC_1214_1350.Q_flow; TC_1214_1350.port_b.Q_flow = -TC_1214_1350.Q_flow; TC_1215_1216.Q_flow = TC_1215_1216.G * TC_1215_1216.dT; TC_1215_1216.dT = TC_1215_1216.port_a.T - TC_1215_1216.port_b.T; TC_1215_1216.port_a.Q_flow = TC_1215_1216.Q_flow; TC_1215_1216.port_b.Q_flow = -TC_1215_1216.Q_flow; TC_1215_1223.Q_flow = TC_1215_1223.G * TC_1215_1223.dT; TC_1215_1223.dT = TC_1215_1223.port_a.T - TC_1215_1223.port_b.T; TC_1215_1223.port_a.Q_flow = TC_1215_1223.Q_flow; TC_1215_1223.port_b.Q_flow = -TC_1215_1223.Q_flow; TC_1215_1351.Q_flow = TC_1215_1351.G * TC_1215_1351.dT; TC_1215_1351.dT = TC_1215_1351.port_a.T - TC_1215_1351.port_b.T; TC_1215_1351.port_a.Q_flow = TC_1215_1351.Q_flow; TC_1215_1351.port_b.Q_flow = -TC_1215_1351.Q_flow; TC_1216_1217.Q_flow = TC_1216_1217.G * TC_1216_1217.dT; TC_1216_1217.dT = TC_1216_1217.port_a.T - TC_1216_1217.port_b.T; TC_1216_1217.port_a.Q_flow = TC_1216_1217.Q_flow; TC_1216_1217.port_b.Q_flow = -TC_1216_1217.Q_flow; TC_1216_1224.Q_flow = TC_1216_1224.G * TC_1216_1224.dT; TC_1216_1224.dT = TC_1216_1224.port_a.T - TC_1216_1224.port_b.T; TC_1216_1224.port_a.Q_flow = TC_1216_1224.Q_flow; TC_1216_1224.port_b.Q_flow = -TC_1216_1224.Q_flow; TC_1216_1352.Q_flow = TC_1216_1352.G * TC_1216_1352.dT; TC_1216_1352.dT = TC_1216_1352.port_a.T - TC_1216_1352.port_b.T; TC_1216_1352.port_a.Q_flow = TC_1216_1352.Q_flow; TC_1216_1352.port_b.Q_flow = -TC_1216_1352.Q_flow; TC_1216_1599.Q_flow = TC_1216_1599.G * TC_1216_1599.dT; TC_1216_1599.dT = TC_1216_1599.port_a.T - TC_1216_1599.port_b.T; TC_1216_1599.port_a.Q_flow = TC_1216_1599.Q_flow; TC_1216_1599.port_b.Q_flow = -TC_1216_1599.Q_flow; TC_1217_1218.Q_flow = TC_1217_1218.G * TC_1217_1218.dT; TC_1217_1218.dT = TC_1217_1218.port_a.T - TC_1217_1218.port_b.T; TC_1217_1218.port_a.Q_flow = TC_1217_1218.Q_flow; TC_1217_1218.port_b.Q_flow = -TC_1217_1218.Q_flow; TC_1217_1353.Q_flow = TC_1217_1353.G * TC_1217_1353.dT; TC_1217_1353.dT = TC_1217_1353.port_a.T - TC_1217_1353.port_b.T; TC_1217_1353.port_a.Q_flow = TC_1217_1353.Q_flow; TC_1217_1353.port_b.Q_flow = -TC_1217_1353.Q_flow; TC_1217_1518.Q_flow = TC_1217_1518.G * TC_1217_1518.dT; TC_1217_1518.dT = TC_1217_1518.port_a.T - TC_1217_1518.port_b.T; TC_1217_1518.port_a.Q_flow = TC_1217_1518.Q_flow; TC_1217_1518.port_b.Q_flow = -TC_1217_1518.Q_flow; TC_1217_1600.Q_flow = TC_1217_1600.G * TC_1217_1600.dT; TC_1217_1600.dT = TC_1217_1600.port_a.T - TC_1217_1600.port_b.T; TC_1217_1600.port_a.Q_flow = TC_1217_1600.Q_flow; TC_1217_1600.port_b.Q_flow = -TC_1217_1600.Q_flow; TC_1218_1219.Q_flow = TC_1218_1219.G * TC_1218_1219.dT; TC_1218_1219.dT = TC_1218_1219.port_a.T - TC_1218_1219.port_b.T; TC_1218_1219.port_a.Q_flow = TC_1218_1219.Q_flow; TC_1218_1219.port_b.Q_flow = -TC_1218_1219.Q_flow; TC_1218_1354.Q_flow = TC_1218_1354.G * TC_1218_1354.dT; TC_1218_1354.dT = TC_1218_1354.port_a.T - TC_1218_1354.port_b.T; TC_1218_1354.port_a.Q_flow = TC_1218_1354.Q_flow; TC_1218_1354.port_b.Q_flow = -TC_1218_1354.Q_flow; TC_1218_1519.Q_flow = TC_1218_1519.G * TC_1218_1519.dT; TC_1218_1519.dT = TC_1218_1519.port_a.T - TC_1218_1519.port_b.T; TC_1218_1519.port_a.Q_flow = TC_1218_1519.Q_flow; TC_1218_1519.port_b.Q_flow = -TC_1218_1519.Q_flow; TC_1218_1601.Q_flow = TC_1218_1601.G * TC_1218_1601.dT; TC_1218_1601.dT = TC_1218_1601.port_a.T - TC_1218_1601.port_b.T; TC_1218_1601.port_a.Q_flow = TC_1218_1601.Q_flow; TC_1218_1601.port_b.Q_flow = -TC_1218_1601.Q_flow; TC_1219_1220.Q_flow = TC_1219_1220.G * TC_1219_1220.dT; TC_1219_1220.dT = TC_1219_1220.port_a.T - TC_1219_1220.port_b.T; TC_1219_1220.port_a.Q_flow = TC_1219_1220.Q_flow; TC_1219_1220.port_b.Q_flow = -TC_1219_1220.Q_flow; TC_1219_1355.Q_flow = TC_1219_1355.G * TC_1219_1355.dT; TC_1219_1355.dT = TC_1219_1355.port_a.T - TC_1219_1355.port_b.T; TC_1219_1355.port_a.Q_flow = TC_1219_1355.Q_flow; TC_1219_1355.port_b.Q_flow = -TC_1219_1355.Q_flow; TC_1219_1520.Q_flow = TC_1219_1520.G * TC_1219_1520.dT; TC_1219_1520.dT = TC_1219_1520.port_a.T - TC_1219_1520.port_b.T; TC_1219_1520.port_a.Q_flow = TC_1219_1520.Q_flow; TC_1219_1520.port_b.Q_flow = -TC_1219_1520.Q_flow; TC_1219_1602.Q_flow = TC_1219_1602.G * TC_1219_1602.dT; TC_1219_1602.dT = TC_1219_1602.port_a.T - TC_1219_1602.port_b.T; TC_1219_1602.port_a.Q_flow = TC_1219_1602.Q_flow; TC_1219_1602.port_b.Q_flow = -TC_1219_1602.Q_flow; TC_1220_1225.Q_flow = TC_1220_1225.G * TC_1220_1225.dT; TC_1220_1225.dT = TC_1220_1225.port_a.T - TC_1220_1225.port_b.T; TC_1220_1225.port_a.Q_flow = TC_1220_1225.Q_flow; TC_1220_1225.port_b.Q_flow = -TC_1220_1225.Q_flow; TC_1220_1356.Q_flow = TC_1220_1356.G * TC_1220_1356.dT; TC_1220_1356.dT = TC_1220_1356.port_a.T - TC_1220_1356.port_b.T; TC_1220_1356.port_a.Q_flow = TC_1220_1356.Q_flow; TC_1220_1356.port_b.Q_flow = -TC_1220_1356.Q_flow; TC_1220_1515.Q_flow = TC_1220_1515.G * TC_1220_1515.dT; TC_1220_1515.dT = TC_1220_1515.port_a.T - TC_1220_1515.port_b.T; TC_1220_1515.port_a.Q_flow = TC_1220_1515.Q_flow; TC_1220_1515.port_b.Q_flow = -TC_1220_1515.Q_flow; TC_1220_1603.Q_flow = TC_1220_1603.G * TC_1220_1603.dT; TC_1220_1603.dT = TC_1220_1603.port_a.T - TC_1220_1603.port_b.T; TC_1220_1603.port_a.Q_flow = TC_1220_1603.Q_flow; TC_1220_1603.port_b.Q_flow = -TC_1220_1603.Q_flow; TC_1221_1222.Q_flow = TC_1221_1222.G * TC_1221_1222.dT; TC_1221_1222.dT = TC_1221_1222.port_a.T - TC_1221_1222.port_b.T; TC_1221_1222.port_a.Q_flow = TC_1221_1222.Q_flow; TC_1221_1222.port_b.Q_flow = -TC_1221_1222.Q_flow; TC_1221_1229.Q_flow = TC_1221_1229.G * TC_1221_1229.dT; TC_1221_1229.dT = TC_1221_1229.port_a.T - TC_1221_1229.port_b.T; TC_1221_1229.port_a.Q_flow = TC_1221_1229.Q_flow; TC_1221_1229.port_b.Q_flow = -TC_1221_1229.Q_flow; TC_1221_1357.Q_flow = TC_1221_1357.G * TC_1221_1357.dT; TC_1221_1357.dT = TC_1221_1357.port_a.T - TC_1221_1357.port_b.T; TC_1221_1357.port_a.Q_flow = TC_1221_1357.Q_flow; TC_1221_1357.port_b.Q_flow = -TC_1221_1357.Q_flow; TC_1221_1517.Q_flow = TC_1221_1517.G * TC_1221_1517.dT; TC_1221_1517.dT = TC_1221_1517.port_a.T - TC_1221_1517.port_b.T; TC_1221_1517.port_a.Q_flow = TC_1221_1517.Q_flow; TC_1221_1517.port_b.Q_flow = -TC_1221_1517.Q_flow; TC_1221_1607.Q_flow = TC_1221_1607.G * TC_1221_1607.dT; TC_1221_1607.dT = TC_1221_1607.port_a.T - TC_1221_1607.port_b.T; TC_1221_1607.port_a.Q_flow = TC_1221_1607.Q_flow; TC_1221_1607.port_b.Q_flow = -TC_1221_1607.Q_flow; TC_1222_1230.Q_flow = TC_1222_1230.G * TC_1222_1230.dT; TC_1222_1230.dT = TC_1222_1230.port_a.T - TC_1222_1230.port_b.T; TC_1222_1230.port_a.Q_flow = TC_1222_1230.Q_flow; TC_1222_1230.port_b.Q_flow = -TC_1222_1230.Q_flow; TC_1222_1358.Q_flow = TC_1222_1358.G * TC_1222_1358.dT; TC_1222_1358.dT = TC_1222_1358.port_a.T - TC_1222_1358.port_b.T; TC_1222_1358.port_a.Q_flow = TC_1222_1358.Q_flow; TC_1222_1358.port_b.Q_flow = -TC_1222_1358.Q_flow; TC_1223_1224.Q_flow = TC_1223_1224.G * TC_1223_1224.dT; TC_1223_1224.dT = TC_1223_1224.port_a.T - TC_1223_1224.port_b.T; TC_1223_1224.port_a.Q_flow = TC_1223_1224.Q_flow; TC_1223_1224.port_b.Q_flow = -TC_1223_1224.Q_flow; TC_1223_1231.Q_flow = TC_1223_1231.G * TC_1223_1231.dT; TC_1223_1231.dT = TC_1223_1231.port_a.T - TC_1223_1231.port_b.T; TC_1223_1231.port_a.Q_flow = TC_1223_1231.Q_flow; TC_1223_1231.port_b.Q_flow = -TC_1223_1231.Q_flow; TC_1223_1359.Q_flow = TC_1223_1359.G * TC_1223_1359.dT; TC_1223_1359.dT = TC_1223_1359.port_a.T - TC_1223_1359.port_b.T; TC_1223_1359.port_a.Q_flow = TC_1223_1359.Q_flow; TC_1223_1359.port_b.Q_flow = -TC_1223_1359.Q_flow; TC_1224_1232.Q_flow = TC_1224_1232.G * TC_1224_1232.dT; TC_1224_1232.dT = TC_1224_1232.port_a.T - TC_1224_1232.port_b.T; TC_1224_1232.port_a.Q_flow = TC_1224_1232.Q_flow; TC_1224_1232.port_b.Q_flow = -TC_1224_1232.Q_flow; TC_1224_1360.Q_flow = TC_1224_1360.G * TC_1224_1360.dT; TC_1224_1360.dT = TC_1224_1360.port_a.T - TC_1224_1360.port_b.T; TC_1224_1360.port_a.Q_flow = TC_1224_1360.Q_flow; TC_1224_1360.port_b.Q_flow = -TC_1224_1360.Q_flow; TC_1224_1518.Q_flow = TC_1224_1518.G * TC_1224_1518.dT; TC_1224_1518.dT = TC_1224_1518.port_a.T - TC_1224_1518.port_b.T; TC_1224_1518.port_a.Q_flow = TC_1224_1518.Q_flow; TC_1224_1518.port_b.Q_flow = -TC_1224_1518.Q_flow; TC_1224_1527.Q_flow = TC_1224_1527.G * TC_1224_1527.dT; TC_1224_1527.dT = TC_1224_1527.port_a.T - TC_1224_1527.port_b.T; TC_1224_1527.port_a.Q_flow = TC_1224_1527.Q_flow; TC_1224_1527.port_b.Q_flow = -TC_1224_1527.Q_flow; TC_1225_1226.Q_flow = TC_1225_1226.G * TC_1225_1226.dT; TC_1225_1226.dT = TC_1225_1226.port_a.T - TC_1225_1226.port_b.T; TC_1225_1226.port_a.Q_flow = TC_1225_1226.Q_flow; TC_1225_1226.port_b.Q_flow = -TC_1225_1226.Q_flow; TC_1225_1233.Q_flow = TC_1225_1233.G * TC_1225_1233.dT; TC_1225_1233.dT = TC_1225_1233.port_a.T - TC_1225_1233.port_b.T; TC_1225_1233.port_a.Q_flow = TC_1225_1233.Q_flow; TC_1225_1233.port_b.Q_flow = -TC_1225_1233.Q_flow; TC_1225_1364.Q_flow = TC_1225_1364.G * TC_1225_1364.dT; TC_1225_1364.dT = TC_1225_1364.port_a.T - TC_1225_1364.port_b.T; TC_1225_1364.port_a.Q_flow = TC_1225_1364.Q_flow; TC_1225_1364.port_b.Q_flow = -TC_1225_1364.Q_flow; TC_1225_1520.Q_flow = TC_1225_1520.G * TC_1225_1520.dT; TC_1225_1520.dT = TC_1225_1520.port_a.T - TC_1225_1520.port_b.T; TC_1225_1520.port_a.Q_flow = TC_1225_1520.Q_flow; TC_1225_1520.port_b.Q_flow = -TC_1225_1520.Q_flow; TC_1225_1531.Q_flow = TC_1225_1531.G * TC_1225_1531.dT; TC_1225_1531.dT = TC_1225_1531.port_a.T - TC_1225_1531.port_b.T; TC_1225_1531.port_a.Q_flow = TC_1225_1531.Q_flow; TC_1225_1531.port_b.Q_flow = -TC_1225_1531.Q_flow; TC_1226_1227.Q_flow = TC_1226_1227.G * TC_1226_1227.dT; TC_1226_1227.dT = TC_1226_1227.port_a.T - TC_1226_1227.port_b.T; TC_1226_1227.port_a.Q_flow = TC_1226_1227.Q_flow; TC_1226_1227.port_b.Q_flow = -TC_1226_1227.Q_flow; TC_1226_1234.Q_flow = TC_1226_1234.G * TC_1226_1234.dT; TC_1226_1234.dT = TC_1226_1234.port_a.T - TC_1226_1234.port_b.T; TC_1226_1234.port_a.Q_flow = TC_1226_1234.Q_flow; TC_1226_1234.port_b.Q_flow = -TC_1226_1234.Q_flow; TC_1226_1365.Q_flow = TC_1226_1365.G * TC_1226_1365.dT; TC_1226_1365.dT = TC_1226_1365.port_a.T - TC_1226_1365.port_b.T; TC_1226_1365.port_a.Q_flow = TC_1226_1365.Q_flow; TC_1226_1365.port_b.Q_flow = -TC_1226_1365.Q_flow; TC_1226_1515.Q_flow = TC_1226_1515.G * TC_1226_1515.dT; TC_1226_1515.dT = TC_1226_1515.port_a.T - TC_1226_1515.port_b.T; TC_1226_1515.port_a.Q_flow = TC_1226_1515.Q_flow; TC_1226_1515.port_b.Q_flow = -TC_1226_1515.Q_flow; TC_1226_1532.Q_flow = TC_1226_1532.G * TC_1226_1532.dT; TC_1226_1532.dT = TC_1226_1532.port_a.T - TC_1226_1532.port_b.T; TC_1226_1532.port_a.Q_flow = TC_1226_1532.Q_flow; TC_1226_1532.port_b.Q_flow = -TC_1226_1532.Q_flow; TC_1227_1228.Q_flow = TC_1227_1228.G * TC_1227_1228.dT; TC_1227_1228.dT = TC_1227_1228.port_a.T - TC_1227_1228.port_b.T; TC_1227_1228.port_a.Q_flow = TC_1227_1228.Q_flow; TC_1227_1228.port_b.Q_flow = -TC_1227_1228.Q_flow; TC_1227_1235.Q_flow = TC_1227_1235.G * TC_1227_1235.dT; TC_1227_1235.dT = TC_1227_1235.port_a.T - TC_1227_1235.port_b.T; TC_1227_1235.port_a.Q_flow = TC_1227_1235.Q_flow; TC_1227_1235.port_b.Q_flow = -TC_1227_1235.Q_flow; TC_1227_1366.Q_flow = TC_1227_1366.G * TC_1227_1366.dT; TC_1227_1366.dT = TC_1227_1366.port_a.T - TC_1227_1366.port_b.T; TC_1227_1366.port_a.Q_flow = TC_1227_1366.Q_flow; TC_1227_1366.port_b.Q_flow = -TC_1227_1366.Q_flow; TC_1227_1516.Q_flow = TC_1227_1516.G * TC_1227_1516.dT; TC_1227_1516.dT = TC_1227_1516.port_a.T - TC_1227_1516.port_b.T; TC_1227_1516.port_a.Q_flow = TC_1227_1516.Q_flow; TC_1227_1516.port_b.Q_flow = -TC_1227_1516.Q_flow; TC_1227_1533.Q_flow = TC_1227_1533.G * TC_1227_1533.dT; TC_1227_1533.dT = TC_1227_1533.port_a.T - TC_1227_1533.port_b.T; TC_1227_1533.port_a.Q_flow = TC_1227_1533.Q_flow; TC_1227_1533.port_b.Q_flow = -TC_1227_1533.Q_flow; TC_1228_1229.Q_flow = TC_1228_1229.G * TC_1228_1229.dT; TC_1228_1229.dT = TC_1228_1229.port_a.T - TC_1228_1229.port_b.T; TC_1228_1229.port_a.Q_flow = TC_1228_1229.Q_flow; TC_1228_1229.port_b.Q_flow = -TC_1228_1229.Q_flow; TC_1228_1236.Q_flow = TC_1228_1236.G * TC_1228_1236.dT; TC_1228_1236.dT = TC_1228_1236.port_a.T - TC_1228_1236.port_b.T; TC_1228_1236.port_a.Q_flow = TC_1228_1236.Q_flow; TC_1228_1236.port_b.Q_flow = -TC_1228_1236.Q_flow; TC_1228_1367.Q_flow = TC_1228_1367.G * TC_1228_1367.dT; TC_1228_1367.dT = TC_1228_1367.port_a.T - TC_1228_1367.port_b.T; TC_1228_1367.port_a.Q_flow = TC_1228_1367.Q_flow; TC_1228_1367.port_b.Q_flow = -TC_1228_1367.Q_flow; TC_1228_1517.Q_flow = TC_1228_1517.G * TC_1228_1517.dT; TC_1228_1517.dT = TC_1228_1517.port_a.T - TC_1228_1517.port_b.T; TC_1228_1517.port_a.Q_flow = TC_1228_1517.Q_flow; TC_1228_1517.port_b.Q_flow = -TC_1228_1517.Q_flow; TC_1228_1534.Q_flow = TC_1228_1534.G * TC_1228_1534.dT; TC_1228_1534.dT = TC_1228_1534.port_a.T - TC_1228_1534.port_b.T; TC_1228_1534.port_a.Q_flow = TC_1228_1534.Q_flow; TC_1228_1534.port_b.Q_flow = -TC_1228_1534.Q_flow; TC_1229_1230.Q_flow = TC_1229_1230.G * TC_1229_1230.dT; TC_1229_1230.dT = TC_1229_1230.port_a.T - TC_1229_1230.port_b.T; TC_1229_1230.port_a.Q_flow = TC_1229_1230.Q_flow; TC_1229_1230.port_b.Q_flow = -TC_1229_1230.Q_flow; TC_1229_1237.Q_flow = TC_1229_1237.G * TC_1229_1237.dT; TC_1229_1237.dT = TC_1229_1237.port_a.T - TC_1229_1237.port_b.T; TC_1229_1237.port_a.Q_flow = TC_1229_1237.Q_flow; TC_1229_1237.port_b.Q_flow = -TC_1229_1237.Q_flow; TC_1229_1368.Q_flow = TC_1229_1368.G * TC_1229_1368.dT; TC_1229_1368.dT = TC_1229_1368.port_a.T - TC_1229_1368.port_b.T; TC_1229_1368.port_a.Q_flow = TC_1229_1368.Q_flow; TC_1229_1368.port_b.Q_flow = -TC_1229_1368.Q_flow; TC_1229_1535.Q_flow = TC_1229_1535.G * TC_1229_1535.dT; TC_1229_1535.dT = TC_1229_1535.port_a.T - TC_1229_1535.port_b.T; TC_1229_1535.port_a.Q_flow = TC_1229_1535.Q_flow; TC_1229_1535.port_b.Q_flow = -TC_1229_1535.Q_flow; TC_1230_1238.Q_flow = TC_1230_1238.G * TC_1230_1238.dT; TC_1230_1238.dT = TC_1230_1238.port_a.T - TC_1230_1238.port_b.T; TC_1230_1238.port_a.Q_flow = TC_1230_1238.Q_flow; TC_1230_1238.port_b.Q_flow = -TC_1230_1238.Q_flow; TC_1230_1369.Q_flow = TC_1230_1369.G * TC_1230_1369.dT; TC_1230_1369.dT = TC_1230_1369.port_a.T - TC_1230_1369.port_b.T; TC_1230_1369.port_a.Q_flow = TC_1230_1369.Q_flow; TC_1230_1369.port_b.Q_flow = -TC_1230_1369.Q_flow; TC_1231_1232.Q_flow = TC_1231_1232.G * TC_1231_1232.dT; TC_1231_1232.dT = TC_1231_1232.port_a.T - TC_1231_1232.port_b.T; TC_1231_1232.port_a.Q_flow = TC_1231_1232.Q_flow; TC_1231_1232.port_b.Q_flow = -TC_1231_1232.Q_flow; TC_1231_1239.Q_flow = TC_1231_1239.G * TC_1231_1239.dT; TC_1231_1239.dT = TC_1231_1239.port_a.T - TC_1231_1239.port_b.T; TC_1231_1239.port_a.Q_flow = TC_1231_1239.Q_flow; TC_1231_1239.port_b.Q_flow = -TC_1231_1239.Q_flow; TC_1231_1370.Q_flow = TC_1231_1370.G * TC_1231_1370.dT; TC_1231_1370.dT = TC_1231_1370.port_a.T - TC_1231_1370.port_b.T; TC_1231_1370.port_a.Q_flow = TC_1231_1370.Q_flow; TC_1231_1370.port_b.Q_flow = -TC_1231_1370.Q_flow; TC_1232_1240.Q_flow = TC_1232_1240.G * TC_1232_1240.dT; TC_1232_1240.dT = TC_1232_1240.port_a.T - TC_1232_1240.port_b.T; TC_1232_1240.port_a.Q_flow = TC_1232_1240.Q_flow; TC_1232_1240.port_b.Q_flow = -TC_1232_1240.Q_flow; TC_1232_1371.Q_flow = TC_1232_1371.G * TC_1232_1371.dT; TC_1232_1371.dT = TC_1232_1371.port_a.T - TC_1232_1371.port_b.T; TC_1232_1371.port_a.Q_flow = TC_1232_1371.Q_flow; TC_1232_1371.port_b.Q_flow = -TC_1232_1371.Q_flow; TC_1232_1521.Q_flow = TC_1232_1521.G * TC_1232_1521.dT; TC_1232_1521.dT = TC_1232_1521.port_a.T - TC_1232_1521.port_b.T; TC_1232_1521.port_a.Q_flow = TC_1232_1521.Q_flow; TC_1232_1521.port_b.Q_flow = -TC_1232_1521.Q_flow; TC_1232_1536.Q_flow = TC_1232_1536.G * TC_1232_1536.dT; TC_1232_1536.dT = TC_1232_1536.port_a.T - TC_1232_1536.port_b.T; TC_1232_1536.port_a.Q_flow = TC_1232_1536.Q_flow; TC_1232_1536.port_b.Q_flow = -TC_1232_1536.Q_flow; TC_1233_1234.Q_flow = TC_1233_1234.G * TC_1233_1234.dT; TC_1233_1234.dT = TC_1233_1234.port_a.T - TC_1233_1234.port_b.T; TC_1233_1234.port_a.Q_flow = TC_1233_1234.Q_flow; TC_1233_1234.port_b.Q_flow = -TC_1233_1234.Q_flow; TC_1233_1241.Q_flow = TC_1233_1241.G * TC_1233_1241.dT; TC_1233_1241.dT = TC_1233_1241.port_a.T - TC_1233_1241.port_b.T; TC_1233_1241.port_a.Q_flow = TC_1233_1241.Q_flow; TC_1233_1241.port_b.Q_flow = -TC_1233_1241.Q_flow; TC_1233_1375.Q_flow = TC_1233_1375.G * TC_1233_1375.dT; TC_1233_1375.dT = TC_1233_1375.port_a.T - TC_1233_1375.port_b.T; TC_1233_1375.port_a.Q_flow = TC_1233_1375.Q_flow; TC_1233_1375.port_b.Q_flow = -TC_1233_1375.Q_flow; TC_1233_1523.Q_flow = TC_1233_1523.G * TC_1233_1523.dT; TC_1233_1523.dT = TC_1233_1523.port_a.T - TC_1233_1523.port_b.T; TC_1233_1523.port_a.Q_flow = TC_1233_1523.Q_flow; TC_1233_1523.port_b.Q_flow = -TC_1233_1523.Q_flow; TC_1233_1540.Q_flow = TC_1233_1540.G * TC_1233_1540.dT; TC_1233_1540.dT = TC_1233_1540.port_a.T - TC_1233_1540.port_b.T; TC_1233_1540.port_a.Q_flow = TC_1233_1540.Q_flow; TC_1233_1540.port_b.Q_flow = -TC_1233_1540.Q_flow; TC_1234_1235.Q_flow = TC_1234_1235.G * TC_1234_1235.dT; TC_1234_1235.dT = TC_1234_1235.port_a.T - TC_1234_1235.port_b.T; TC_1234_1235.port_a.Q_flow = TC_1234_1235.Q_flow; TC_1234_1235.port_b.Q_flow = -TC_1234_1235.Q_flow; TC_1234_1242.Q_flow = TC_1234_1242.G * TC_1234_1242.dT; TC_1234_1242.dT = TC_1234_1242.port_a.T - TC_1234_1242.port_b.T; TC_1234_1242.port_a.Q_flow = TC_1234_1242.Q_flow; TC_1234_1242.port_b.Q_flow = -TC_1234_1242.Q_flow; TC_1234_1376.Q_flow = TC_1234_1376.G * TC_1234_1376.dT; TC_1234_1376.dT = TC_1234_1376.port_a.T - TC_1234_1376.port_b.T; TC_1234_1376.port_a.Q_flow = TC_1234_1376.Q_flow; TC_1234_1376.port_b.Q_flow = -TC_1234_1376.Q_flow; TC_1234_1541.Q_flow = TC_1234_1541.G * TC_1234_1541.dT; TC_1234_1541.dT = TC_1234_1541.port_a.T - TC_1234_1541.port_b.T; TC_1234_1541.port_a.Q_flow = TC_1234_1541.Q_flow; TC_1234_1541.port_b.Q_flow = -TC_1234_1541.Q_flow; TC_1235_1236.Q_flow = TC_1235_1236.G * TC_1235_1236.dT; TC_1235_1236.dT = TC_1235_1236.port_a.T - TC_1235_1236.port_b.T; TC_1235_1236.port_a.Q_flow = TC_1235_1236.Q_flow; TC_1235_1236.port_b.Q_flow = -TC_1235_1236.Q_flow; TC_1235_1243.Q_flow = TC_1235_1243.G * TC_1235_1243.dT; TC_1235_1243.dT = TC_1235_1243.port_a.T - TC_1235_1243.port_b.T; TC_1235_1243.port_a.Q_flow = TC_1235_1243.Q_flow; TC_1235_1243.port_b.Q_flow = -TC_1235_1243.Q_flow; TC_1235_1377.Q_flow = TC_1235_1377.G * TC_1235_1377.dT; TC_1235_1377.dT = TC_1235_1377.port_a.T - TC_1235_1377.port_b.T; TC_1235_1377.port_a.Q_flow = TC_1235_1377.Q_flow; TC_1235_1377.port_b.Q_flow = -TC_1235_1377.Q_flow; TC_1235_1542.Q_flow = TC_1235_1542.G * TC_1235_1542.dT; TC_1235_1542.dT = TC_1235_1542.port_a.T - TC_1235_1542.port_b.T; TC_1235_1542.port_a.Q_flow = TC_1235_1542.Q_flow; TC_1235_1542.port_b.Q_flow = -TC_1235_1542.Q_flow; TC_1236_1237.Q_flow = TC_1236_1237.G * TC_1236_1237.dT; TC_1236_1237.dT = TC_1236_1237.port_a.T - TC_1236_1237.port_b.T; TC_1236_1237.port_a.Q_flow = TC_1236_1237.Q_flow; TC_1236_1237.port_b.Q_flow = -TC_1236_1237.Q_flow; TC_1236_1244.Q_flow = TC_1236_1244.G * TC_1236_1244.dT; TC_1236_1244.dT = TC_1236_1244.port_a.T - TC_1236_1244.port_b.T; TC_1236_1244.port_a.Q_flow = TC_1236_1244.Q_flow; TC_1236_1244.port_b.Q_flow = -TC_1236_1244.Q_flow; TC_1236_1378.Q_flow = TC_1236_1378.G * TC_1236_1378.dT; TC_1236_1378.dT = TC_1236_1378.port_a.T - TC_1236_1378.port_b.T; TC_1236_1378.port_a.Q_flow = TC_1236_1378.Q_flow; TC_1236_1378.port_b.Q_flow = -TC_1236_1378.Q_flow; TC_1236_1543.Q_flow = TC_1236_1543.G * TC_1236_1543.dT; TC_1236_1543.dT = TC_1236_1543.port_a.T - TC_1236_1543.port_b.T; TC_1236_1543.port_a.Q_flow = TC_1236_1543.Q_flow; TC_1236_1543.port_b.Q_flow = -TC_1236_1543.Q_flow; TC_1237_1238.Q_flow = TC_1237_1238.G * TC_1237_1238.dT; TC_1237_1238.dT = TC_1237_1238.port_a.T - TC_1237_1238.port_b.T; TC_1237_1238.port_a.Q_flow = TC_1237_1238.Q_flow; TC_1237_1238.port_b.Q_flow = -TC_1237_1238.Q_flow; TC_1237_1245.Q_flow = TC_1237_1245.G * TC_1237_1245.dT; TC_1237_1245.dT = TC_1237_1245.port_a.T - TC_1237_1245.port_b.T; TC_1237_1245.port_a.Q_flow = TC_1237_1245.Q_flow; TC_1237_1245.port_b.Q_flow = -TC_1237_1245.Q_flow; TC_1237_1379.Q_flow = TC_1237_1379.G * TC_1237_1379.dT; TC_1237_1379.dT = TC_1237_1379.port_a.T - TC_1237_1379.port_b.T; TC_1237_1379.port_a.Q_flow = TC_1237_1379.Q_flow; TC_1237_1379.port_b.Q_flow = -TC_1237_1379.Q_flow; TC_1237_1544.Q_flow = TC_1237_1544.G * TC_1237_1544.dT; TC_1237_1544.dT = TC_1237_1544.port_a.T - TC_1237_1544.port_b.T; TC_1237_1544.port_a.Q_flow = TC_1237_1544.Q_flow; TC_1237_1544.port_b.Q_flow = -TC_1237_1544.Q_flow; TC_1238_1246.Q_flow = TC_1238_1246.G * TC_1238_1246.dT; TC_1238_1246.dT = TC_1238_1246.port_a.T - TC_1238_1246.port_b.T; TC_1238_1246.port_a.Q_flow = TC_1238_1246.Q_flow; TC_1238_1246.port_b.Q_flow = -TC_1238_1246.Q_flow; TC_1238_1380.Q_flow = TC_1238_1380.G * TC_1238_1380.dT; TC_1238_1380.dT = TC_1238_1380.port_a.T - TC_1238_1380.port_b.T; TC_1238_1380.port_a.Q_flow = TC_1238_1380.Q_flow; TC_1238_1380.port_b.Q_flow = -TC_1238_1380.Q_flow; TC_1239_1240.Q_flow = TC_1239_1240.G * TC_1239_1240.dT; TC_1239_1240.dT = TC_1239_1240.port_a.T - TC_1239_1240.port_b.T; TC_1239_1240.port_a.Q_flow = TC_1239_1240.Q_flow; TC_1239_1240.port_b.Q_flow = -TC_1239_1240.Q_flow; TC_1239_1247.Q_flow = TC_1239_1247.G * TC_1239_1247.dT; TC_1239_1247.dT = TC_1239_1247.port_a.T - TC_1239_1247.port_b.T; TC_1239_1247.port_a.Q_flow = TC_1239_1247.Q_flow; TC_1239_1247.port_b.Q_flow = -TC_1239_1247.Q_flow; TC_1239_1381.Q_flow = TC_1239_1381.G * TC_1239_1381.dT; TC_1239_1381.dT = TC_1239_1381.port_a.T - TC_1239_1381.port_b.T; TC_1239_1381.port_a.Q_flow = TC_1239_1381.Q_flow; TC_1239_1381.port_b.Q_flow = -TC_1239_1381.Q_flow; TC_1240_1248.Q_flow = TC_1240_1248.G * TC_1240_1248.dT; TC_1240_1248.dT = TC_1240_1248.port_a.T - TC_1240_1248.port_b.T; TC_1240_1248.port_a.Q_flow = TC_1240_1248.Q_flow; TC_1240_1248.port_b.Q_flow = -TC_1240_1248.Q_flow; TC_1240_1382.Q_flow = TC_1240_1382.G * TC_1240_1382.dT; TC_1240_1382.dT = TC_1240_1382.port_a.T - TC_1240_1382.port_b.T; TC_1240_1382.port_a.Q_flow = TC_1240_1382.Q_flow; TC_1240_1382.port_b.Q_flow = -TC_1240_1382.Q_flow; TC_1240_1524.Q_flow = TC_1240_1524.G * TC_1240_1524.dT; TC_1240_1524.dT = TC_1240_1524.port_a.T - TC_1240_1524.port_b.T; TC_1240_1524.port_a.Q_flow = TC_1240_1524.Q_flow; TC_1240_1524.port_b.Q_flow = -TC_1240_1524.Q_flow; TC_1240_1545.Q_flow = TC_1240_1545.G * TC_1240_1545.dT; TC_1240_1545.dT = TC_1240_1545.port_a.T - TC_1240_1545.port_b.T; TC_1240_1545.port_a.Q_flow = TC_1240_1545.Q_flow; TC_1240_1545.port_b.Q_flow = -TC_1240_1545.Q_flow; TC_1241_1242.Q_flow = TC_1241_1242.G * TC_1241_1242.dT; TC_1241_1242.dT = TC_1241_1242.port_a.T - TC_1241_1242.port_b.T; TC_1241_1242.port_a.Q_flow = TC_1241_1242.Q_flow; TC_1241_1242.port_b.Q_flow = -TC_1241_1242.Q_flow; TC_1241_1252.Q_flow = TC_1241_1252.G * TC_1241_1252.dT; TC_1241_1252.dT = TC_1241_1252.port_a.T - TC_1241_1252.port_b.T; TC_1241_1252.port_a.Q_flow = TC_1241_1252.Q_flow; TC_1241_1252.port_b.Q_flow = -TC_1241_1252.Q_flow; TC_1241_1386.Q_flow = TC_1241_1386.G * TC_1241_1386.dT; TC_1241_1386.dT = TC_1241_1386.port_a.T - TC_1241_1386.port_b.T; TC_1241_1386.port_a.Q_flow = TC_1241_1386.Q_flow; TC_1241_1386.port_b.Q_flow = -TC_1241_1386.Q_flow; TC_1241_1526.Q_flow = TC_1241_1526.G * TC_1241_1526.dT; TC_1241_1526.dT = TC_1241_1526.port_a.T - TC_1241_1526.port_b.T; TC_1241_1526.port_a.Q_flow = TC_1241_1526.Q_flow; TC_1241_1526.port_b.Q_flow = -TC_1241_1526.Q_flow; TC_1241_1549.Q_flow = TC_1241_1549.G * TC_1241_1549.dT; TC_1241_1549.dT = TC_1241_1549.port_a.T - TC_1241_1549.port_b.T; TC_1241_1549.port_a.Q_flow = TC_1241_1549.Q_flow; TC_1241_1549.port_b.Q_flow = -TC_1241_1549.Q_flow; TC_1242_1243.Q_flow = TC_1242_1243.G * TC_1242_1243.dT; TC_1242_1243.dT = TC_1242_1243.port_a.T - TC_1242_1243.port_b.T; TC_1242_1243.port_a.Q_flow = TC_1242_1243.Q_flow; TC_1242_1243.port_b.Q_flow = -TC_1242_1243.Q_flow; TC_1242_1253.Q_flow = TC_1242_1253.G * TC_1242_1253.dT; TC_1242_1253.dT = TC_1242_1253.port_a.T - TC_1242_1253.port_b.T; TC_1242_1253.port_a.Q_flow = TC_1242_1253.Q_flow; TC_1242_1253.port_b.Q_flow = -TC_1242_1253.Q_flow; TC_1242_1387.Q_flow = TC_1242_1387.G * TC_1242_1387.dT; TC_1242_1387.dT = TC_1242_1387.port_a.T - TC_1242_1387.port_b.T; TC_1242_1387.port_a.Q_flow = TC_1242_1387.Q_flow; TC_1242_1387.port_b.Q_flow = -TC_1242_1387.Q_flow; TC_1242_1550.Q_flow = TC_1242_1550.G * TC_1242_1550.dT; TC_1242_1550.dT = TC_1242_1550.port_a.T - TC_1242_1550.port_b.T; TC_1242_1550.port_a.Q_flow = TC_1242_1550.Q_flow; TC_1242_1550.port_b.Q_flow = -TC_1242_1550.Q_flow; TC_1243_1244.Q_flow = TC_1243_1244.G * TC_1243_1244.dT; TC_1243_1244.dT = TC_1243_1244.port_a.T - TC_1243_1244.port_b.T; TC_1243_1244.port_a.Q_flow = TC_1243_1244.Q_flow; TC_1243_1244.port_b.Q_flow = -TC_1243_1244.Q_flow; TC_1243_1254.Q_flow = TC_1243_1254.G * TC_1243_1254.dT; TC_1243_1254.dT = TC_1243_1254.port_a.T - TC_1243_1254.port_b.T; TC_1243_1254.port_a.Q_flow = TC_1243_1254.Q_flow; TC_1243_1254.port_b.Q_flow = -TC_1243_1254.Q_flow; TC_1243_1388.Q_flow = TC_1243_1388.G * TC_1243_1388.dT; TC_1243_1388.dT = TC_1243_1388.port_a.T - TC_1243_1388.port_b.T; TC_1243_1388.port_a.Q_flow = TC_1243_1388.Q_flow; TC_1243_1388.port_b.Q_flow = -TC_1243_1388.Q_flow; TC_1243_1551.Q_flow = TC_1243_1551.G * TC_1243_1551.dT; TC_1243_1551.dT = TC_1243_1551.port_a.T - TC_1243_1551.port_b.T; TC_1243_1551.port_a.Q_flow = TC_1243_1551.Q_flow; TC_1243_1551.port_b.Q_flow = -TC_1243_1551.Q_flow; TC_1244_1245.Q_flow = TC_1244_1245.G * TC_1244_1245.dT; TC_1244_1245.dT = TC_1244_1245.port_a.T - TC_1244_1245.port_b.T; TC_1244_1245.port_a.Q_flow = TC_1244_1245.Q_flow; TC_1244_1245.port_b.Q_flow = -TC_1244_1245.Q_flow; TC_1244_1255.Q_flow = TC_1244_1255.G * TC_1244_1255.dT; TC_1244_1255.dT = TC_1244_1255.port_a.T - TC_1244_1255.port_b.T; TC_1244_1255.port_a.Q_flow = TC_1244_1255.Q_flow; TC_1244_1255.port_b.Q_flow = -TC_1244_1255.Q_flow; TC_1244_1389.Q_flow = TC_1244_1389.G * TC_1244_1389.dT; TC_1244_1389.dT = TC_1244_1389.port_a.T - TC_1244_1389.port_b.T; TC_1244_1389.port_a.Q_flow = TC_1244_1389.Q_flow; TC_1244_1389.port_b.Q_flow = -TC_1244_1389.Q_flow; TC_1244_1552.Q_flow = TC_1244_1552.G * TC_1244_1552.dT; TC_1244_1552.dT = TC_1244_1552.port_a.T - TC_1244_1552.port_b.T; TC_1244_1552.port_a.Q_flow = TC_1244_1552.Q_flow; TC_1244_1552.port_b.Q_flow = -TC_1244_1552.Q_flow; TC_1245_1246.Q_flow = TC_1245_1246.G * TC_1245_1246.dT; TC_1245_1246.dT = TC_1245_1246.port_a.T - TC_1245_1246.port_b.T; TC_1245_1246.port_a.Q_flow = TC_1245_1246.Q_flow; TC_1245_1246.port_b.Q_flow = -TC_1245_1246.Q_flow; TC_1245_1256.Q_flow = TC_1245_1256.G * TC_1245_1256.dT; TC_1245_1256.dT = TC_1245_1256.port_a.T - TC_1245_1256.port_b.T; TC_1245_1256.port_a.Q_flow = TC_1245_1256.Q_flow; TC_1245_1256.port_b.Q_flow = -TC_1245_1256.Q_flow; TC_1245_1390.Q_flow = TC_1245_1390.G * TC_1245_1390.dT; TC_1245_1390.dT = TC_1245_1390.port_a.T - TC_1245_1390.port_b.T; TC_1245_1390.port_a.Q_flow = TC_1245_1390.Q_flow; TC_1245_1390.port_b.Q_flow = -TC_1245_1390.Q_flow; TC_1245_1553.Q_flow = TC_1245_1553.G * TC_1245_1553.dT; TC_1245_1553.dT = TC_1245_1553.port_a.T - TC_1245_1553.port_b.T; TC_1245_1553.port_a.Q_flow = TC_1245_1553.Q_flow; TC_1245_1553.port_b.Q_flow = -TC_1245_1553.Q_flow; TC_1246_1257.Q_flow = TC_1246_1257.G * TC_1246_1257.dT; TC_1246_1257.dT = TC_1246_1257.port_a.T - TC_1246_1257.port_b.T; TC_1246_1257.port_a.Q_flow = TC_1246_1257.Q_flow; TC_1246_1257.port_b.Q_flow = -TC_1246_1257.Q_flow; TC_1246_1391.Q_flow = TC_1246_1391.G * TC_1246_1391.dT; TC_1246_1391.dT = TC_1246_1391.port_a.T - TC_1246_1391.port_b.T; TC_1246_1391.port_a.Q_flow = TC_1246_1391.Q_flow; TC_1246_1391.port_b.Q_flow = -TC_1246_1391.Q_flow; TC_1247_1248.Q_flow = TC_1247_1248.G * TC_1247_1248.dT; TC_1247_1248.dT = TC_1247_1248.port_a.T - TC_1247_1248.port_b.T; TC_1247_1248.port_a.Q_flow = TC_1247_1248.Q_flow; TC_1247_1248.port_b.Q_flow = -TC_1247_1248.Q_flow; TC_1247_1258.Q_flow = TC_1247_1258.G * TC_1247_1258.dT; TC_1247_1258.dT = TC_1247_1258.port_a.T - TC_1247_1258.port_b.T; TC_1247_1258.port_a.Q_flow = TC_1247_1258.Q_flow; TC_1247_1258.port_b.Q_flow = -TC_1247_1258.Q_flow; TC_1247_1392.Q_flow = TC_1247_1392.G * TC_1247_1392.dT; TC_1247_1392.dT = TC_1247_1392.port_a.T - TC_1247_1392.port_b.T; TC_1247_1392.port_a.Q_flow = TC_1247_1392.Q_flow; TC_1247_1392.port_b.Q_flow = -TC_1247_1392.Q_flow; TC_1248_1249.Q_flow = TC_1248_1249.G * TC_1248_1249.dT; TC_1248_1249.dT = TC_1248_1249.port_a.T - TC_1248_1249.port_b.T; TC_1248_1249.port_a.Q_flow = TC_1248_1249.Q_flow; TC_1248_1249.port_b.Q_flow = -TC_1248_1249.Q_flow; TC_1248_1259.Q_flow = TC_1248_1259.G * TC_1248_1259.dT; TC_1248_1259.dT = TC_1248_1259.port_a.T - TC_1248_1259.port_b.T; TC_1248_1259.port_a.Q_flow = TC_1248_1259.Q_flow; TC_1248_1259.port_b.Q_flow = -TC_1248_1259.Q_flow; TC_1248_1393.Q_flow = TC_1248_1393.G * TC_1248_1393.dT; TC_1248_1393.dT = TC_1248_1393.port_a.T - TC_1248_1393.port_b.T; TC_1248_1393.port_a.Q_flow = TC_1248_1393.Q_flow; TC_1248_1393.port_b.Q_flow = -TC_1248_1393.Q_flow; TC_1248_1554.Q_flow = TC_1248_1554.G * TC_1248_1554.dT; TC_1248_1554.dT = TC_1248_1554.port_a.T - TC_1248_1554.port_b.T; TC_1248_1554.port_a.Q_flow = TC_1248_1554.Q_flow; TC_1248_1554.port_b.Q_flow = -TC_1248_1554.Q_flow; TC_1249_1250.Q_flow = TC_1249_1250.G * TC_1249_1250.dT; TC_1249_1250.dT = TC_1249_1250.port_a.T - TC_1249_1250.port_b.T; TC_1249_1250.port_a.Q_flow = TC_1249_1250.Q_flow; TC_1249_1250.port_b.Q_flow = -TC_1249_1250.Q_flow; TC_1249_1260.Q_flow = TC_1249_1260.G * TC_1249_1260.dT; TC_1249_1260.dT = TC_1249_1260.port_a.T - TC_1249_1260.port_b.T; TC_1249_1260.port_a.Q_flow = TC_1249_1260.Q_flow; TC_1249_1260.port_b.Q_flow = -TC_1249_1260.Q_flow; TC_1249_1394.Q_flow = TC_1249_1394.G * TC_1249_1394.dT; TC_1249_1394.dT = TC_1249_1394.port_a.T - TC_1249_1394.port_b.T; TC_1249_1394.port_a.Q_flow = TC_1249_1394.Q_flow; TC_1249_1394.port_b.Q_flow = -TC_1249_1394.Q_flow; TC_1249_1524.Q_flow = TC_1249_1524.G * TC_1249_1524.dT; TC_1249_1524.dT = TC_1249_1524.port_a.T - TC_1249_1524.port_b.T; TC_1249_1524.port_a.Q_flow = TC_1249_1524.Q_flow; TC_1249_1524.port_b.Q_flow = -TC_1249_1524.Q_flow; TC_1249_1555.Q_flow = TC_1249_1555.G * TC_1249_1555.dT; TC_1249_1555.dT = TC_1249_1555.port_a.T - TC_1249_1555.port_b.T; TC_1249_1555.port_a.Q_flow = TC_1249_1555.Q_flow; TC_1249_1555.port_b.Q_flow = -TC_1249_1555.Q_flow; TC_1250_1251.Q_flow = TC_1250_1251.G * TC_1250_1251.dT; TC_1250_1251.dT = TC_1250_1251.port_a.T - TC_1250_1251.port_b.T; TC_1250_1251.port_a.Q_flow = TC_1250_1251.Q_flow; TC_1250_1251.port_b.Q_flow = -TC_1250_1251.Q_flow; TC_1250_1261.Q_flow = TC_1250_1261.G * TC_1250_1261.dT; TC_1250_1261.dT = TC_1250_1261.port_a.T - TC_1250_1261.port_b.T; TC_1250_1261.port_a.Q_flow = TC_1250_1261.Q_flow; TC_1250_1261.port_b.Q_flow = -TC_1250_1261.Q_flow; TC_1250_1395.Q_flow = TC_1250_1395.G * TC_1250_1395.dT; TC_1250_1395.dT = TC_1250_1395.port_a.T - TC_1250_1395.port_b.T; TC_1250_1395.port_a.Q_flow = TC_1250_1395.Q_flow; TC_1250_1395.port_b.Q_flow = -TC_1250_1395.Q_flow; TC_1250_1525.Q_flow = TC_1250_1525.G * TC_1250_1525.dT; TC_1250_1525.dT = TC_1250_1525.port_a.T - TC_1250_1525.port_b.T; TC_1250_1525.port_a.Q_flow = TC_1250_1525.Q_flow; TC_1250_1525.port_b.Q_flow = -TC_1250_1525.Q_flow; TC_1250_1556.Q_flow = TC_1250_1556.G * TC_1250_1556.dT; TC_1250_1556.dT = TC_1250_1556.port_a.T - TC_1250_1556.port_b.T; TC_1250_1556.port_a.Q_flow = TC_1250_1556.Q_flow; TC_1250_1556.port_b.Q_flow = -TC_1250_1556.Q_flow; TC_1251_1252.Q_flow = TC_1251_1252.G * TC_1251_1252.dT; TC_1251_1252.dT = TC_1251_1252.port_a.T - TC_1251_1252.port_b.T; TC_1251_1252.port_a.Q_flow = TC_1251_1252.Q_flow; TC_1251_1252.port_b.Q_flow = -TC_1251_1252.Q_flow; TC_1251_1262.Q_flow = TC_1251_1262.G * TC_1251_1262.dT; TC_1251_1262.dT = TC_1251_1262.port_a.T - TC_1251_1262.port_b.T; TC_1251_1262.port_a.Q_flow = TC_1251_1262.Q_flow; TC_1251_1262.port_b.Q_flow = -TC_1251_1262.Q_flow; TC_1251_1396.Q_flow = TC_1251_1396.G * TC_1251_1396.dT; TC_1251_1396.dT = TC_1251_1396.port_a.T - TC_1251_1396.port_b.T; TC_1251_1396.port_a.Q_flow = TC_1251_1396.Q_flow; TC_1251_1396.port_b.Q_flow = -TC_1251_1396.Q_flow; TC_1251_1526.Q_flow = TC_1251_1526.G * TC_1251_1526.dT; TC_1251_1526.dT = TC_1251_1526.port_a.T - TC_1251_1526.port_b.T; TC_1251_1526.port_a.Q_flow = TC_1251_1526.Q_flow; TC_1251_1526.port_b.Q_flow = -TC_1251_1526.Q_flow; TC_1251_1557.Q_flow = TC_1251_1557.G * TC_1251_1557.dT; TC_1251_1557.dT = TC_1251_1557.port_a.T - TC_1251_1557.port_b.T; TC_1251_1557.port_a.Q_flow = TC_1251_1557.Q_flow; TC_1251_1557.port_b.Q_flow = -TC_1251_1557.Q_flow; TC_1252_1253.Q_flow = TC_1252_1253.G * TC_1252_1253.dT; TC_1252_1253.dT = TC_1252_1253.port_a.T - TC_1252_1253.port_b.T; TC_1252_1253.port_a.Q_flow = TC_1252_1253.Q_flow; TC_1252_1253.port_b.Q_flow = -TC_1252_1253.Q_flow; TC_1252_1263.Q_flow = TC_1252_1263.G * TC_1252_1263.dT; TC_1252_1263.dT = TC_1252_1263.port_a.T - TC_1252_1263.port_b.T; TC_1252_1263.port_a.Q_flow = TC_1252_1263.Q_flow; TC_1252_1263.port_b.Q_flow = -TC_1252_1263.Q_flow; TC_1252_1397.Q_flow = TC_1252_1397.G * TC_1252_1397.dT; TC_1252_1397.dT = TC_1252_1397.port_a.T - TC_1252_1397.port_b.T; TC_1252_1397.port_a.Q_flow = TC_1252_1397.Q_flow; TC_1252_1397.port_b.Q_flow = -TC_1252_1397.Q_flow; TC_1252_1558.Q_flow = TC_1252_1558.G * TC_1252_1558.dT; TC_1252_1558.dT = TC_1252_1558.port_a.T - TC_1252_1558.port_b.T; TC_1252_1558.port_a.Q_flow = TC_1252_1558.Q_flow; TC_1252_1558.port_b.Q_flow = -TC_1252_1558.Q_flow; TC_1253_1254.Q_flow = TC_1253_1254.G * TC_1253_1254.dT; TC_1253_1254.dT = TC_1253_1254.port_a.T - TC_1253_1254.port_b.T; TC_1253_1254.port_a.Q_flow = TC_1253_1254.Q_flow; TC_1253_1254.port_b.Q_flow = -TC_1253_1254.Q_flow; TC_1253_1264.Q_flow = TC_1253_1264.G * TC_1253_1264.dT; TC_1253_1264.dT = TC_1253_1264.port_a.T - TC_1253_1264.port_b.T; TC_1253_1264.port_a.Q_flow = TC_1253_1264.Q_flow; TC_1253_1264.port_b.Q_flow = -TC_1253_1264.Q_flow; TC_1253_1398.Q_flow = TC_1253_1398.G * TC_1253_1398.dT; TC_1253_1398.dT = TC_1253_1398.port_a.T - TC_1253_1398.port_b.T; TC_1253_1398.port_a.Q_flow = TC_1253_1398.Q_flow; TC_1253_1398.port_b.Q_flow = -TC_1253_1398.Q_flow; TC_1253_1559.Q_flow = TC_1253_1559.G * TC_1253_1559.dT; TC_1253_1559.dT = TC_1253_1559.port_a.T - TC_1253_1559.port_b.T; TC_1253_1559.port_a.Q_flow = TC_1253_1559.Q_flow; TC_1253_1559.port_b.Q_flow = -TC_1253_1559.Q_flow; TC_1254_1255.Q_flow = TC_1254_1255.G * TC_1254_1255.dT; TC_1254_1255.dT = TC_1254_1255.port_a.T - TC_1254_1255.port_b.T; TC_1254_1255.port_a.Q_flow = TC_1254_1255.Q_flow; TC_1254_1255.port_b.Q_flow = -TC_1254_1255.Q_flow; TC_1254_1265.Q_flow = TC_1254_1265.G * TC_1254_1265.dT; TC_1254_1265.dT = TC_1254_1265.port_a.T - TC_1254_1265.port_b.T; TC_1254_1265.port_a.Q_flow = TC_1254_1265.Q_flow; TC_1254_1265.port_b.Q_flow = -TC_1254_1265.Q_flow; TC_1254_1399.Q_flow = TC_1254_1399.G * TC_1254_1399.dT; TC_1254_1399.dT = TC_1254_1399.port_a.T - TC_1254_1399.port_b.T; TC_1254_1399.port_a.Q_flow = TC_1254_1399.Q_flow; TC_1254_1399.port_b.Q_flow = -TC_1254_1399.Q_flow; TC_1254_1560.Q_flow = TC_1254_1560.G * TC_1254_1560.dT; TC_1254_1560.dT = TC_1254_1560.port_a.T - TC_1254_1560.port_b.T; TC_1254_1560.port_a.Q_flow = TC_1254_1560.Q_flow; TC_1254_1560.port_b.Q_flow = -TC_1254_1560.Q_flow; TC_1255_1256.Q_flow = TC_1255_1256.G * TC_1255_1256.dT; TC_1255_1256.dT = TC_1255_1256.port_a.T - TC_1255_1256.port_b.T; TC_1255_1256.port_a.Q_flow = TC_1255_1256.Q_flow; TC_1255_1256.port_b.Q_flow = -TC_1255_1256.Q_flow; TC_1255_1266.Q_flow = TC_1255_1266.G * TC_1255_1266.dT; TC_1255_1266.dT = TC_1255_1266.port_a.T - TC_1255_1266.port_b.T; TC_1255_1266.port_a.Q_flow = TC_1255_1266.Q_flow; TC_1255_1266.port_b.Q_flow = -TC_1255_1266.Q_flow; TC_1255_1400.Q_flow = TC_1255_1400.G * TC_1255_1400.dT; TC_1255_1400.dT = TC_1255_1400.port_a.T - TC_1255_1400.port_b.T; TC_1255_1400.port_a.Q_flow = TC_1255_1400.Q_flow; TC_1255_1400.port_b.Q_flow = -TC_1255_1400.Q_flow; TC_1255_1561.Q_flow = TC_1255_1561.G * TC_1255_1561.dT; TC_1255_1561.dT = TC_1255_1561.port_a.T - TC_1255_1561.port_b.T; TC_1255_1561.port_a.Q_flow = TC_1255_1561.Q_flow; TC_1255_1561.port_b.Q_flow = -TC_1255_1561.Q_flow; TC_1256_1257.Q_flow = TC_1256_1257.G * TC_1256_1257.dT; TC_1256_1257.dT = TC_1256_1257.port_a.T - TC_1256_1257.port_b.T; TC_1256_1257.port_a.Q_flow = TC_1256_1257.Q_flow; TC_1256_1257.port_b.Q_flow = -TC_1256_1257.Q_flow; TC_1256_1267.Q_flow = TC_1256_1267.G * TC_1256_1267.dT; TC_1256_1267.dT = TC_1256_1267.port_a.T - TC_1256_1267.port_b.T; TC_1256_1267.port_a.Q_flow = TC_1256_1267.Q_flow; TC_1256_1267.port_b.Q_flow = -TC_1256_1267.Q_flow; TC_1256_1401.Q_flow = TC_1256_1401.G * TC_1256_1401.dT; TC_1256_1401.dT = TC_1256_1401.port_a.T - TC_1256_1401.port_b.T; TC_1256_1401.port_a.Q_flow = TC_1256_1401.Q_flow; TC_1256_1401.port_b.Q_flow = -TC_1256_1401.Q_flow; TC_1256_1562.Q_flow = TC_1256_1562.G * TC_1256_1562.dT; TC_1256_1562.dT = TC_1256_1562.port_a.T - TC_1256_1562.port_b.T; TC_1256_1562.port_a.Q_flow = TC_1256_1562.Q_flow; TC_1256_1562.port_b.Q_flow = -TC_1256_1562.Q_flow; TC_1257_1268.Q_flow = TC_1257_1268.G * TC_1257_1268.dT; TC_1257_1268.dT = TC_1257_1268.port_a.T - TC_1257_1268.port_b.T; TC_1257_1268.port_a.Q_flow = TC_1257_1268.Q_flow; TC_1257_1268.port_b.Q_flow = -TC_1257_1268.Q_flow; TC_1257_1402.Q_flow = TC_1257_1402.G * TC_1257_1402.dT; TC_1257_1402.dT = TC_1257_1402.port_a.T - TC_1257_1402.port_b.T; TC_1257_1402.port_a.Q_flow = TC_1257_1402.Q_flow; TC_1257_1402.port_b.Q_flow = -TC_1257_1402.Q_flow; TC_1258_1259.Q_flow = TC_1258_1259.G * TC_1258_1259.dT; TC_1258_1259.dT = TC_1258_1259.port_a.T - TC_1258_1259.port_b.T; TC_1258_1259.port_a.Q_flow = TC_1258_1259.Q_flow; TC_1258_1259.port_b.Q_flow = -TC_1258_1259.Q_flow; TC_1258_1403.Q_flow = TC_1258_1403.G * TC_1258_1403.dT; TC_1258_1403.dT = TC_1258_1403.port_a.T - TC_1258_1403.port_b.T; TC_1258_1403.port_a.Q_flow = TC_1258_1403.Q_flow; TC_1258_1403.port_b.Q_flow = -TC_1258_1403.Q_flow; TC_1259_1260.Q_flow = TC_1259_1260.G * TC_1259_1260.dT; TC_1259_1260.dT = TC_1259_1260.port_a.T - TC_1259_1260.port_b.T; TC_1259_1260.port_a.Q_flow = TC_1259_1260.Q_flow; TC_1259_1260.port_b.Q_flow = -TC_1259_1260.Q_flow; TC_1259_1404.Q_flow = TC_1259_1404.G * TC_1259_1404.dT; TC_1259_1404.dT = TC_1259_1404.port_a.T - TC_1259_1404.port_b.T; TC_1259_1404.port_a.Q_flow = TC_1259_1404.Q_flow; TC_1259_1404.port_b.Q_flow = -TC_1259_1404.Q_flow; TC_1260_1261.Q_flow = TC_1260_1261.G * TC_1260_1261.dT; TC_1260_1261.dT = TC_1260_1261.port_a.T - TC_1260_1261.port_b.T; TC_1260_1261.port_a.Q_flow = TC_1260_1261.Q_flow; TC_1260_1261.port_b.Q_flow = -TC_1260_1261.Q_flow; TC_1260_1405.Q_flow = TC_1260_1405.G * TC_1260_1405.dT; TC_1260_1405.dT = TC_1260_1405.port_a.T - TC_1260_1405.port_b.T; TC_1260_1405.port_a.Q_flow = TC_1260_1405.Q_flow; TC_1260_1405.port_b.Q_flow = -TC_1260_1405.Q_flow; TC_1261_1262.Q_flow = TC_1261_1262.G * TC_1261_1262.dT; TC_1261_1262.dT = TC_1261_1262.port_a.T - TC_1261_1262.port_b.T; TC_1261_1262.port_a.Q_flow = TC_1261_1262.Q_flow; TC_1261_1262.port_b.Q_flow = -TC_1261_1262.Q_flow; TC_1261_1406.Q_flow = TC_1261_1406.G * TC_1261_1406.dT; TC_1261_1406.dT = TC_1261_1406.port_a.T - TC_1261_1406.port_b.T; TC_1261_1406.port_a.Q_flow = TC_1261_1406.Q_flow; TC_1261_1406.port_b.Q_flow = -TC_1261_1406.Q_flow; TC_1262_1263.Q_flow = TC_1262_1263.G * TC_1262_1263.dT; TC_1262_1263.dT = TC_1262_1263.port_a.T - TC_1262_1263.port_b.T; TC_1262_1263.port_a.Q_flow = TC_1262_1263.Q_flow; TC_1262_1263.port_b.Q_flow = -TC_1262_1263.Q_flow; TC_1262_1407.Q_flow = TC_1262_1407.G * TC_1262_1407.dT; TC_1262_1407.dT = TC_1262_1407.port_a.T - TC_1262_1407.port_b.T; TC_1262_1407.port_a.Q_flow = TC_1262_1407.Q_flow; TC_1262_1407.port_b.Q_flow = -TC_1262_1407.Q_flow; TC_1263_1264.Q_flow = TC_1263_1264.G * TC_1263_1264.dT; TC_1263_1264.dT = TC_1263_1264.port_a.T - TC_1263_1264.port_b.T; TC_1263_1264.port_a.Q_flow = TC_1263_1264.Q_flow; TC_1263_1264.port_b.Q_flow = -TC_1263_1264.Q_flow; TC_1263_1408.Q_flow = TC_1263_1408.G * TC_1263_1408.dT; TC_1263_1408.dT = TC_1263_1408.port_a.T - TC_1263_1408.port_b.T; TC_1263_1408.port_a.Q_flow = TC_1263_1408.Q_flow; TC_1263_1408.port_b.Q_flow = -TC_1263_1408.Q_flow; TC_1264_1265.Q_flow = TC_1264_1265.G * TC_1264_1265.dT; TC_1264_1265.dT = TC_1264_1265.port_a.T - TC_1264_1265.port_b.T; TC_1264_1265.port_a.Q_flow = TC_1264_1265.Q_flow; TC_1264_1265.port_b.Q_flow = -TC_1264_1265.Q_flow; TC_1264_1409.Q_flow = TC_1264_1409.G * TC_1264_1409.dT; TC_1264_1409.dT = TC_1264_1409.port_a.T - TC_1264_1409.port_b.T; TC_1264_1409.port_a.Q_flow = TC_1264_1409.Q_flow; TC_1264_1409.port_b.Q_flow = -TC_1264_1409.Q_flow; TC_1265_1266.Q_flow = TC_1265_1266.G * TC_1265_1266.dT; TC_1265_1266.dT = TC_1265_1266.port_a.T - TC_1265_1266.port_b.T; TC_1265_1266.port_a.Q_flow = TC_1265_1266.Q_flow; TC_1265_1266.port_b.Q_flow = -TC_1265_1266.Q_flow; TC_1265_1410.Q_flow = TC_1265_1410.G * TC_1265_1410.dT; TC_1265_1410.dT = TC_1265_1410.port_a.T - TC_1265_1410.port_b.T; TC_1265_1410.port_a.Q_flow = TC_1265_1410.Q_flow; TC_1265_1410.port_b.Q_flow = -TC_1265_1410.Q_flow; TC_1266_1267.Q_flow = TC_1266_1267.G * TC_1266_1267.dT; TC_1266_1267.dT = TC_1266_1267.port_a.T - TC_1266_1267.port_b.T; TC_1266_1267.port_a.Q_flow = TC_1266_1267.Q_flow; TC_1266_1267.port_b.Q_flow = -TC_1266_1267.Q_flow; TC_1266_1411.Q_flow = TC_1266_1411.G * TC_1266_1411.dT; TC_1266_1411.dT = TC_1266_1411.port_a.T - TC_1266_1411.port_b.T; TC_1266_1411.port_a.Q_flow = TC_1266_1411.Q_flow; TC_1266_1411.port_b.Q_flow = -TC_1266_1411.Q_flow; TC_1267_1268.Q_flow = TC_1267_1268.G * TC_1267_1268.dT; TC_1267_1268.dT = TC_1267_1268.port_a.T - TC_1267_1268.port_b.T; TC_1267_1268.port_a.Q_flow = TC_1267_1268.Q_flow; TC_1267_1268.port_b.Q_flow = -TC_1267_1268.Q_flow; TC_1267_1412.Q_flow = TC_1267_1412.G * TC_1267_1412.dT; TC_1267_1412.dT = TC_1267_1412.port_a.T - TC_1267_1412.port_b.T; TC_1267_1412.port_a.Q_flow = TC_1267_1412.Q_flow; TC_1267_1412.port_b.Q_flow = -TC_1267_1412.Q_flow; TC_1268_1413.Q_flow = TC_1268_1413.G * TC_1268_1413.dT; TC_1268_1413.dT = TC_1268_1413.port_a.T - TC_1268_1413.port_b.T; TC_1268_1413.port_a.Q_flow = TC_1268_1413.Q_flow; TC_1268_1413.port_b.Q_flow = -TC_1268_1413.Q_flow; TC_1269_1270.Q_flow = TC_1269_1270.G * TC_1269_1270.dT; TC_1269_1270.dT = TC_1269_1270.port_a.T - TC_1269_1270.port_b.T; TC_1269_1270.port_a.Q_flow = TC_1269_1270.Q_flow; TC_1269_1270.port_b.Q_flow = -TC_1269_1270.Q_flow; TC_1269_1280.Q_flow = TC_1269_1280.G * TC_1269_1280.dT; TC_1269_1280.dT = TC_1269_1280.port_a.T - TC_1269_1280.port_b.T; TC_1269_1280.port_a.Q_flow = TC_1269_1280.Q_flow; TC_1269_1280.port_b.Q_flow = -TC_1269_1280.Q_flow; TC_1269_1477.Q_flow = TC_1269_1477.G * TC_1269_1477.dT; TC_1269_1477.dT = TC_1269_1477.port_a.T - TC_1269_1477.port_b.T; TC_1269_1477.port_a.Q_flow = TC_1269_1477.Q_flow; TC_1269_1477.port_b.Q_flow = -TC_1269_1477.Q_flow; TC_1270_1271.Q_flow = TC_1270_1271.G * TC_1270_1271.dT; TC_1270_1271.dT = TC_1270_1271.port_a.T - TC_1270_1271.port_b.T; TC_1270_1271.port_a.Q_flow = TC_1270_1271.Q_flow; TC_1270_1271.port_b.Q_flow = -TC_1270_1271.Q_flow; TC_1270_1281.Q_flow = TC_1270_1281.G * TC_1270_1281.dT; TC_1270_1281.dT = TC_1270_1281.port_a.T - TC_1270_1281.port_b.T; TC_1270_1281.port_a.Q_flow = TC_1270_1281.Q_flow; TC_1270_1281.port_b.Q_flow = -TC_1270_1281.Q_flow; TC_1270_1478.Q_flow = TC_1270_1478.G * TC_1270_1478.dT; TC_1270_1478.dT = TC_1270_1478.port_a.T - TC_1270_1478.port_b.T; TC_1270_1478.port_a.Q_flow = TC_1270_1478.Q_flow; TC_1270_1478.port_b.Q_flow = -TC_1270_1478.Q_flow; TC_1271_1272.Q_flow = TC_1271_1272.G * TC_1271_1272.dT; TC_1271_1272.dT = TC_1271_1272.port_a.T - TC_1271_1272.port_b.T; TC_1271_1272.port_a.Q_flow = TC_1271_1272.Q_flow; TC_1271_1272.port_b.Q_flow = -TC_1271_1272.Q_flow; TC_1271_1282.Q_flow = TC_1271_1282.G * TC_1271_1282.dT; TC_1271_1282.dT = TC_1271_1282.port_a.T - TC_1271_1282.port_b.T; TC_1271_1282.port_a.Q_flow = TC_1271_1282.Q_flow; TC_1271_1282.port_b.Q_flow = -TC_1271_1282.Q_flow; TC_1271_1479.Q_flow = TC_1271_1479.G * TC_1271_1479.dT; TC_1271_1479.dT = TC_1271_1479.port_a.T - TC_1271_1479.port_b.T; TC_1271_1479.port_a.Q_flow = TC_1271_1479.Q_flow; TC_1271_1479.port_b.Q_flow = -TC_1271_1479.Q_flow; TC_1272_1273.Q_flow = TC_1272_1273.G * TC_1272_1273.dT; TC_1272_1273.dT = TC_1272_1273.port_a.T - TC_1272_1273.port_b.T; TC_1272_1273.port_a.Q_flow = TC_1272_1273.Q_flow; TC_1272_1273.port_b.Q_flow = -TC_1272_1273.Q_flow; TC_1272_1283.Q_flow = TC_1272_1283.G * TC_1272_1283.dT; TC_1272_1283.dT = TC_1272_1283.port_a.T - TC_1272_1283.port_b.T; TC_1272_1283.port_a.Q_flow = TC_1272_1283.Q_flow; TC_1272_1283.port_b.Q_flow = -TC_1272_1283.Q_flow; TC_1272_1480.Q_flow = TC_1272_1480.G * TC_1272_1480.dT; TC_1272_1480.dT = TC_1272_1480.port_a.T - TC_1272_1480.port_b.T; TC_1272_1480.port_a.Q_flow = TC_1272_1480.Q_flow; TC_1272_1480.port_b.Q_flow = -TC_1272_1480.Q_flow; TC_1273_1274.Q_flow = TC_1273_1274.G * TC_1273_1274.dT; TC_1273_1274.dT = TC_1273_1274.port_a.T - TC_1273_1274.port_b.T; TC_1273_1274.port_a.Q_flow = TC_1273_1274.Q_flow; TC_1273_1274.port_b.Q_flow = -TC_1273_1274.Q_flow; TC_1273_1284.Q_flow = TC_1273_1284.G * TC_1273_1284.dT; TC_1273_1284.dT = TC_1273_1284.port_a.T - TC_1273_1284.port_b.T; TC_1273_1284.port_a.Q_flow = TC_1273_1284.Q_flow; TC_1273_1284.port_b.Q_flow = -TC_1273_1284.Q_flow; TC_1273_1481.Q_flow = TC_1273_1481.G * TC_1273_1481.dT; TC_1273_1481.dT = TC_1273_1481.port_a.T - TC_1273_1481.port_b.T; TC_1273_1481.port_a.Q_flow = TC_1273_1481.Q_flow; TC_1273_1481.port_b.Q_flow = -TC_1273_1481.Q_flow; TC_1274_1275.Q_flow = TC_1274_1275.G * TC_1274_1275.dT; TC_1274_1275.dT = TC_1274_1275.port_a.T - TC_1274_1275.port_b.T; TC_1274_1275.port_a.Q_flow = TC_1274_1275.Q_flow; TC_1274_1275.port_b.Q_flow = -TC_1274_1275.Q_flow; TC_1274_1285.Q_flow = TC_1274_1285.G * TC_1274_1285.dT; TC_1274_1285.dT = TC_1274_1285.port_a.T - TC_1274_1285.port_b.T; TC_1274_1285.port_a.Q_flow = TC_1274_1285.Q_flow; TC_1274_1285.port_b.Q_flow = -TC_1274_1285.Q_flow; TC_1274_1482.Q_flow = TC_1274_1482.G * TC_1274_1482.dT; TC_1274_1482.dT = TC_1274_1482.port_a.T - TC_1274_1482.port_b.T; TC_1274_1482.port_a.Q_flow = TC_1274_1482.Q_flow; TC_1274_1482.port_b.Q_flow = -TC_1274_1482.Q_flow; TC_1275_1276.Q_flow = TC_1275_1276.G * TC_1275_1276.dT; TC_1275_1276.dT = TC_1275_1276.port_a.T - TC_1275_1276.port_b.T; TC_1275_1276.port_a.Q_flow = TC_1275_1276.Q_flow; TC_1275_1276.port_b.Q_flow = -TC_1275_1276.Q_flow; TC_1275_1286.Q_flow = TC_1275_1286.G * TC_1275_1286.dT; TC_1275_1286.dT = TC_1275_1286.port_a.T - TC_1275_1286.port_b.T; TC_1275_1286.port_a.Q_flow = TC_1275_1286.Q_flow; TC_1275_1286.port_b.Q_flow = -TC_1275_1286.Q_flow; TC_1275_1483.Q_flow = TC_1275_1483.G * TC_1275_1483.dT; TC_1275_1483.dT = TC_1275_1483.port_a.T - TC_1275_1483.port_b.T; TC_1275_1483.port_a.Q_flow = TC_1275_1483.Q_flow; TC_1275_1483.port_b.Q_flow = -TC_1275_1483.Q_flow; TC_1276_1277.Q_flow = TC_1276_1277.G * TC_1276_1277.dT; TC_1276_1277.dT = TC_1276_1277.port_a.T - TC_1276_1277.port_b.T; TC_1276_1277.port_a.Q_flow = TC_1276_1277.Q_flow; TC_1276_1277.port_b.Q_flow = -TC_1276_1277.Q_flow; TC_1276_1287.Q_flow = TC_1276_1287.G * TC_1276_1287.dT; TC_1276_1287.dT = TC_1276_1287.port_a.T - TC_1276_1287.port_b.T; TC_1276_1287.port_a.Q_flow = TC_1276_1287.Q_flow; TC_1276_1287.port_b.Q_flow = -TC_1276_1287.Q_flow; TC_1276_1484.Q_flow = TC_1276_1484.G * TC_1276_1484.dT; TC_1276_1484.dT = TC_1276_1484.port_a.T - TC_1276_1484.port_b.T; TC_1276_1484.port_a.Q_flow = TC_1276_1484.Q_flow; TC_1276_1484.port_b.Q_flow = -TC_1276_1484.Q_flow; TC_1277_1278.Q_flow = TC_1277_1278.G * TC_1277_1278.dT; TC_1277_1278.dT = TC_1277_1278.port_a.T - TC_1277_1278.port_b.T; TC_1277_1278.port_a.Q_flow = TC_1277_1278.Q_flow; TC_1277_1278.port_b.Q_flow = -TC_1277_1278.Q_flow; TC_1277_1288.Q_flow = TC_1277_1288.G * TC_1277_1288.dT; TC_1277_1288.dT = TC_1277_1288.port_a.T - TC_1277_1288.port_b.T; TC_1277_1288.port_a.Q_flow = TC_1277_1288.Q_flow; TC_1277_1288.port_b.Q_flow = -TC_1277_1288.Q_flow; TC_1277_1485.Q_flow = TC_1277_1485.G * TC_1277_1485.dT; TC_1277_1485.dT = TC_1277_1485.port_a.T - TC_1277_1485.port_b.T; TC_1277_1485.port_a.Q_flow = TC_1277_1485.Q_flow; TC_1277_1485.port_b.Q_flow = -TC_1277_1485.Q_flow; TC_1278_1279.Q_flow = TC_1278_1279.G * TC_1278_1279.dT; TC_1278_1279.dT = TC_1278_1279.port_a.T - TC_1278_1279.port_b.T; TC_1278_1279.port_a.Q_flow = TC_1278_1279.Q_flow; TC_1278_1279.port_b.Q_flow = -TC_1278_1279.Q_flow; TC_1278_1289.Q_flow = TC_1278_1289.G * TC_1278_1289.dT; TC_1278_1289.dT = TC_1278_1289.port_a.T - TC_1278_1289.port_b.T; TC_1278_1289.port_a.Q_flow = TC_1278_1289.Q_flow; TC_1278_1289.port_b.Q_flow = -TC_1278_1289.Q_flow; TC_1278_1486.Q_flow = TC_1278_1486.G * TC_1278_1486.dT; TC_1278_1486.dT = TC_1278_1486.port_a.T - TC_1278_1486.port_b.T; TC_1278_1486.port_a.Q_flow = TC_1278_1486.Q_flow; TC_1278_1486.port_b.Q_flow = -TC_1278_1486.Q_flow; TC_1279_1290.Q_flow = TC_1279_1290.G * TC_1279_1290.dT; TC_1279_1290.dT = TC_1279_1290.port_a.T - TC_1279_1290.port_b.T; TC_1279_1290.port_a.Q_flow = TC_1279_1290.Q_flow; TC_1279_1290.port_b.Q_flow = -TC_1279_1290.Q_flow; TC_1279_1487.Q_flow = TC_1279_1487.G * TC_1279_1487.dT; TC_1279_1487.dT = TC_1279_1487.port_a.T - TC_1279_1487.port_b.T; TC_1279_1487.port_a.Q_flow = TC_1279_1487.Q_flow; TC_1279_1487.port_b.Q_flow = -TC_1279_1487.Q_flow; TC_1280_1281.Q_flow = TC_1280_1281.G * TC_1280_1281.dT; TC_1280_1281.dT = TC_1280_1281.port_a.T - TC_1280_1281.port_b.T; TC_1280_1281.port_a.Q_flow = TC_1280_1281.Q_flow; TC_1280_1281.port_b.Q_flow = -TC_1280_1281.Q_flow; TC_1280_1291.Q_flow = TC_1280_1291.G * TC_1280_1291.dT; TC_1280_1291.dT = TC_1280_1291.port_a.T - TC_1280_1291.port_b.T; TC_1280_1291.port_a.Q_flow = TC_1280_1291.Q_flow; TC_1280_1291.port_b.Q_flow = -TC_1280_1291.Q_flow; TC_1280_1466.Q_flow = TC_1280_1466.G * TC_1280_1466.dT; TC_1280_1466.dT = TC_1280_1466.port_a.T - TC_1280_1466.port_b.T; TC_1280_1466.port_a.Q_flow = TC_1280_1466.Q_flow; TC_1280_1466.port_b.Q_flow = -TC_1280_1466.Q_flow; TC_1281_1282.Q_flow = TC_1281_1282.G * TC_1281_1282.dT; TC_1281_1282.dT = TC_1281_1282.port_a.T - TC_1281_1282.port_b.T; TC_1281_1282.port_a.Q_flow = TC_1281_1282.Q_flow; TC_1281_1282.port_b.Q_flow = -TC_1281_1282.Q_flow; TC_1281_1292.Q_flow = TC_1281_1292.G * TC_1281_1292.dT; TC_1281_1292.dT = TC_1281_1292.port_a.T - TC_1281_1292.port_b.T; TC_1281_1292.port_a.Q_flow = TC_1281_1292.Q_flow; TC_1281_1292.port_b.Q_flow = -TC_1281_1292.Q_flow; TC_1281_1467.Q_flow = TC_1281_1467.G * TC_1281_1467.dT; TC_1281_1467.dT = TC_1281_1467.port_a.T - TC_1281_1467.port_b.T; TC_1281_1467.port_a.Q_flow = TC_1281_1467.Q_flow; TC_1281_1467.port_b.Q_flow = -TC_1281_1467.Q_flow; TC_1282_1283.Q_flow = TC_1282_1283.G * TC_1282_1283.dT; TC_1282_1283.dT = TC_1282_1283.port_a.T - TC_1282_1283.port_b.T; TC_1282_1283.port_a.Q_flow = TC_1282_1283.Q_flow; TC_1282_1283.port_b.Q_flow = -TC_1282_1283.Q_flow; TC_1282_1293.Q_flow = TC_1282_1293.G * TC_1282_1293.dT; TC_1282_1293.dT = TC_1282_1293.port_a.T - TC_1282_1293.port_b.T; TC_1282_1293.port_a.Q_flow = TC_1282_1293.Q_flow; TC_1282_1293.port_b.Q_flow = -TC_1282_1293.Q_flow; TC_1282_1468.Q_flow = TC_1282_1468.G * TC_1282_1468.dT; TC_1282_1468.dT = TC_1282_1468.port_a.T - TC_1282_1468.port_b.T; TC_1282_1468.port_a.Q_flow = TC_1282_1468.Q_flow; TC_1282_1468.port_b.Q_flow = -TC_1282_1468.Q_flow; TC_1283_1284.Q_flow = TC_1283_1284.G * TC_1283_1284.dT; TC_1283_1284.dT = TC_1283_1284.port_a.T - TC_1283_1284.port_b.T; TC_1283_1284.port_a.Q_flow = TC_1283_1284.Q_flow; TC_1283_1284.port_b.Q_flow = -TC_1283_1284.Q_flow; TC_1283_1294.Q_flow = TC_1283_1294.G * TC_1283_1294.dT; TC_1283_1294.dT = TC_1283_1294.port_a.T - TC_1283_1294.port_b.T; TC_1283_1294.port_a.Q_flow = TC_1283_1294.Q_flow; TC_1283_1294.port_b.Q_flow = -TC_1283_1294.Q_flow; TC_1283_1469.Q_flow = TC_1283_1469.G * TC_1283_1469.dT; TC_1283_1469.dT = TC_1283_1469.port_a.T - TC_1283_1469.port_b.T; TC_1283_1469.port_a.Q_flow = TC_1283_1469.Q_flow; TC_1283_1469.port_b.Q_flow = -TC_1283_1469.Q_flow; TC_1284_1285.Q_flow = TC_1284_1285.G * TC_1284_1285.dT; TC_1284_1285.dT = TC_1284_1285.port_a.T - TC_1284_1285.port_b.T; TC_1284_1285.port_a.Q_flow = TC_1284_1285.Q_flow; TC_1284_1285.port_b.Q_flow = -TC_1284_1285.Q_flow; TC_1284_1295.Q_flow = TC_1284_1295.G * TC_1284_1295.dT; TC_1284_1295.dT = TC_1284_1295.port_a.T - TC_1284_1295.port_b.T; TC_1284_1295.port_a.Q_flow = TC_1284_1295.Q_flow; TC_1284_1295.port_b.Q_flow = -TC_1284_1295.Q_flow; TC_1284_1470.Q_flow = TC_1284_1470.G * TC_1284_1470.dT; TC_1284_1470.dT = TC_1284_1470.port_a.T - TC_1284_1470.port_b.T; TC_1284_1470.port_a.Q_flow = TC_1284_1470.Q_flow; TC_1284_1470.port_b.Q_flow = -TC_1284_1470.Q_flow; TC_1285_1286.Q_flow = TC_1285_1286.G * TC_1285_1286.dT; TC_1285_1286.dT = TC_1285_1286.port_a.T - TC_1285_1286.port_b.T; TC_1285_1286.port_a.Q_flow = TC_1285_1286.Q_flow; TC_1285_1286.port_b.Q_flow = -TC_1285_1286.Q_flow; TC_1285_1296.Q_flow = TC_1285_1296.G * TC_1285_1296.dT; TC_1285_1296.dT = TC_1285_1296.port_a.T - TC_1285_1296.port_b.T; TC_1285_1296.port_a.Q_flow = TC_1285_1296.Q_flow; TC_1285_1296.port_b.Q_flow = -TC_1285_1296.Q_flow; TC_1285_1471.Q_flow = TC_1285_1471.G * TC_1285_1471.dT; TC_1285_1471.dT = TC_1285_1471.port_a.T - TC_1285_1471.port_b.T; TC_1285_1471.port_a.Q_flow = TC_1285_1471.Q_flow; TC_1285_1471.port_b.Q_flow = -TC_1285_1471.Q_flow; TC_1286_1287.Q_flow = TC_1286_1287.G * TC_1286_1287.dT; TC_1286_1287.dT = TC_1286_1287.port_a.T - TC_1286_1287.port_b.T; TC_1286_1287.port_a.Q_flow = TC_1286_1287.Q_flow; TC_1286_1287.port_b.Q_flow = -TC_1286_1287.Q_flow; TC_1286_1297.Q_flow = TC_1286_1297.G * TC_1286_1297.dT; TC_1286_1297.dT = TC_1286_1297.port_a.T - TC_1286_1297.port_b.T; TC_1286_1297.port_a.Q_flow = TC_1286_1297.Q_flow; TC_1286_1297.port_b.Q_flow = -TC_1286_1297.Q_flow; TC_1286_1472.Q_flow = TC_1286_1472.G * TC_1286_1472.dT; TC_1286_1472.dT = TC_1286_1472.port_a.T - TC_1286_1472.port_b.T; TC_1286_1472.port_a.Q_flow = TC_1286_1472.Q_flow; TC_1286_1472.port_b.Q_flow = -TC_1286_1472.Q_flow; TC_1287_1288.Q_flow = TC_1287_1288.G * TC_1287_1288.dT; TC_1287_1288.dT = TC_1287_1288.port_a.T - TC_1287_1288.port_b.T; TC_1287_1288.port_a.Q_flow = TC_1287_1288.Q_flow; TC_1287_1288.port_b.Q_flow = -TC_1287_1288.Q_flow; TC_1287_1298.Q_flow = TC_1287_1298.G * TC_1287_1298.dT; TC_1287_1298.dT = TC_1287_1298.port_a.T - TC_1287_1298.port_b.T; TC_1287_1298.port_a.Q_flow = TC_1287_1298.Q_flow; TC_1287_1298.port_b.Q_flow = -TC_1287_1298.Q_flow; TC_1287_1473.Q_flow = TC_1287_1473.G * TC_1287_1473.dT; TC_1287_1473.dT = TC_1287_1473.port_a.T - TC_1287_1473.port_b.T; TC_1287_1473.port_a.Q_flow = TC_1287_1473.Q_flow; TC_1287_1473.port_b.Q_flow = -TC_1287_1473.Q_flow; TC_1288_1289.Q_flow = TC_1288_1289.G * TC_1288_1289.dT; TC_1288_1289.dT = TC_1288_1289.port_a.T - TC_1288_1289.port_b.T; TC_1288_1289.port_a.Q_flow = TC_1288_1289.Q_flow; TC_1288_1289.port_b.Q_flow = -TC_1288_1289.Q_flow; TC_1288_1299.Q_flow = TC_1288_1299.G * TC_1288_1299.dT; TC_1288_1299.dT = TC_1288_1299.port_a.T - TC_1288_1299.port_b.T; TC_1288_1299.port_a.Q_flow = TC_1288_1299.Q_flow; TC_1288_1299.port_b.Q_flow = -TC_1288_1299.Q_flow; TC_1288_1474.Q_flow = TC_1288_1474.G * TC_1288_1474.dT; TC_1288_1474.dT = TC_1288_1474.port_a.T - TC_1288_1474.port_b.T; TC_1288_1474.port_a.Q_flow = TC_1288_1474.Q_flow; TC_1288_1474.port_b.Q_flow = -TC_1288_1474.Q_flow; TC_1289_1290.Q_flow = TC_1289_1290.G * TC_1289_1290.dT; TC_1289_1290.dT = TC_1289_1290.port_a.T - TC_1289_1290.port_b.T; TC_1289_1290.port_a.Q_flow = TC_1289_1290.Q_flow; TC_1289_1290.port_b.Q_flow = -TC_1289_1290.Q_flow; TC_1289_1300.Q_flow = TC_1289_1300.G * TC_1289_1300.dT; TC_1289_1300.dT = TC_1289_1300.port_a.T - TC_1289_1300.port_b.T; TC_1289_1300.port_a.Q_flow = TC_1289_1300.Q_flow; TC_1289_1300.port_b.Q_flow = -TC_1289_1300.Q_flow; TC_1289_1475.Q_flow = TC_1289_1475.G * TC_1289_1475.dT; TC_1289_1475.dT = TC_1289_1475.port_a.T - TC_1289_1475.port_b.T; TC_1289_1475.port_a.Q_flow = TC_1289_1475.Q_flow; TC_1289_1475.port_b.Q_flow = -TC_1289_1475.Q_flow; TC_1290_1301.Q_flow = TC_1290_1301.G * TC_1290_1301.dT; TC_1290_1301.dT = TC_1290_1301.port_a.T - TC_1290_1301.port_b.T; TC_1290_1301.port_a.Q_flow = TC_1290_1301.Q_flow; TC_1290_1301.port_b.Q_flow = -TC_1290_1301.Q_flow; TC_1290_1476.Q_flow = TC_1290_1476.G * TC_1290_1476.dT; TC_1290_1476.dT = TC_1290_1476.port_a.T - TC_1290_1476.port_b.T; TC_1290_1476.port_a.Q_flow = TC_1290_1476.Q_flow; TC_1290_1476.port_b.Q_flow = -TC_1290_1476.Q_flow; TC_1291_1292.Q_flow = TC_1291_1292.G * TC_1291_1292.dT; TC_1291_1292.dT = TC_1291_1292.port_a.T - TC_1291_1292.port_b.T; TC_1291_1292.port_a.Q_flow = TC_1291_1292.Q_flow; TC_1291_1292.port_b.Q_flow = -TC_1291_1292.Q_flow; TC_1291_1302.Q_flow = TC_1291_1302.G * TC_1291_1302.dT; TC_1291_1302.dT = TC_1291_1302.port_a.T - TC_1291_1302.port_b.T; TC_1291_1302.port_a.Q_flow = TC_1291_1302.Q_flow; TC_1291_1302.port_b.Q_flow = -TC_1291_1302.Q_flow; TC_1291_1461.Q_flow = TC_1291_1461.G * TC_1291_1461.dT; TC_1291_1461.dT = TC_1291_1461.port_a.T - TC_1291_1461.port_b.T; TC_1291_1461.port_a.Q_flow = TC_1291_1461.Q_flow; TC_1291_1461.port_b.Q_flow = -TC_1291_1461.Q_flow; TC_1292_1293.Q_flow = TC_1292_1293.G * TC_1292_1293.dT; TC_1292_1293.dT = TC_1292_1293.port_a.T - TC_1292_1293.port_b.T; TC_1292_1293.port_a.Q_flow = TC_1292_1293.Q_flow; TC_1292_1293.port_b.Q_flow = -TC_1292_1293.Q_flow; TC_1292_1303.Q_flow = TC_1292_1303.G * TC_1292_1303.dT; TC_1292_1303.dT = TC_1292_1303.port_a.T - TC_1292_1303.port_b.T; TC_1292_1303.port_a.Q_flow = TC_1292_1303.Q_flow; TC_1292_1303.port_b.Q_flow = -TC_1292_1303.Q_flow; TC_1292_1462.Q_flow = TC_1292_1462.G * TC_1292_1462.dT; TC_1292_1462.dT = TC_1292_1462.port_a.T - TC_1292_1462.port_b.T; TC_1292_1462.port_a.Q_flow = TC_1292_1462.Q_flow; TC_1292_1462.port_b.Q_flow = -TC_1292_1462.Q_flow; TC_1293_1294.Q_flow = TC_1293_1294.G * TC_1293_1294.dT; TC_1293_1294.dT = TC_1293_1294.port_a.T - TC_1293_1294.port_b.T; TC_1293_1294.port_a.Q_flow = TC_1293_1294.Q_flow; TC_1293_1294.port_b.Q_flow = -TC_1293_1294.Q_flow; TC_1293_1304.Q_flow = TC_1293_1304.G * TC_1293_1304.dT; TC_1293_1304.dT = TC_1293_1304.port_a.T - TC_1293_1304.port_b.T; TC_1293_1304.port_a.Q_flow = TC_1293_1304.Q_flow; TC_1293_1304.port_b.Q_flow = -TC_1293_1304.Q_flow; TC_1293_1497.Q_flow = TC_1293_1497.G * TC_1293_1497.dT; TC_1293_1497.dT = TC_1293_1497.port_a.T - TC_1293_1497.port_b.T; TC_1293_1497.port_a.Q_flow = TC_1293_1497.Q_flow; TC_1293_1497.port_b.Q_flow = -TC_1293_1497.Q_flow; TC_1294_1295.Q_flow = TC_1294_1295.G * TC_1294_1295.dT; TC_1294_1295.dT = TC_1294_1295.port_a.T - TC_1294_1295.port_b.T; TC_1294_1295.port_a.Q_flow = TC_1294_1295.Q_flow; TC_1294_1295.port_b.Q_flow = -TC_1294_1295.Q_flow; TC_1294_1305.Q_flow = TC_1294_1305.G * TC_1294_1305.dT; TC_1294_1305.dT = TC_1294_1305.port_a.T - TC_1294_1305.port_b.T; TC_1294_1305.port_a.Q_flow = TC_1294_1305.Q_flow; TC_1294_1305.port_b.Q_flow = -TC_1294_1305.Q_flow; TC_1294_1498.Q_flow = TC_1294_1498.G * TC_1294_1498.dT; TC_1294_1498.dT = TC_1294_1498.port_a.T - TC_1294_1498.port_b.T; TC_1294_1498.port_a.Q_flow = TC_1294_1498.Q_flow; TC_1294_1498.port_b.Q_flow = -TC_1294_1498.Q_flow; TC_1295_1296.Q_flow = TC_1295_1296.G * TC_1295_1296.dT; TC_1295_1296.dT = TC_1295_1296.port_a.T - TC_1295_1296.port_b.T; TC_1295_1296.port_a.Q_flow = TC_1295_1296.Q_flow; TC_1295_1296.port_b.Q_flow = -TC_1295_1296.Q_flow; TC_1295_1306.Q_flow = TC_1295_1306.G * TC_1295_1306.dT; TC_1295_1306.dT = TC_1295_1306.port_a.T - TC_1295_1306.port_b.T; TC_1295_1306.port_a.Q_flow = TC_1295_1306.Q_flow; TC_1295_1306.port_b.Q_flow = -TC_1295_1306.Q_flow; TC_1295_1499.Q_flow = TC_1295_1499.G * TC_1295_1499.dT; TC_1295_1499.dT = TC_1295_1499.port_a.T - TC_1295_1499.port_b.T; TC_1295_1499.port_a.Q_flow = TC_1295_1499.Q_flow; TC_1295_1499.port_b.Q_flow = -TC_1295_1499.Q_flow; TC_1296_1297.Q_flow = TC_1296_1297.G * TC_1296_1297.dT; TC_1296_1297.dT = TC_1296_1297.port_a.T - TC_1296_1297.port_b.T; TC_1296_1297.port_a.Q_flow = TC_1296_1297.Q_flow; TC_1296_1297.port_b.Q_flow = -TC_1296_1297.Q_flow; TC_1296_1307.Q_flow = TC_1296_1307.G * TC_1296_1307.dT; TC_1296_1307.dT = TC_1296_1307.port_a.T - TC_1296_1307.port_b.T; TC_1296_1307.port_a.Q_flow = TC_1296_1307.Q_flow; TC_1296_1307.port_b.Q_flow = -TC_1296_1307.Q_flow; TC_1296_1500.Q_flow = TC_1296_1500.G * TC_1296_1500.dT; TC_1296_1500.dT = TC_1296_1500.port_a.T - TC_1296_1500.port_b.T; TC_1296_1500.port_a.Q_flow = TC_1296_1500.Q_flow; TC_1296_1500.port_b.Q_flow = -TC_1296_1500.Q_flow; TC_1297_1298.Q_flow = TC_1297_1298.G * TC_1297_1298.dT; TC_1297_1298.dT = TC_1297_1298.port_a.T - TC_1297_1298.port_b.T; TC_1297_1298.port_a.Q_flow = TC_1297_1298.Q_flow; TC_1297_1298.port_b.Q_flow = -TC_1297_1298.Q_flow; TC_1297_1308.Q_flow = TC_1297_1308.G * TC_1297_1308.dT; TC_1297_1308.dT = TC_1297_1308.port_a.T - TC_1297_1308.port_b.T; TC_1297_1308.port_a.Q_flow = TC_1297_1308.Q_flow; TC_1297_1308.port_b.Q_flow = -TC_1297_1308.Q_flow; TC_1298_1299.Q_flow = TC_1298_1299.G * TC_1298_1299.dT; TC_1298_1299.dT = TC_1298_1299.port_a.T - TC_1298_1299.port_b.T; TC_1298_1299.port_a.Q_flow = TC_1298_1299.Q_flow; TC_1298_1299.port_b.Q_flow = -TC_1298_1299.Q_flow; TC_1298_1309.Q_flow = TC_1298_1309.G * TC_1298_1309.dT; TC_1298_1309.dT = TC_1298_1309.port_a.T - TC_1298_1309.port_b.T; TC_1298_1309.port_a.Q_flow = TC_1298_1309.Q_flow; TC_1298_1309.port_b.Q_flow = -TC_1298_1309.Q_flow; TC_1299_1300.Q_flow = TC_1299_1300.G * TC_1299_1300.dT; TC_1299_1300.dT = TC_1299_1300.port_a.T - TC_1299_1300.port_b.T; TC_1299_1300.port_a.Q_flow = TC_1299_1300.Q_flow; TC_1299_1300.port_b.Q_flow = -TC_1299_1300.Q_flow; TC_1299_1310.Q_flow = TC_1299_1310.G * TC_1299_1310.dT; TC_1299_1310.dT = TC_1299_1310.port_a.T - TC_1299_1310.port_b.T; TC_1299_1310.port_a.Q_flow = TC_1299_1310.Q_flow; TC_1299_1310.port_b.Q_flow = -TC_1299_1310.Q_flow; TC_1300_1301.Q_flow = TC_1300_1301.G * TC_1300_1301.dT; TC_1300_1301.dT = TC_1300_1301.port_a.T - TC_1300_1301.port_b.T; TC_1300_1301.port_a.Q_flow = TC_1300_1301.Q_flow; TC_1300_1301.port_b.Q_flow = -TC_1300_1301.Q_flow; TC_1300_1311.Q_flow = TC_1300_1311.G * TC_1300_1311.dT; TC_1300_1311.dT = TC_1300_1311.port_a.T - TC_1300_1311.port_b.T; TC_1300_1311.port_a.Q_flow = TC_1300_1311.Q_flow; TC_1300_1311.port_b.Q_flow = -TC_1300_1311.Q_flow; TC_1301_1312.Q_flow = TC_1301_1312.G * TC_1301_1312.dT; TC_1301_1312.dT = TC_1301_1312.port_a.T - TC_1301_1312.port_b.T; TC_1301_1312.port_a.Q_flow = TC_1301_1312.Q_flow; TC_1301_1312.port_b.Q_flow = -TC_1301_1312.Q_flow; TC_1301_1463.Q_flow = TC_1301_1463.G * TC_1301_1463.dT; TC_1301_1463.dT = TC_1301_1463.port_a.T - TC_1301_1463.port_b.T; TC_1301_1463.port_a.Q_flow = TC_1301_1463.Q_flow; TC_1301_1463.port_b.Q_flow = -TC_1301_1463.Q_flow; TC_1302_1303.Q_flow = TC_1302_1303.G * TC_1302_1303.dT; TC_1302_1303.dT = TC_1302_1303.port_a.T - TC_1302_1303.port_b.T; TC_1302_1303.port_a.Q_flow = TC_1302_1303.Q_flow; TC_1302_1303.port_b.Q_flow = -TC_1302_1303.Q_flow; TC_1302_1313.Q_flow = TC_1302_1313.G * TC_1302_1313.dT; TC_1302_1313.dT = TC_1302_1313.port_a.T - TC_1302_1313.port_b.T; TC_1302_1313.port_a.Q_flow = TC_1302_1313.Q_flow; TC_1302_1313.port_b.Q_flow = -TC_1302_1313.Q_flow; TC_1302_1464.Q_flow = TC_1302_1464.G * TC_1302_1464.dT; TC_1302_1464.dT = TC_1302_1464.port_a.T - TC_1302_1464.port_b.T; TC_1302_1464.port_a.Q_flow = TC_1302_1464.Q_flow; TC_1302_1464.port_b.Q_flow = -TC_1302_1464.Q_flow; TC_1303_1304.Q_flow = TC_1303_1304.G * TC_1303_1304.dT; TC_1303_1304.dT = TC_1303_1304.port_a.T - TC_1303_1304.port_b.T; TC_1303_1304.port_a.Q_flow = TC_1303_1304.Q_flow; TC_1303_1304.port_b.Q_flow = -TC_1303_1304.Q_flow; TC_1303_1314.Q_flow = TC_1303_1314.G * TC_1303_1314.dT; TC_1303_1314.dT = TC_1303_1314.port_a.T - TC_1303_1314.port_b.T; TC_1303_1314.port_a.Q_flow = TC_1303_1314.Q_flow; TC_1303_1314.port_b.Q_flow = -TC_1303_1314.Q_flow; TC_1303_1465.Q_flow = TC_1303_1465.G * TC_1303_1465.dT; TC_1303_1465.dT = TC_1303_1465.port_a.T - TC_1303_1465.port_b.T; TC_1303_1465.port_a.Q_flow = TC_1303_1465.Q_flow; TC_1303_1465.port_b.Q_flow = -TC_1303_1465.Q_flow; TC_1304_1305.Q_flow = TC_1304_1305.G * TC_1304_1305.dT; TC_1304_1305.dT = TC_1304_1305.port_a.T - TC_1304_1305.port_b.T; TC_1304_1305.port_a.Q_flow = TC_1304_1305.Q_flow; TC_1304_1305.port_b.Q_flow = -TC_1304_1305.Q_flow; TC_1304_1315.Q_flow = TC_1304_1315.G * TC_1304_1315.dT; TC_1304_1315.dT = TC_1304_1315.port_a.T - TC_1304_1315.port_b.T; TC_1304_1315.port_a.Q_flow = TC_1304_1315.Q_flow; TC_1304_1315.port_b.Q_flow = -TC_1304_1315.Q_flow; TC_1304_1501.Q_flow = TC_1304_1501.G * TC_1304_1501.dT; TC_1304_1501.dT = TC_1304_1501.port_a.T - TC_1304_1501.port_b.T; TC_1304_1501.port_a.Q_flow = TC_1304_1501.Q_flow; TC_1304_1501.port_b.Q_flow = -TC_1304_1501.Q_flow; TC_1305_1306.Q_flow = TC_1305_1306.G * TC_1305_1306.dT; TC_1305_1306.dT = TC_1305_1306.port_a.T - TC_1305_1306.port_b.T; TC_1305_1306.port_a.Q_flow = TC_1305_1306.Q_flow; TC_1305_1306.port_b.Q_flow = -TC_1305_1306.Q_flow; TC_1305_1316.Q_flow = TC_1305_1316.G * TC_1305_1316.dT; TC_1305_1316.dT = TC_1305_1316.port_a.T - TC_1305_1316.port_b.T; TC_1305_1316.port_a.Q_flow = TC_1305_1316.Q_flow; TC_1305_1316.port_b.Q_flow = -TC_1305_1316.Q_flow; TC_1305_1502.Q_flow = TC_1305_1502.G * TC_1305_1502.dT; TC_1305_1502.dT = TC_1305_1502.port_a.T - TC_1305_1502.port_b.T; TC_1305_1502.port_a.Q_flow = TC_1305_1502.Q_flow; TC_1305_1502.port_b.Q_flow = -TC_1305_1502.Q_flow; TC_1306_1307.Q_flow = TC_1306_1307.G * TC_1306_1307.dT; TC_1306_1307.dT = TC_1306_1307.port_a.T - TC_1306_1307.port_b.T; TC_1306_1307.port_a.Q_flow = TC_1306_1307.Q_flow; TC_1306_1307.port_b.Q_flow = -TC_1306_1307.Q_flow; TC_1306_1317.Q_flow = TC_1306_1317.G * TC_1306_1317.dT; TC_1306_1317.dT = TC_1306_1317.port_a.T - TC_1306_1317.port_b.T; TC_1306_1317.port_a.Q_flow = TC_1306_1317.Q_flow; TC_1306_1317.port_b.Q_flow = -TC_1306_1317.Q_flow; TC_1306_1503.Q_flow = TC_1306_1503.G * TC_1306_1503.dT; TC_1306_1503.dT = TC_1306_1503.port_a.T - TC_1306_1503.port_b.T; TC_1306_1503.port_a.Q_flow = TC_1306_1503.Q_flow; TC_1306_1503.port_b.Q_flow = -TC_1306_1503.Q_flow; TC_1307_1308.Q_flow = TC_1307_1308.G * TC_1307_1308.dT; TC_1307_1308.dT = TC_1307_1308.port_a.T - TC_1307_1308.port_b.T; TC_1307_1308.port_a.Q_flow = TC_1307_1308.Q_flow; TC_1307_1308.port_b.Q_flow = -TC_1307_1308.Q_flow; TC_1307_1318.Q_flow = TC_1307_1318.G * TC_1307_1318.dT; TC_1307_1318.dT = TC_1307_1318.port_a.T - TC_1307_1318.port_b.T; TC_1307_1318.port_a.Q_flow = TC_1307_1318.Q_flow; TC_1307_1318.port_b.Q_flow = -TC_1307_1318.Q_flow; TC_1307_1504.Q_flow = TC_1307_1504.G * TC_1307_1504.dT; TC_1307_1504.dT = TC_1307_1504.port_a.T - TC_1307_1504.port_b.T; TC_1307_1504.port_a.Q_flow = TC_1307_1504.Q_flow; TC_1307_1504.port_b.Q_flow = -TC_1307_1504.Q_flow; TC_1308_1309.Q_flow = TC_1308_1309.G * TC_1308_1309.dT; TC_1308_1309.dT = TC_1308_1309.port_a.T - TC_1308_1309.port_b.T; TC_1308_1309.port_a.Q_flow = TC_1308_1309.Q_flow; TC_1308_1309.port_b.Q_flow = -TC_1308_1309.Q_flow; TC_1308_1319.Q_flow = TC_1308_1319.G * TC_1308_1319.dT; TC_1308_1319.dT = TC_1308_1319.port_a.T - TC_1308_1319.port_b.T; TC_1308_1319.port_a.Q_flow = TC_1308_1319.Q_flow; TC_1308_1319.port_b.Q_flow = -TC_1308_1319.Q_flow; TC_1309_1310.Q_flow = TC_1309_1310.G * TC_1309_1310.dT; TC_1309_1310.dT = TC_1309_1310.port_a.T - TC_1309_1310.port_b.T; TC_1309_1310.port_a.Q_flow = TC_1309_1310.Q_flow; TC_1309_1310.port_b.Q_flow = -TC_1309_1310.Q_flow; TC_1309_1320.Q_flow = TC_1309_1320.G * TC_1309_1320.dT; TC_1309_1320.dT = TC_1309_1320.port_a.T - TC_1309_1320.port_b.T; TC_1309_1320.port_a.Q_flow = TC_1309_1320.Q_flow; TC_1309_1320.port_b.Q_flow = -TC_1309_1320.Q_flow; TC_1310_1311.Q_flow = TC_1310_1311.G * TC_1310_1311.dT; TC_1310_1311.dT = TC_1310_1311.port_a.T - TC_1310_1311.port_b.T; TC_1310_1311.port_a.Q_flow = TC_1310_1311.Q_flow; TC_1310_1311.port_b.Q_flow = -TC_1310_1311.Q_flow; TC_1310_1321.Q_flow = TC_1310_1321.G * TC_1310_1321.dT; TC_1310_1321.dT = TC_1310_1321.port_a.T - TC_1310_1321.port_b.T; TC_1310_1321.port_a.Q_flow = TC_1310_1321.Q_flow; TC_1310_1321.port_b.Q_flow = -TC_1310_1321.Q_flow; TC_1311_1312.Q_flow = TC_1311_1312.G * TC_1311_1312.dT; TC_1311_1312.dT = TC_1311_1312.port_a.T - TC_1311_1312.port_b.T; TC_1311_1312.port_a.Q_flow = TC_1311_1312.Q_flow; TC_1311_1312.port_b.Q_flow = -TC_1311_1312.Q_flow; TC_1311_1322.Q_flow = TC_1311_1322.G * TC_1311_1322.dT; TC_1311_1322.dT = TC_1311_1322.port_a.T - TC_1311_1322.port_b.T; TC_1311_1322.port_a.Q_flow = TC_1311_1322.Q_flow; TC_1311_1322.port_b.Q_flow = -TC_1311_1322.Q_flow; TC_1312_1323.Q_flow = TC_1312_1323.G * TC_1312_1323.dT; TC_1312_1323.dT = TC_1312_1323.port_a.T - TC_1312_1323.port_b.T; TC_1312_1323.port_a.Q_flow = TC_1312_1323.Q_flow; TC_1312_1323.port_b.Q_flow = -TC_1312_1323.Q_flow; TC_1312_1414.Q_flow = TC_1312_1414.G * TC_1312_1414.dT; TC_1312_1414.dT = TC_1312_1414.port_a.T - TC_1312_1414.port_b.T; TC_1312_1414.port_a.Q_flow = TC_1312_1414.Q_flow; TC_1312_1414.port_b.Q_flow = -TC_1312_1414.Q_flow; TC_1313_1314.Q_flow = TC_1313_1314.G * TC_1313_1314.dT; TC_1313_1314.dT = TC_1313_1314.port_a.T - TC_1313_1314.port_b.T; TC_1313_1314.port_a.Q_flow = TC_1313_1314.Q_flow; TC_1313_1314.port_b.Q_flow = -TC_1313_1314.Q_flow; TC_1313_1324.Q_flow = TC_1313_1324.G * TC_1313_1324.dT; TC_1313_1324.dT = TC_1313_1324.port_a.T - TC_1313_1324.port_b.T; TC_1313_1324.port_a.Q_flow = TC_1313_1324.Q_flow; TC_1313_1324.port_b.Q_flow = -TC_1313_1324.Q_flow; TC_1313_1415.Q_flow = TC_1313_1415.G * TC_1313_1415.dT; TC_1313_1415.dT = TC_1313_1415.port_a.T - TC_1313_1415.port_b.T; TC_1313_1415.port_a.Q_flow = TC_1313_1415.Q_flow; TC_1313_1415.port_b.Q_flow = -TC_1313_1415.Q_flow; TC_1314_1315.Q_flow = TC_1314_1315.G * TC_1314_1315.dT; TC_1314_1315.dT = TC_1314_1315.port_a.T - TC_1314_1315.port_b.T; TC_1314_1315.port_a.Q_flow = TC_1314_1315.Q_flow; TC_1314_1315.port_b.Q_flow = -TC_1314_1315.Q_flow; TC_1314_1325.Q_flow = TC_1314_1325.G * TC_1314_1325.dT; TC_1314_1325.dT = TC_1314_1325.port_a.T - TC_1314_1325.port_b.T; TC_1314_1325.port_a.Q_flow = TC_1314_1325.Q_flow; TC_1314_1325.port_b.Q_flow = -TC_1314_1325.Q_flow; TC_1314_1416.Q_flow = TC_1314_1416.G * TC_1314_1416.dT; TC_1314_1416.dT = TC_1314_1416.port_a.T - TC_1314_1416.port_b.T; TC_1314_1416.port_a.Q_flow = TC_1314_1416.Q_flow; TC_1314_1416.port_b.Q_flow = -TC_1314_1416.Q_flow; TC_1315_1316.Q_flow = TC_1315_1316.G * TC_1315_1316.dT; TC_1315_1316.dT = TC_1315_1316.port_a.T - TC_1315_1316.port_b.T; TC_1315_1316.port_a.Q_flow = TC_1315_1316.Q_flow; TC_1315_1316.port_b.Q_flow = -TC_1315_1316.Q_flow; TC_1315_1326.Q_flow = TC_1315_1326.G * TC_1315_1326.dT; TC_1315_1326.dT = TC_1315_1326.port_a.T - TC_1315_1326.port_b.T; TC_1315_1326.port_a.Q_flow = TC_1315_1326.Q_flow; TC_1315_1326.port_b.Q_flow = -TC_1315_1326.Q_flow; TC_1315_1505.Q_flow = TC_1315_1505.G * TC_1315_1505.dT; TC_1315_1505.dT = TC_1315_1505.port_a.T - TC_1315_1505.port_b.T; TC_1315_1505.port_a.Q_flow = TC_1315_1505.Q_flow; TC_1315_1505.port_b.Q_flow = -TC_1315_1505.Q_flow; TC_1316_1317.Q_flow = TC_1316_1317.G * TC_1316_1317.dT; TC_1316_1317.dT = TC_1316_1317.port_a.T - TC_1316_1317.port_b.T; TC_1316_1317.port_a.Q_flow = TC_1316_1317.Q_flow; TC_1316_1317.port_b.Q_flow = -TC_1316_1317.Q_flow; TC_1316_1327.Q_flow = TC_1316_1327.G * TC_1316_1327.dT; TC_1316_1327.dT = TC_1316_1327.port_a.T - TC_1316_1327.port_b.T; TC_1316_1327.port_a.Q_flow = TC_1316_1327.Q_flow; TC_1316_1327.port_b.Q_flow = -TC_1316_1327.Q_flow; TC_1316_1506.Q_flow = TC_1316_1506.G * TC_1316_1506.dT; TC_1316_1506.dT = TC_1316_1506.port_a.T - TC_1316_1506.port_b.T; TC_1316_1506.port_a.Q_flow = TC_1316_1506.Q_flow; TC_1316_1506.port_b.Q_flow = -TC_1316_1506.Q_flow; TC_1317_1318.Q_flow = TC_1317_1318.G * TC_1317_1318.dT; TC_1317_1318.dT = TC_1317_1318.port_a.T - TC_1317_1318.port_b.T; TC_1317_1318.port_a.Q_flow = TC_1317_1318.Q_flow; TC_1317_1318.port_b.Q_flow = -TC_1317_1318.Q_flow; TC_1317_1328.Q_flow = TC_1317_1328.G * TC_1317_1328.dT; TC_1317_1328.dT = TC_1317_1328.port_a.T - TC_1317_1328.port_b.T; TC_1317_1328.port_a.Q_flow = TC_1317_1328.Q_flow; TC_1317_1328.port_b.Q_flow = -TC_1317_1328.Q_flow; TC_1317_1507.Q_flow = TC_1317_1507.G * TC_1317_1507.dT; TC_1317_1507.dT = TC_1317_1507.port_a.T - TC_1317_1507.port_b.T; TC_1317_1507.port_a.Q_flow = TC_1317_1507.Q_flow; TC_1317_1507.port_b.Q_flow = -TC_1317_1507.Q_flow; TC_1318_1319.Q_flow = TC_1318_1319.G * TC_1318_1319.dT; TC_1318_1319.dT = TC_1318_1319.port_a.T - TC_1318_1319.port_b.T; TC_1318_1319.port_a.Q_flow = TC_1318_1319.Q_flow; TC_1318_1319.port_b.Q_flow = -TC_1318_1319.Q_flow; TC_1318_1329.Q_flow = TC_1318_1329.G * TC_1318_1329.dT; TC_1318_1329.dT = TC_1318_1329.port_a.T - TC_1318_1329.port_b.T; TC_1318_1329.port_a.Q_flow = TC_1318_1329.Q_flow; TC_1318_1329.port_b.Q_flow = -TC_1318_1329.Q_flow; TC_1318_1508.Q_flow = TC_1318_1508.G * TC_1318_1508.dT; TC_1318_1508.dT = TC_1318_1508.port_a.T - TC_1318_1508.port_b.T; TC_1318_1508.port_a.Q_flow = TC_1318_1508.Q_flow; TC_1318_1508.port_b.Q_flow = -TC_1318_1508.Q_flow; TC_1319_1320.Q_flow = TC_1319_1320.G * TC_1319_1320.dT; TC_1319_1320.dT = TC_1319_1320.port_a.T - TC_1319_1320.port_b.T; TC_1319_1320.port_a.Q_flow = TC_1319_1320.Q_flow; TC_1319_1320.port_b.Q_flow = -TC_1319_1320.Q_flow; TC_1319_1330.Q_flow = TC_1319_1330.G * TC_1319_1330.dT; TC_1319_1330.dT = TC_1319_1330.port_a.T - TC_1319_1330.port_b.T; TC_1319_1330.port_a.Q_flow = TC_1319_1330.Q_flow; TC_1319_1330.port_b.Q_flow = -TC_1319_1330.Q_flow; TC_1320_1321.Q_flow = TC_1320_1321.G * TC_1320_1321.dT; TC_1320_1321.dT = TC_1320_1321.port_a.T - TC_1320_1321.port_b.T; TC_1320_1321.port_a.Q_flow = TC_1320_1321.Q_flow; TC_1320_1321.port_b.Q_flow = -TC_1320_1321.Q_flow; TC_1320_1331.Q_flow = TC_1320_1331.G * TC_1320_1331.dT; TC_1320_1331.dT = TC_1320_1331.port_a.T - TC_1320_1331.port_b.T; TC_1320_1331.port_a.Q_flow = TC_1320_1331.Q_flow; TC_1320_1331.port_b.Q_flow = -TC_1320_1331.Q_flow; TC_1321_1322.Q_flow = TC_1321_1322.G * TC_1321_1322.dT; TC_1321_1322.dT = TC_1321_1322.port_a.T - TC_1321_1322.port_b.T; TC_1321_1322.port_a.Q_flow = TC_1321_1322.Q_flow; TC_1321_1322.port_b.Q_flow = -TC_1321_1322.Q_flow; TC_1321_1332.Q_flow = TC_1321_1332.G * TC_1321_1332.dT; TC_1321_1332.dT = TC_1321_1332.port_a.T - TC_1321_1332.port_b.T; TC_1321_1332.port_a.Q_flow = TC_1321_1332.Q_flow; TC_1321_1332.port_b.Q_flow = -TC_1321_1332.Q_flow; TC_1322_1323.Q_flow = TC_1322_1323.G * TC_1322_1323.dT; TC_1322_1323.dT = TC_1322_1323.port_a.T - TC_1322_1323.port_b.T; TC_1322_1323.port_a.Q_flow = TC_1322_1323.Q_flow; TC_1322_1323.port_b.Q_flow = -TC_1322_1323.Q_flow; TC_1322_1333.Q_flow = TC_1322_1333.G * TC_1322_1333.dT; TC_1322_1333.dT = TC_1322_1333.port_a.T - TC_1322_1333.port_b.T; TC_1322_1333.port_a.Q_flow = TC_1322_1333.Q_flow; TC_1322_1333.port_b.Q_flow = -TC_1322_1333.Q_flow; TC_1323_1334.Q_flow = TC_1323_1334.G * TC_1323_1334.dT; TC_1323_1334.dT = TC_1323_1334.port_a.T - TC_1323_1334.port_b.T; TC_1323_1334.port_a.Q_flow = TC_1323_1334.Q_flow; TC_1323_1334.port_b.Q_flow = -TC_1323_1334.Q_flow; TC_1323_1417.Q_flow = TC_1323_1417.G * TC_1323_1417.dT; TC_1323_1417.dT = TC_1323_1417.port_a.T - TC_1323_1417.port_b.T; TC_1323_1417.port_a.Q_flow = TC_1323_1417.Q_flow; TC_1323_1417.port_b.Q_flow = -TC_1323_1417.Q_flow; TC_1324_1325.Q_flow = TC_1324_1325.G * TC_1324_1325.dT; TC_1324_1325.dT = TC_1324_1325.port_a.T - TC_1324_1325.port_b.T; TC_1324_1325.port_a.Q_flow = TC_1324_1325.Q_flow; TC_1324_1325.port_b.Q_flow = -TC_1324_1325.Q_flow; TC_1324_1335.Q_flow = TC_1324_1335.G * TC_1324_1335.dT; TC_1324_1335.dT = TC_1324_1335.port_a.T - TC_1324_1335.port_b.T; TC_1324_1335.port_a.Q_flow = TC_1324_1335.Q_flow; TC_1324_1335.port_b.Q_flow = -TC_1324_1335.Q_flow; TC_1324_1418.Q_flow = TC_1324_1418.G * TC_1324_1418.dT; TC_1324_1418.dT = TC_1324_1418.port_a.T - TC_1324_1418.port_b.T; TC_1324_1418.port_a.Q_flow = TC_1324_1418.Q_flow; TC_1324_1418.port_b.Q_flow = -TC_1324_1418.Q_flow; TC_1325_1326.Q_flow = TC_1325_1326.G * TC_1325_1326.dT; TC_1325_1326.dT = TC_1325_1326.port_a.T - TC_1325_1326.port_b.T; TC_1325_1326.port_a.Q_flow = TC_1325_1326.Q_flow; TC_1325_1326.port_b.Q_flow = -TC_1325_1326.Q_flow; TC_1325_1336.Q_flow = TC_1325_1336.G * TC_1325_1336.dT; TC_1325_1336.dT = TC_1325_1336.port_a.T - TC_1325_1336.port_b.T; TC_1325_1336.port_a.Q_flow = TC_1325_1336.Q_flow; TC_1325_1336.port_b.Q_flow = -TC_1325_1336.Q_flow; TC_1325_1419.Q_flow = TC_1325_1419.G * TC_1325_1419.dT; TC_1325_1419.dT = TC_1325_1419.port_a.T - TC_1325_1419.port_b.T; TC_1325_1419.port_a.Q_flow = TC_1325_1419.Q_flow; TC_1325_1419.port_b.Q_flow = -TC_1325_1419.Q_flow; TC_1326_1327.Q_flow = TC_1326_1327.G * TC_1326_1327.dT; TC_1326_1327.dT = TC_1326_1327.port_a.T - TC_1326_1327.port_b.T; TC_1326_1327.port_a.Q_flow = TC_1326_1327.Q_flow; TC_1326_1327.port_b.Q_flow = -TC_1326_1327.Q_flow; TC_1326_1337.Q_flow = TC_1326_1337.G * TC_1326_1337.dT; TC_1326_1337.dT = TC_1326_1337.port_a.T - TC_1326_1337.port_b.T; TC_1326_1337.port_a.Q_flow = TC_1326_1337.Q_flow; TC_1326_1337.port_b.Q_flow = -TC_1326_1337.Q_flow; TC_1327_1328.Q_flow = TC_1327_1328.G * TC_1327_1328.dT; TC_1327_1328.dT = TC_1327_1328.port_a.T - TC_1327_1328.port_b.T; TC_1327_1328.port_a.Q_flow = TC_1327_1328.Q_flow; TC_1327_1328.port_b.Q_flow = -TC_1327_1328.Q_flow; TC_1327_1338.Q_flow = TC_1327_1338.G * TC_1327_1338.dT; TC_1327_1338.dT = TC_1327_1338.port_a.T - TC_1327_1338.port_b.T; TC_1327_1338.port_a.Q_flow = TC_1327_1338.Q_flow; TC_1327_1338.port_b.Q_flow = -TC_1327_1338.Q_flow; TC_1328_1329.Q_flow = TC_1328_1329.G * TC_1328_1329.dT; TC_1328_1329.dT = TC_1328_1329.port_a.T - TC_1328_1329.port_b.T; TC_1328_1329.port_a.Q_flow = TC_1328_1329.Q_flow; TC_1328_1329.port_b.Q_flow = -TC_1328_1329.Q_flow; TC_1328_1339.Q_flow = TC_1328_1339.G * TC_1328_1339.dT; TC_1328_1339.dT = TC_1328_1339.port_a.T - TC_1328_1339.port_b.T; TC_1328_1339.port_a.Q_flow = TC_1328_1339.Q_flow; TC_1328_1339.port_b.Q_flow = -TC_1328_1339.Q_flow; TC_1329_1330.Q_flow = TC_1329_1330.G * TC_1329_1330.dT; TC_1329_1330.dT = TC_1329_1330.port_a.T - TC_1329_1330.port_b.T; TC_1329_1330.port_a.Q_flow = TC_1329_1330.Q_flow; TC_1329_1330.port_b.Q_flow = -TC_1329_1330.Q_flow; TC_1329_1340.Q_flow = TC_1329_1340.G * TC_1329_1340.dT; TC_1329_1340.dT = TC_1329_1340.port_a.T - TC_1329_1340.port_b.T; TC_1329_1340.port_a.Q_flow = TC_1329_1340.Q_flow; TC_1329_1340.port_b.Q_flow = -TC_1329_1340.Q_flow; TC_1330_1331.Q_flow = TC_1330_1331.G * TC_1330_1331.dT; TC_1330_1331.dT = TC_1330_1331.port_a.T - TC_1330_1331.port_b.T; TC_1330_1331.port_a.Q_flow = TC_1330_1331.Q_flow; TC_1330_1331.port_b.Q_flow = -TC_1330_1331.Q_flow; TC_1330_1488.Q_flow = TC_1330_1488.G * TC_1330_1488.dT; TC_1330_1488.dT = TC_1330_1488.port_a.T - TC_1330_1488.port_b.T; TC_1330_1488.port_a.Q_flow = TC_1330_1488.Q_flow; TC_1330_1488.port_b.Q_flow = -TC_1330_1488.Q_flow; TC_1331_1332.Q_flow = TC_1331_1332.G * TC_1331_1332.dT; TC_1331_1332.dT = TC_1331_1332.port_a.T - TC_1331_1332.port_b.T; TC_1331_1332.port_a.Q_flow = TC_1331_1332.Q_flow; TC_1331_1332.port_b.Q_flow = -TC_1331_1332.Q_flow; TC_1331_1489.Q_flow = TC_1331_1489.G * TC_1331_1489.dT; TC_1331_1489.dT = TC_1331_1489.port_a.T - TC_1331_1489.port_b.T; TC_1331_1489.port_a.Q_flow = TC_1331_1489.Q_flow; TC_1331_1489.port_b.Q_flow = -TC_1331_1489.Q_flow; TC_1332_1333.Q_flow = TC_1332_1333.G * TC_1332_1333.dT; TC_1332_1333.dT = TC_1332_1333.port_a.T - TC_1332_1333.port_b.T; TC_1332_1333.port_a.Q_flow = TC_1332_1333.Q_flow; TC_1332_1333.port_b.Q_flow = -TC_1332_1333.Q_flow; TC_1332_1490.Q_flow = TC_1332_1490.G * TC_1332_1490.dT; TC_1332_1490.dT = TC_1332_1490.port_a.T - TC_1332_1490.port_b.T; TC_1332_1490.port_a.Q_flow = TC_1332_1490.Q_flow; TC_1332_1490.port_b.Q_flow = -TC_1332_1490.Q_flow; TC_1333_1334.Q_flow = TC_1333_1334.G * TC_1333_1334.dT; TC_1333_1334.dT = TC_1333_1334.port_a.T - TC_1333_1334.port_b.T; TC_1333_1334.port_a.Q_flow = TC_1333_1334.Q_flow; TC_1333_1334.port_b.Q_flow = -TC_1333_1334.Q_flow; TC_1333_1341.Q_flow = TC_1333_1341.G * TC_1333_1341.dT; TC_1333_1341.dT = TC_1333_1341.port_a.T - TC_1333_1341.port_b.T; TC_1333_1341.port_a.Q_flow = TC_1333_1341.Q_flow; TC_1333_1341.port_b.Q_flow = -TC_1333_1341.Q_flow; TC_1334_1342.Q_flow = TC_1334_1342.G * TC_1334_1342.dT; TC_1334_1342.dT = TC_1334_1342.port_a.T - TC_1334_1342.port_b.T; TC_1334_1342.port_a.Q_flow = TC_1334_1342.Q_flow; TC_1334_1342.port_b.Q_flow = -TC_1334_1342.Q_flow; TC_1334_1420.Q_flow = TC_1334_1420.G * TC_1334_1420.dT; TC_1334_1420.dT = TC_1334_1420.port_a.T - TC_1334_1420.port_b.T; TC_1334_1420.port_a.Q_flow = TC_1334_1420.Q_flow; TC_1334_1420.port_b.Q_flow = -TC_1334_1420.Q_flow; TC_1335_1336.Q_flow = TC_1335_1336.G * TC_1335_1336.dT; TC_1335_1336.dT = TC_1335_1336.port_a.T - TC_1335_1336.port_b.T; TC_1335_1336.port_a.Q_flow = TC_1335_1336.Q_flow; TC_1335_1336.port_b.Q_flow = -TC_1335_1336.Q_flow; TC_1335_1343.Q_flow = TC_1335_1343.G * TC_1335_1343.dT; TC_1335_1343.dT = TC_1335_1343.port_a.T - TC_1335_1343.port_b.T; TC_1335_1343.port_a.Q_flow = TC_1335_1343.Q_flow; TC_1335_1343.port_b.Q_flow = -TC_1335_1343.Q_flow; TC_1335_1421.Q_flow = TC_1335_1421.G * TC_1335_1421.dT; TC_1335_1421.dT = TC_1335_1421.port_a.T - TC_1335_1421.port_b.T; TC_1335_1421.port_a.Q_flow = TC_1335_1421.Q_flow; TC_1335_1421.port_b.Q_flow = -TC_1335_1421.Q_flow; TC_1336_1337.Q_flow = TC_1336_1337.G * TC_1336_1337.dT; TC_1336_1337.dT = TC_1336_1337.port_a.T - TC_1336_1337.port_b.T; TC_1336_1337.port_a.Q_flow = TC_1336_1337.Q_flow; TC_1336_1337.port_b.Q_flow = -TC_1336_1337.Q_flow; TC_1336_1344.Q_flow = TC_1336_1344.G * TC_1336_1344.dT; TC_1336_1344.dT = TC_1336_1344.port_a.T - TC_1336_1344.port_b.T; TC_1336_1344.port_a.Q_flow = TC_1336_1344.Q_flow; TC_1336_1344.port_b.Q_flow = -TC_1336_1344.Q_flow; TC_1336_1422.Q_flow = TC_1336_1422.G * TC_1336_1422.dT; TC_1336_1422.dT = TC_1336_1422.port_a.T - TC_1336_1422.port_b.T; TC_1336_1422.port_a.Q_flow = TC_1336_1422.Q_flow; TC_1336_1422.port_b.Q_flow = -TC_1336_1422.Q_flow; TC_1337_1338.Q_flow = TC_1337_1338.G * TC_1337_1338.dT; TC_1337_1338.dT = TC_1337_1338.port_a.T - TC_1337_1338.port_b.T; TC_1337_1338.port_a.Q_flow = TC_1337_1338.Q_flow; TC_1337_1338.port_b.Q_flow = -TC_1337_1338.Q_flow; TC_1337_1345.Q_flow = TC_1337_1345.G * TC_1337_1345.dT; TC_1337_1345.dT = TC_1337_1345.port_a.T - TC_1337_1345.port_b.T; TC_1337_1345.port_a.Q_flow = TC_1337_1345.Q_flow; TC_1337_1345.port_b.Q_flow = -TC_1337_1345.Q_flow; TC_1338_1339.Q_flow = TC_1338_1339.G * TC_1338_1339.dT; TC_1338_1339.dT = TC_1338_1339.port_a.T - TC_1338_1339.port_b.T; TC_1338_1339.port_a.Q_flow = TC_1338_1339.Q_flow; TC_1338_1339.port_b.Q_flow = -TC_1338_1339.Q_flow; TC_1338_1346.Q_flow = TC_1338_1346.G * TC_1338_1346.dT; TC_1338_1346.dT = TC_1338_1346.port_a.T - TC_1338_1346.port_b.T; TC_1338_1346.port_a.Q_flow = TC_1338_1346.Q_flow; TC_1338_1346.port_b.Q_flow = -TC_1338_1346.Q_flow; TC_1339_1340.Q_flow = TC_1339_1340.G * TC_1339_1340.dT; TC_1339_1340.dT = TC_1339_1340.port_a.T - TC_1339_1340.port_b.T; TC_1339_1340.port_a.Q_flow = TC_1339_1340.Q_flow; TC_1339_1340.port_b.Q_flow = -TC_1339_1340.Q_flow; TC_1339_1347.Q_flow = TC_1339_1347.G * TC_1339_1347.dT; TC_1339_1347.dT = TC_1339_1347.port_a.T - TC_1339_1347.port_b.T; TC_1339_1347.port_a.Q_flow = TC_1339_1347.Q_flow; TC_1339_1347.port_b.Q_flow = -TC_1339_1347.Q_flow; TC_1340_1348.Q_flow = TC_1340_1348.G * TC_1340_1348.dT; TC_1340_1348.dT = TC_1340_1348.port_a.T - TC_1340_1348.port_b.T; TC_1340_1348.port_a.Q_flow = TC_1340_1348.Q_flow; TC_1340_1348.port_b.Q_flow = -TC_1340_1348.Q_flow; TC_1340_1488.Q_flow = TC_1340_1488.G * TC_1340_1488.dT; TC_1340_1488.dT = TC_1340_1488.port_a.T - TC_1340_1488.port_b.T; TC_1340_1488.port_a.Q_flow = TC_1340_1488.Q_flow; TC_1340_1488.port_b.Q_flow = -TC_1340_1488.Q_flow; TC_1341_1342.Q_flow = TC_1341_1342.G * TC_1341_1342.dT; TC_1341_1342.dT = TC_1341_1342.port_a.T - TC_1341_1342.port_b.T; TC_1341_1342.port_a.Q_flow = TC_1341_1342.Q_flow; TC_1341_1342.port_b.Q_flow = -TC_1341_1342.Q_flow; TC_1341_1349.Q_flow = TC_1341_1349.G * TC_1341_1349.dT; TC_1341_1349.dT = TC_1341_1349.port_a.T - TC_1341_1349.port_b.T; TC_1341_1349.port_a.Q_flow = TC_1341_1349.Q_flow; TC_1341_1349.port_b.Q_flow = -TC_1341_1349.Q_flow; TC_1341_1490.Q_flow = TC_1341_1490.G * TC_1341_1490.dT; TC_1341_1490.dT = TC_1341_1490.port_a.T - TC_1341_1490.port_b.T; TC_1341_1490.port_a.Q_flow = TC_1341_1490.Q_flow; TC_1341_1490.port_b.Q_flow = -TC_1341_1490.Q_flow; TC_1342_1350.Q_flow = TC_1342_1350.G * TC_1342_1350.dT; TC_1342_1350.dT = TC_1342_1350.port_a.T - TC_1342_1350.port_b.T; TC_1342_1350.port_a.Q_flow = TC_1342_1350.Q_flow; TC_1342_1350.port_b.Q_flow = -TC_1342_1350.Q_flow; TC_1342_1423.Q_flow = TC_1342_1423.G * TC_1342_1423.dT; TC_1342_1423.dT = TC_1342_1423.port_a.T - TC_1342_1423.port_b.T; TC_1342_1423.port_a.Q_flow = TC_1342_1423.Q_flow; TC_1342_1423.port_b.Q_flow = -TC_1342_1423.Q_flow; TC_1343_1344.Q_flow = TC_1343_1344.G * TC_1343_1344.dT; TC_1343_1344.dT = TC_1343_1344.port_a.T - TC_1343_1344.port_b.T; TC_1343_1344.port_a.Q_flow = TC_1343_1344.Q_flow; TC_1343_1344.port_b.Q_flow = -TC_1343_1344.Q_flow; TC_1343_1351.Q_flow = TC_1343_1351.G * TC_1343_1351.dT; TC_1343_1351.dT = TC_1343_1351.port_a.T - TC_1343_1351.port_b.T; TC_1343_1351.port_a.Q_flow = TC_1343_1351.Q_flow; TC_1343_1351.port_b.Q_flow = -TC_1343_1351.Q_flow; TC_1343_1424.Q_flow = TC_1343_1424.G * TC_1343_1424.dT; TC_1343_1424.dT = TC_1343_1424.port_a.T - TC_1343_1424.port_b.T; TC_1343_1424.port_a.Q_flow = TC_1343_1424.Q_flow; TC_1343_1424.port_b.Q_flow = -TC_1343_1424.Q_flow; TC_1344_1345.Q_flow = TC_1344_1345.G * TC_1344_1345.dT; TC_1344_1345.dT = TC_1344_1345.port_a.T - TC_1344_1345.port_b.T; TC_1344_1345.port_a.Q_flow = TC_1344_1345.Q_flow; TC_1344_1345.port_b.Q_flow = -TC_1344_1345.Q_flow; TC_1344_1352.Q_flow = TC_1344_1352.G * TC_1344_1352.dT; TC_1344_1352.dT = TC_1344_1352.port_a.T - TC_1344_1352.port_b.T; TC_1344_1352.port_a.Q_flow = TC_1344_1352.Q_flow; TC_1344_1352.port_b.Q_flow = -TC_1344_1352.Q_flow; TC_1344_1425.Q_flow = TC_1344_1425.G * TC_1344_1425.dT; TC_1344_1425.dT = TC_1344_1425.port_a.T - TC_1344_1425.port_b.T; TC_1344_1425.port_a.Q_flow = TC_1344_1425.Q_flow; TC_1344_1425.port_b.Q_flow = -TC_1344_1425.Q_flow; TC_1345_1346.Q_flow = TC_1345_1346.G * TC_1345_1346.dT; TC_1345_1346.dT = TC_1345_1346.port_a.T - TC_1345_1346.port_b.T; TC_1345_1346.port_a.Q_flow = TC_1345_1346.Q_flow; TC_1345_1346.port_b.Q_flow = -TC_1345_1346.Q_flow; TC_1345_1353.Q_flow = TC_1345_1353.G * TC_1345_1353.dT; TC_1345_1353.dT = TC_1345_1353.port_a.T - TC_1345_1353.port_b.T; TC_1345_1353.port_a.Q_flow = TC_1345_1353.Q_flow; TC_1345_1353.port_b.Q_flow = -TC_1345_1353.Q_flow; TC_1346_1347.Q_flow = TC_1346_1347.G * TC_1346_1347.dT; TC_1346_1347.dT = TC_1346_1347.port_a.T - TC_1346_1347.port_b.T; TC_1346_1347.port_a.Q_flow = TC_1346_1347.Q_flow; TC_1346_1347.port_b.Q_flow = -TC_1346_1347.Q_flow; TC_1346_1354.Q_flow = TC_1346_1354.G * TC_1346_1354.dT; TC_1346_1354.dT = TC_1346_1354.port_a.T - TC_1346_1354.port_b.T; TC_1346_1354.port_a.Q_flow = TC_1346_1354.Q_flow; TC_1346_1354.port_b.Q_flow = -TC_1346_1354.Q_flow; TC_1347_1348.Q_flow = TC_1347_1348.G * TC_1347_1348.dT; TC_1347_1348.dT = TC_1347_1348.port_a.T - TC_1347_1348.port_b.T; TC_1347_1348.port_a.Q_flow = TC_1347_1348.Q_flow; TC_1347_1348.port_b.Q_flow = -TC_1347_1348.Q_flow; TC_1347_1355.Q_flow = TC_1347_1355.G * TC_1347_1355.dT; TC_1347_1355.dT = TC_1347_1355.port_a.T - TC_1347_1355.port_b.T; TC_1347_1355.port_a.Q_flow = TC_1347_1355.Q_flow; TC_1347_1355.port_b.Q_flow = -TC_1347_1355.Q_flow; TC_1348_1356.Q_flow = TC_1348_1356.G * TC_1348_1356.dT; TC_1348_1356.dT = TC_1348_1356.port_a.T - TC_1348_1356.port_b.T; TC_1348_1356.port_a.Q_flow = TC_1348_1356.Q_flow; TC_1348_1356.port_b.Q_flow = -TC_1348_1356.Q_flow; TC_1348_1491.Q_flow = TC_1348_1491.G * TC_1348_1491.dT; TC_1348_1491.dT = TC_1348_1491.port_a.T - TC_1348_1491.port_b.T; TC_1348_1491.port_a.Q_flow = TC_1348_1491.Q_flow; TC_1348_1491.port_b.Q_flow = -TC_1348_1491.Q_flow; TC_1349_1350.Q_flow = TC_1349_1350.G * TC_1349_1350.dT; TC_1349_1350.dT = TC_1349_1350.port_a.T - TC_1349_1350.port_b.T; TC_1349_1350.port_a.Q_flow = TC_1349_1350.Q_flow; TC_1349_1350.port_b.Q_flow = -TC_1349_1350.Q_flow; TC_1349_1357.Q_flow = TC_1349_1357.G * TC_1349_1357.dT; TC_1349_1357.dT = TC_1349_1357.port_a.T - TC_1349_1357.port_b.T; TC_1349_1357.port_a.Q_flow = TC_1349_1357.Q_flow; TC_1349_1357.port_b.Q_flow = -TC_1349_1357.Q_flow; TC_1349_1493.Q_flow = TC_1349_1493.G * TC_1349_1493.dT; TC_1349_1493.dT = TC_1349_1493.port_a.T - TC_1349_1493.port_b.T; TC_1349_1493.port_a.Q_flow = TC_1349_1493.Q_flow; TC_1349_1493.port_b.Q_flow = -TC_1349_1493.Q_flow; TC_1350_1358.Q_flow = TC_1350_1358.G * TC_1350_1358.dT; TC_1350_1358.dT = TC_1350_1358.port_a.T - TC_1350_1358.port_b.T; TC_1350_1358.port_a.Q_flow = TC_1350_1358.Q_flow; TC_1350_1358.port_b.Q_flow = -TC_1350_1358.Q_flow; TC_1350_1426.Q_flow = TC_1350_1426.G * TC_1350_1426.dT; TC_1350_1426.dT = TC_1350_1426.port_a.T - TC_1350_1426.port_b.T; TC_1350_1426.port_a.Q_flow = TC_1350_1426.Q_flow; TC_1350_1426.port_b.Q_flow = -TC_1350_1426.Q_flow; TC_1351_1352.Q_flow = TC_1351_1352.G * TC_1351_1352.dT; TC_1351_1352.dT = TC_1351_1352.port_a.T - TC_1351_1352.port_b.T; TC_1351_1352.port_a.Q_flow = TC_1351_1352.Q_flow; TC_1351_1352.port_b.Q_flow = -TC_1351_1352.Q_flow; TC_1351_1359.Q_flow = TC_1351_1359.G * TC_1351_1359.dT; TC_1351_1359.dT = TC_1351_1359.port_a.T - TC_1351_1359.port_b.T; TC_1351_1359.port_a.Q_flow = TC_1351_1359.Q_flow; TC_1351_1359.port_b.Q_flow = -TC_1351_1359.Q_flow; TC_1351_1427.Q_flow = TC_1351_1427.G * TC_1351_1427.dT; TC_1351_1427.dT = TC_1351_1427.port_a.T - TC_1351_1427.port_b.T; TC_1351_1427.port_a.Q_flow = TC_1351_1427.Q_flow; TC_1351_1427.port_b.Q_flow = -TC_1351_1427.Q_flow; TC_1352_1353.Q_flow = TC_1352_1353.G * TC_1352_1353.dT; TC_1352_1353.dT = TC_1352_1353.port_a.T - TC_1352_1353.port_b.T; TC_1352_1353.port_a.Q_flow = TC_1352_1353.Q_flow; TC_1352_1353.port_b.Q_flow = -TC_1352_1353.Q_flow; TC_1352_1360.Q_flow = TC_1352_1360.G * TC_1352_1360.dT; TC_1352_1360.dT = TC_1352_1360.port_a.T - TC_1352_1360.port_b.T; TC_1352_1360.port_a.Q_flow = TC_1352_1360.Q_flow; TC_1352_1360.port_b.Q_flow = -TC_1352_1360.Q_flow; TC_1352_1428.Q_flow = TC_1352_1428.G * TC_1352_1428.dT; TC_1352_1428.dT = TC_1352_1428.port_a.T - TC_1352_1428.port_b.T; TC_1352_1428.port_a.Q_flow = TC_1352_1428.Q_flow; TC_1352_1428.port_b.Q_flow = -TC_1352_1428.Q_flow; TC_1353_1354.Q_flow = TC_1353_1354.G * TC_1353_1354.dT; TC_1353_1354.dT = TC_1353_1354.port_a.T - TC_1353_1354.port_b.T; TC_1353_1354.port_a.Q_flow = TC_1353_1354.Q_flow; TC_1353_1354.port_b.Q_flow = -TC_1353_1354.Q_flow; TC_1353_1361.Q_flow = TC_1353_1361.G * TC_1353_1361.dT; TC_1353_1361.dT = TC_1353_1361.port_a.T - TC_1353_1361.port_b.T; TC_1353_1361.port_a.Q_flow = TC_1353_1361.Q_flow; TC_1353_1361.port_b.Q_flow = -TC_1353_1361.Q_flow; TC_1354_1355.Q_flow = TC_1354_1355.G * TC_1354_1355.dT; TC_1354_1355.dT = TC_1354_1355.port_a.T - TC_1354_1355.port_b.T; TC_1354_1355.port_a.Q_flow = TC_1354_1355.Q_flow; TC_1354_1355.port_b.Q_flow = -TC_1354_1355.Q_flow; TC_1354_1362.Q_flow = TC_1354_1362.G * TC_1354_1362.dT; TC_1354_1362.dT = TC_1354_1362.port_a.T - TC_1354_1362.port_b.T; TC_1354_1362.port_a.Q_flow = TC_1354_1362.Q_flow; TC_1354_1362.port_b.Q_flow = -TC_1354_1362.Q_flow; TC_1355_1356.Q_flow = TC_1355_1356.G * TC_1355_1356.dT; TC_1355_1356.dT = TC_1355_1356.port_a.T - TC_1355_1356.port_b.T; TC_1355_1356.port_a.Q_flow = TC_1355_1356.Q_flow; TC_1355_1356.port_b.Q_flow = -TC_1355_1356.Q_flow; TC_1355_1363.Q_flow = TC_1355_1363.G * TC_1355_1363.dT; TC_1355_1363.dT = TC_1355_1363.port_a.T - TC_1355_1363.port_b.T; TC_1355_1363.port_a.Q_flow = TC_1355_1363.Q_flow; TC_1355_1363.port_b.Q_flow = -TC_1355_1363.Q_flow; TC_1356_1364.Q_flow = TC_1356_1364.G * TC_1356_1364.dT; TC_1356_1364.dT = TC_1356_1364.port_a.T - TC_1356_1364.port_b.T; TC_1356_1364.port_a.Q_flow = TC_1356_1364.Q_flow; TC_1356_1364.port_b.Q_flow = -TC_1356_1364.Q_flow; TC_1356_1494.Q_flow = TC_1356_1494.G * TC_1356_1494.dT; TC_1356_1494.dT = TC_1356_1494.port_a.T - TC_1356_1494.port_b.T; TC_1356_1494.port_a.Q_flow = TC_1356_1494.Q_flow; TC_1356_1494.port_b.Q_flow = -TC_1356_1494.Q_flow; TC_1357_1358.Q_flow = TC_1357_1358.G * TC_1357_1358.dT; TC_1357_1358.dT = TC_1357_1358.port_a.T - TC_1357_1358.port_b.T; TC_1357_1358.port_a.Q_flow = TC_1357_1358.Q_flow; TC_1357_1358.port_b.Q_flow = -TC_1357_1358.Q_flow; TC_1357_1368.Q_flow = TC_1357_1368.G * TC_1357_1368.dT; TC_1357_1368.dT = TC_1357_1368.port_a.T - TC_1357_1368.port_b.T; TC_1357_1368.port_a.Q_flow = TC_1357_1368.Q_flow; TC_1357_1368.port_b.Q_flow = -TC_1357_1368.Q_flow; TC_1357_1496.Q_flow = TC_1357_1496.G * TC_1357_1496.dT; TC_1357_1496.dT = TC_1357_1496.port_a.T - TC_1357_1496.port_b.T; TC_1357_1496.port_a.Q_flow = TC_1357_1496.Q_flow; TC_1357_1496.port_b.Q_flow = -TC_1357_1496.Q_flow; TC_1358_1369.Q_flow = TC_1358_1369.G * TC_1358_1369.dT; TC_1358_1369.dT = TC_1358_1369.port_a.T - TC_1358_1369.port_b.T; TC_1358_1369.port_a.Q_flow = TC_1358_1369.Q_flow; TC_1358_1369.port_b.Q_flow = -TC_1358_1369.Q_flow; TC_1358_1429.Q_flow = TC_1358_1429.G * TC_1358_1429.dT; TC_1358_1429.dT = TC_1358_1429.port_a.T - TC_1358_1429.port_b.T; TC_1358_1429.port_a.Q_flow = TC_1358_1429.Q_flow; TC_1358_1429.port_b.Q_flow = -TC_1358_1429.Q_flow; TC_1359_1360.Q_flow = TC_1359_1360.G * TC_1359_1360.dT; TC_1359_1360.dT = TC_1359_1360.port_a.T - TC_1359_1360.port_b.T; TC_1359_1360.port_a.Q_flow = TC_1359_1360.Q_flow; TC_1359_1360.port_b.Q_flow = -TC_1359_1360.Q_flow; TC_1359_1370.Q_flow = TC_1359_1370.G * TC_1359_1370.dT; TC_1359_1370.dT = TC_1359_1370.port_a.T - TC_1359_1370.port_b.T; TC_1359_1370.port_a.Q_flow = TC_1359_1370.Q_flow; TC_1359_1370.port_b.Q_flow = -TC_1359_1370.Q_flow; TC_1359_1430.Q_flow = TC_1359_1430.G * TC_1359_1430.dT; TC_1359_1430.dT = TC_1359_1430.port_a.T - TC_1359_1430.port_b.T; TC_1359_1430.port_a.Q_flow = TC_1359_1430.Q_flow; TC_1359_1430.port_b.Q_flow = -TC_1359_1430.Q_flow; TC_1360_1361.Q_flow = TC_1360_1361.G * TC_1360_1361.dT; TC_1360_1361.dT = TC_1360_1361.port_a.T - TC_1360_1361.port_b.T; TC_1360_1361.port_a.Q_flow = TC_1360_1361.Q_flow; TC_1360_1361.port_b.Q_flow = -TC_1360_1361.Q_flow; TC_1360_1371.Q_flow = TC_1360_1371.G * TC_1360_1371.dT; TC_1360_1371.dT = TC_1360_1371.port_a.T - TC_1360_1371.port_b.T; TC_1360_1371.port_a.Q_flow = TC_1360_1371.Q_flow; TC_1360_1371.port_b.Q_flow = -TC_1360_1371.Q_flow; TC_1360_1431.Q_flow = TC_1360_1431.G * TC_1360_1431.dT; TC_1360_1431.dT = TC_1360_1431.port_a.T - TC_1360_1431.port_b.T; TC_1360_1431.port_a.Q_flow = TC_1360_1431.Q_flow; TC_1360_1431.port_b.Q_flow = -TC_1360_1431.Q_flow; TC_1361_1362.Q_flow = TC_1361_1362.G * TC_1361_1362.dT; TC_1361_1362.dT = TC_1361_1362.port_a.T - TC_1361_1362.port_b.T; TC_1361_1362.port_a.Q_flow = TC_1361_1362.Q_flow; TC_1361_1362.port_b.Q_flow = -TC_1361_1362.Q_flow; TC_1361_1372.Q_flow = TC_1361_1372.G * TC_1361_1372.dT; TC_1361_1372.dT = TC_1361_1372.port_a.T - TC_1361_1372.port_b.T; TC_1361_1372.port_a.Q_flow = TC_1361_1372.Q_flow; TC_1361_1372.port_b.Q_flow = -TC_1361_1372.Q_flow; TC_1361_1518.Q_flow = TC_1361_1518.G * TC_1361_1518.dT; TC_1361_1518.dT = TC_1361_1518.port_a.T - TC_1361_1518.port_b.T; TC_1361_1518.port_a.Q_flow = TC_1361_1518.Q_flow; TC_1361_1518.port_b.Q_flow = -TC_1361_1518.Q_flow; TC_1362_1363.Q_flow = TC_1362_1363.G * TC_1362_1363.dT; TC_1362_1363.dT = TC_1362_1363.port_a.T - TC_1362_1363.port_b.T; TC_1362_1363.port_a.Q_flow = TC_1362_1363.Q_flow; TC_1362_1363.port_b.Q_flow = -TC_1362_1363.Q_flow; TC_1362_1373.Q_flow = TC_1362_1373.G * TC_1362_1373.dT; TC_1362_1373.dT = TC_1362_1373.port_a.T - TC_1362_1373.port_b.T; TC_1362_1373.port_a.Q_flow = TC_1362_1373.Q_flow; TC_1362_1373.port_b.Q_flow = -TC_1362_1373.Q_flow; TC_1362_1519.Q_flow = TC_1362_1519.G * TC_1362_1519.dT; TC_1362_1519.dT = TC_1362_1519.port_a.T - TC_1362_1519.port_b.T; TC_1362_1519.port_a.Q_flow = TC_1362_1519.Q_flow; TC_1362_1519.port_b.Q_flow = -TC_1362_1519.Q_flow; TC_1363_1364.Q_flow = TC_1363_1364.G * TC_1363_1364.dT; TC_1363_1364.dT = TC_1363_1364.port_a.T - TC_1363_1364.port_b.T; TC_1363_1364.port_a.Q_flow = TC_1363_1364.Q_flow; TC_1363_1364.port_b.Q_flow = -TC_1363_1364.Q_flow; TC_1363_1374.Q_flow = TC_1363_1374.G * TC_1363_1374.dT; TC_1363_1374.dT = TC_1363_1374.port_a.T - TC_1363_1374.port_b.T; TC_1363_1374.port_a.Q_flow = TC_1363_1374.Q_flow; TC_1363_1374.port_b.Q_flow = -TC_1363_1374.Q_flow; TC_1363_1520.Q_flow = TC_1363_1520.G * TC_1363_1520.dT; TC_1363_1520.dT = TC_1363_1520.port_a.T - TC_1363_1520.port_b.T; TC_1363_1520.port_a.Q_flow = TC_1363_1520.Q_flow; TC_1363_1520.port_b.Q_flow = -TC_1363_1520.Q_flow; TC_1364_1365.Q_flow = TC_1364_1365.G * TC_1364_1365.dT; TC_1364_1365.dT = TC_1364_1365.port_a.T - TC_1364_1365.port_b.T; TC_1364_1365.port_a.Q_flow = TC_1364_1365.Q_flow; TC_1364_1365.port_b.Q_flow = -TC_1364_1365.Q_flow; TC_1364_1375.Q_flow = TC_1364_1375.G * TC_1364_1375.dT; TC_1364_1375.dT = TC_1364_1375.port_a.T - TC_1364_1375.port_b.T; TC_1364_1375.port_a.Q_flow = TC_1364_1375.Q_flow; TC_1364_1375.port_b.Q_flow = -TC_1364_1375.Q_flow; TC_1365_1366.Q_flow = TC_1365_1366.G * TC_1365_1366.dT; TC_1365_1366.dT = TC_1365_1366.port_a.T - TC_1365_1366.port_b.T; TC_1365_1366.port_a.Q_flow = TC_1365_1366.Q_flow; TC_1365_1366.port_b.Q_flow = -TC_1365_1366.Q_flow; TC_1365_1376.Q_flow = TC_1365_1376.G * TC_1365_1376.dT; TC_1365_1376.dT = TC_1365_1376.port_a.T - TC_1365_1376.port_b.T; TC_1365_1376.port_a.Q_flow = TC_1365_1376.Q_flow; TC_1365_1376.port_b.Q_flow = -TC_1365_1376.Q_flow; TC_1365_1494.Q_flow = TC_1365_1494.G * TC_1365_1494.dT; TC_1365_1494.dT = TC_1365_1494.port_a.T - TC_1365_1494.port_b.T; TC_1365_1494.port_a.Q_flow = TC_1365_1494.Q_flow; TC_1365_1494.port_b.Q_flow = -TC_1365_1494.Q_flow; TC_1366_1367.Q_flow = TC_1366_1367.G * TC_1366_1367.dT; TC_1366_1367.dT = TC_1366_1367.port_a.T - TC_1366_1367.port_b.T; TC_1366_1367.port_a.Q_flow = TC_1366_1367.Q_flow; TC_1366_1367.port_b.Q_flow = -TC_1366_1367.Q_flow; TC_1366_1377.Q_flow = TC_1366_1377.G * TC_1366_1377.dT; TC_1366_1377.dT = TC_1366_1377.port_a.T - TC_1366_1377.port_b.T; TC_1366_1377.port_a.Q_flow = TC_1366_1377.Q_flow; TC_1366_1377.port_b.Q_flow = -TC_1366_1377.Q_flow; TC_1366_1495.Q_flow = TC_1366_1495.G * TC_1366_1495.dT; TC_1366_1495.dT = TC_1366_1495.port_a.T - TC_1366_1495.port_b.T; TC_1366_1495.port_a.Q_flow = TC_1366_1495.Q_flow; TC_1366_1495.port_b.Q_flow = -TC_1366_1495.Q_flow; TC_1367_1368.Q_flow = TC_1367_1368.G * TC_1367_1368.dT; TC_1367_1368.dT = TC_1367_1368.port_a.T - TC_1367_1368.port_b.T; TC_1367_1368.port_a.Q_flow = TC_1367_1368.Q_flow; TC_1367_1368.port_b.Q_flow = -TC_1367_1368.Q_flow; TC_1367_1378.Q_flow = TC_1367_1378.G * TC_1367_1378.dT; TC_1367_1378.dT = TC_1367_1378.port_a.T - TC_1367_1378.port_b.T; TC_1367_1378.port_a.Q_flow = TC_1367_1378.Q_flow; TC_1367_1378.port_b.Q_flow = -TC_1367_1378.Q_flow; TC_1367_1496.Q_flow = TC_1367_1496.G * TC_1367_1496.dT; TC_1367_1496.dT = TC_1367_1496.port_a.T - TC_1367_1496.port_b.T; TC_1367_1496.port_a.Q_flow = TC_1367_1496.Q_flow; TC_1367_1496.port_b.Q_flow = -TC_1367_1496.Q_flow; TC_1368_1369.Q_flow = TC_1368_1369.G * TC_1368_1369.dT; TC_1368_1369.dT = TC_1368_1369.port_a.T - TC_1368_1369.port_b.T; TC_1368_1369.port_a.Q_flow = TC_1368_1369.Q_flow; TC_1368_1369.port_b.Q_flow = -TC_1368_1369.Q_flow; TC_1368_1379.Q_flow = TC_1368_1379.G * TC_1368_1379.dT; TC_1368_1379.dT = TC_1368_1379.port_a.T - TC_1368_1379.port_b.T; TC_1368_1379.port_a.Q_flow = TC_1368_1379.Q_flow; TC_1368_1379.port_b.Q_flow = -TC_1368_1379.Q_flow; TC_1369_1380.Q_flow = TC_1369_1380.G * TC_1369_1380.dT; TC_1369_1380.dT = TC_1369_1380.port_a.T - TC_1369_1380.port_b.T; TC_1369_1380.port_a.Q_flow = TC_1369_1380.Q_flow; TC_1369_1380.port_b.Q_flow = -TC_1369_1380.Q_flow; TC_1369_1432.Q_flow = TC_1369_1432.G * TC_1369_1432.dT; TC_1369_1432.dT = TC_1369_1432.port_a.T - TC_1369_1432.port_b.T; TC_1369_1432.port_a.Q_flow = TC_1369_1432.Q_flow; TC_1369_1432.port_b.Q_flow = -TC_1369_1432.Q_flow; TC_1370_1371.Q_flow = TC_1370_1371.G * TC_1370_1371.dT; TC_1370_1371.dT = TC_1370_1371.port_a.T - TC_1370_1371.port_b.T; TC_1370_1371.port_a.Q_flow = TC_1370_1371.Q_flow; TC_1370_1371.port_b.Q_flow = -TC_1370_1371.Q_flow; TC_1370_1381.Q_flow = TC_1370_1381.G * TC_1370_1381.dT; TC_1370_1381.dT = TC_1370_1381.port_a.T - TC_1370_1381.port_b.T; TC_1370_1381.port_a.Q_flow = TC_1370_1381.Q_flow; TC_1370_1381.port_b.Q_flow = -TC_1370_1381.Q_flow; TC_1370_1433.Q_flow = TC_1370_1433.G * TC_1370_1433.dT; TC_1370_1433.dT = TC_1370_1433.port_a.T - TC_1370_1433.port_b.T; TC_1370_1433.port_a.Q_flow = TC_1370_1433.Q_flow; TC_1370_1433.port_b.Q_flow = -TC_1370_1433.Q_flow; TC_1371_1372.Q_flow = TC_1371_1372.G * TC_1371_1372.dT; TC_1371_1372.dT = TC_1371_1372.port_a.T - TC_1371_1372.port_b.T; TC_1371_1372.port_a.Q_flow = TC_1371_1372.Q_flow; TC_1371_1372.port_b.Q_flow = -TC_1371_1372.Q_flow; TC_1371_1382.Q_flow = TC_1371_1382.G * TC_1371_1382.dT; TC_1371_1382.dT = TC_1371_1382.port_a.T - TC_1371_1382.port_b.T; TC_1371_1382.port_a.Q_flow = TC_1371_1382.Q_flow; TC_1371_1382.port_b.Q_flow = -TC_1371_1382.Q_flow; TC_1371_1434.Q_flow = TC_1371_1434.G * TC_1371_1434.dT; TC_1371_1434.dT = TC_1371_1434.port_a.T - TC_1371_1434.port_b.T; TC_1371_1434.port_a.Q_flow = TC_1371_1434.Q_flow; TC_1371_1434.port_b.Q_flow = -TC_1371_1434.Q_flow; TC_1372_1373.Q_flow = TC_1372_1373.G * TC_1372_1373.dT; TC_1372_1373.dT = TC_1372_1373.port_a.T - TC_1372_1373.port_b.T; TC_1372_1373.port_a.Q_flow = TC_1372_1373.Q_flow; TC_1372_1373.port_b.Q_flow = -TC_1372_1373.Q_flow; TC_1372_1383.Q_flow = TC_1372_1383.G * TC_1372_1383.dT; TC_1372_1383.dT = TC_1372_1383.port_a.T - TC_1372_1383.port_b.T; TC_1372_1383.port_a.Q_flow = TC_1372_1383.Q_flow; TC_1372_1383.port_b.Q_flow = -TC_1372_1383.Q_flow; TC_1372_1521.Q_flow = TC_1372_1521.G * TC_1372_1521.dT; TC_1372_1521.dT = TC_1372_1521.port_a.T - TC_1372_1521.port_b.T; TC_1372_1521.port_a.Q_flow = TC_1372_1521.Q_flow; TC_1372_1521.port_b.Q_flow = -TC_1372_1521.Q_flow; TC_1373_1374.Q_flow = TC_1373_1374.G * TC_1373_1374.dT; TC_1373_1374.dT = TC_1373_1374.port_a.T - TC_1373_1374.port_b.T; TC_1373_1374.port_a.Q_flow = TC_1373_1374.Q_flow; TC_1373_1374.port_b.Q_flow = -TC_1373_1374.Q_flow; TC_1373_1384.Q_flow = TC_1373_1384.G * TC_1373_1384.dT; TC_1373_1384.dT = TC_1373_1384.port_a.T - TC_1373_1384.port_b.T; TC_1373_1384.port_a.Q_flow = TC_1373_1384.Q_flow; TC_1373_1384.port_b.Q_flow = -TC_1373_1384.Q_flow; TC_1373_1522.Q_flow = TC_1373_1522.G * TC_1373_1522.dT; TC_1373_1522.dT = TC_1373_1522.port_a.T - TC_1373_1522.port_b.T; TC_1373_1522.port_a.Q_flow = TC_1373_1522.Q_flow; TC_1373_1522.port_b.Q_flow = -TC_1373_1522.Q_flow; TC_1374_1375.Q_flow = TC_1374_1375.G * TC_1374_1375.dT; TC_1374_1375.dT = TC_1374_1375.port_a.T - TC_1374_1375.port_b.T; TC_1374_1375.port_a.Q_flow = TC_1374_1375.Q_flow; TC_1374_1375.port_b.Q_flow = -TC_1374_1375.Q_flow; TC_1374_1385.Q_flow = TC_1374_1385.G * TC_1374_1385.dT; TC_1374_1385.dT = TC_1374_1385.port_a.T - TC_1374_1385.port_b.T; TC_1374_1385.port_a.Q_flow = TC_1374_1385.Q_flow; TC_1374_1385.port_b.Q_flow = -TC_1374_1385.Q_flow; TC_1374_1523.Q_flow = TC_1374_1523.G * TC_1374_1523.dT; TC_1374_1523.dT = TC_1374_1523.port_a.T - TC_1374_1523.port_b.T; TC_1374_1523.port_a.Q_flow = TC_1374_1523.Q_flow; TC_1374_1523.port_b.Q_flow = -TC_1374_1523.Q_flow; TC_1375_1376.Q_flow = TC_1375_1376.G * TC_1375_1376.dT; TC_1375_1376.dT = TC_1375_1376.port_a.T - TC_1375_1376.port_b.T; TC_1375_1376.port_a.Q_flow = TC_1375_1376.Q_flow; TC_1375_1376.port_b.Q_flow = -TC_1375_1376.Q_flow; TC_1375_1386.Q_flow = TC_1375_1386.G * TC_1375_1386.dT; TC_1375_1386.dT = TC_1375_1386.port_a.T - TC_1375_1386.port_b.T; TC_1375_1386.port_a.Q_flow = TC_1375_1386.Q_flow; TC_1375_1386.port_b.Q_flow = -TC_1375_1386.Q_flow; TC_1376_1377.Q_flow = TC_1376_1377.G * TC_1376_1377.dT; TC_1376_1377.dT = TC_1376_1377.port_a.T - TC_1376_1377.port_b.T; TC_1376_1377.port_a.Q_flow = TC_1376_1377.Q_flow; TC_1376_1377.port_b.Q_flow = -TC_1376_1377.Q_flow; TC_1376_1387.Q_flow = TC_1376_1387.G * TC_1376_1387.dT; TC_1376_1387.dT = TC_1376_1387.port_a.T - TC_1376_1387.port_b.T; TC_1376_1387.port_a.Q_flow = TC_1376_1387.Q_flow; TC_1376_1387.port_b.Q_flow = -TC_1376_1387.Q_flow; TC_1377_1378.Q_flow = TC_1377_1378.G * TC_1377_1378.dT; TC_1377_1378.dT = TC_1377_1378.port_a.T - TC_1377_1378.port_b.T; TC_1377_1378.port_a.Q_flow = TC_1377_1378.Q_flow; TC_1377_1378.port_b.Q_flow = -TC_1377_1378.Q_flow; TC_1377_1388.Q_flow = TC_1377_1388.G * TC_1377_1388.dT; TC_1377_1388.dT = TC_1377_1388.port_a.T - TC_1377_1388.port_b.T; TC_1377_1388.port_a.Q_flow = TC_1377_1388.Q_flow; TC_1377_1388.port_b.Q_flow = -TC_1377_1388.Q_flow; TC_1378_1379.Q_flow = TC_1378_1379.G * TC_1378_1379.dT; TC_1378_1379.dT = TC_1378_1379.port_a.T - TC_1378_1379.port_b.T; TC_1378_1379.port_a.Q_flow = TC_1378_1379.Q_flow; TC_1378_1379.port_b.Q_flow = -TC_1378_1379.Q_flow; TC_1378_1389.Q_flow = TC_1378_1389.G * TC_1378_1389.dT; TC_1378_1389.dT = TC_1378_1389.port_a.T - TC_1378_1389.port_b.T; TC_1378_1389.port_a.Q_flow = TC_1378_1389.Q_flow; TC_1378_1389.port_b.Q_flow = -TC_1378_1389.Q_flow; TC_1379_1380.Q_flow = TC_1379_1380.G * TC_1379_1380.dT; TC_1379_1380.dT = TC_1379_1380.port_a.T - TC_1379_1380.port_b.T; TC_1379_1380.port_a.Q_flow = TC_1379_1380.Q_flow; TC_1379_1380.port_b.Q_flow = -TC_1379_1380.Q_flow; TC_1379_1390.Q_flow = TC_1379_1390.G * TC_1379_1390.dT; TC_1379_1390.dT = TC_1379_1390.port_a.T - TC_1379_1390.port_b.T; TC_1379_1390.port_a.Q_flow = TC_1379_1390.Q_flow; TC_1379_1390.port_b.Q_flow = -TC_1379_1390.Q_flow; TC_1380_1391.Q_flow = TC_1380_1391.G * TC_1380_1391.dT; TC_1380_1391.dT = TC_1380_1391.port_a.T - TC_1380_1391.port_b.T; TC_1380_1391.port_a.Q_flow = TC_1380_1391.Q_flow; TC_1380_1391.port_b.Q_flow = -TC_1380_1391.Q_flow; TC_1380_1435.Q_flow = TC_1380_1435.G * TC_1380_1435.dT; TC_1380_1435.dT = TC_1380_1435.port_a.T - TC_1380_1435.port_b.T; TC_1380_1435.port_a.Q_flow = TC_1380_1435.Q_flow; TC_1380_1435.port_b.Q_flow = -TC_1380_1435.Q_flow; TC_1381_1382.Q_flow = TC_1381_1382.G * TC_1381_1382.dT; TC_1381_1382.dT = TC_1381_1382.port_a.T - TC_1381_1382.port_b.T; TC_1381_1382.port_a.Q_flow = TC_1381_1382.Q_flow; TC_1381_1382.port_b.Q_flow = -TC_1381_1382.Q_flow; TC_1381_1392.Q_flow = TC_1381_1392.G * TC_1381_1392.dT; TC_1381_1392.dT = TC_1381_1392.port_a.T - TC_1381_1392.port_b.T; TC_1381_1392.port_a.Q_flow = TC_1381_1392.Q_flow; TC_1381_1392.port_b.Q_flow = -TC_1381_1392.Q_flow; TC_1381_1436.Q_flow = TC_1381_1436.G * TC_1381_1436.dT; TC_1381_1436.dT = TC_1381_1436.port_a.T - TC_1381_1436.port_b.T; TC_1381_1436.port_a.Q_flow = TC_1381_1436.Q_flow; TC_1381_1436.port_b.Q_flow = -TC_1381_1436.Q_flow; TC_1382_1383.Q_flow = TC_1382_1383.G * TC_1382_1383.dT; TC_1382_1383.dT = TC_1382_1383.port_a.T - TC_1382_1383.port_b.T; TC_1382_1383.port_a.Q_flow = TC_1382_1383.Q_flow; TC_1382_1383.port_b.Q_flow = -TC_1382_1383.Q_flow; TC_1382_1393.Q_flow = TC_1382_1393.G * TC_1382_1393.dT; TC_1382_1393.dT = TC_1382_1393.port_a.T - TC_1382_1393.port_b.T; TC_1382_1393.port_a.Q_flow = TC_1382_1393.Q_flow; TC_1382_1393.port_b.Q_flow = -TC_1382_1393.Q_flow; TC_1382_1437.Q_flow = TC_1382_1437.G * TC_1382_1437.dT; TC_1382_1437.dT = TC_1382_1437.port_a.T - TC_1382_1437.port_b.T; TC_1382_1437.port_a.Q_flow = TC_1382_1437.Q_flow; TC_1382_1437.port_b.Q_flow = -TC_1382_1437.Q_flow; TC_1383_1384.Q_flow = TC_1383_1384.G * TC_1383_1384.dT; TC_1383_1384.dT = TC_1383_1384.port_a.T - TC_1383_1384.port_b.T; TC_1383_1384.port_a.Q_flow = TC_1383_1384.Q_flow; TC_1383_1384.port_b.Q_flow = -TC_1383_1384.Q_flow; TC_1383_1394.Q_flow = TC_1383_1394.G * TC_1383_1394.dT; TC_1383_1394.dT = TC_1383_1394.port_a.T - TC_1383_1394.port_b.T; TC_1383_1394.port_a.Q_flow = TC_1383_1394.Q_flow; TC_1383_1394.port_b.Q_flow = -TC_1383_1394.Q_flow; TC_1383_1524.Q_flow = TC_1383_1524.G * TC_1383_1524.dT; TC_1383_1524.dT = TC_1383_1524.port_a.T - TC_1383_1524.port_b.T; TC_1383_1524.port_a.Q_flow = TC_1383_1524.Q_flow; TC_1383_1524.port_b.Q_flow = -TC_1383_1524.Q_flow; TC_1384_1385.Q_flow = TC_1384_1385.G * TC_1384_1385.dT; TC_1384_1385.dT = TC_1384_1385.port_a.T - TC_1384_1385.port_b.T; TC_1384_1385.port_a.Q_flow = TC_1384_1385.Q_flow; TC_1384_1385.port_b.Q_flow = -TC_1384_1385.Q_flow; TC_1384_1395.Q_flow = TC_1384_1395.G * TC_1384_1395.dT; TC_1384_1395.dT = TC_1384_1395.port_a.T - TC_1384_1395.port_b.T; TC_1384_1395.port_a.Q_flow = TC_1384_1395.Q_flow; TC_1384_1395.port_b.Q_flow = -TC_1384_1395.Q_flow; TC_1384_1525.Q_flow = TC_1384_1525.G * TC_1384_1525.dT; TC_1384_1525.dT = TC_1384_1525.port_a.T - TC_1384_1525.port_b.T; TC_1384_1525.port_a.Q_flow = TC_1384_1525.Q_flow; TC_1384_1525.port_b.Q_flow = -TC_1384_1525.Q_flow; TC_1385_1386.Q_flow = TC_1385_1386.G * TC_1385_1386.dT; TC_1385_1386.dT = TC_1385_1386.port_a.T - TC_1385_1386.port_b.T; TC_1385_1386.port_a.Q_flow = TC_1385_1386.Q_flow; TC_1385_1386.port_b.Q_flow = -TC_1385_1386.Q_flow; TC_1385_1396.Q_flow = TC_1385_1396.G * TC_1385_1396.dT; TC_1385_1396.dT = TC_1385_1396.port_a.T - TC_1385_1396.port_b.T; TC_1385_1396.port_a.Q_flow = TC_1385_1396.Q_flow; TC_1385_1396.port_b.Q_flow = -TC_1385_1396.Q_flow; TC_1385_1526.Q_flow = TC_1385_1526.G * TC_1385_1526.dT; TC_1385_1526.dT = TC_1385_1526.port_a.T - TC_1385_1526.port_b.T; TC_1385_1526.port_a.Q_flow = TC_1385_1526.Q_flow; TC_1385_1526.port_b.Q_flow = -TC_1385_1526.Q_flow; TC_1386_1387.Q_flow = TC_1386_1387.G * TC_1386_1387.dT; TC_1386_1387.dT = TC_1386_1387.port_a.T - TC_1386_1387.port_b.T; TC_1386_1387.port_a.Q_flow = TC_1386_1387.Q_flow; TC_1386_1387.port_b.Q_flow = -TC_1386_1387.Q_flow; TC_1386_1397.Q_flow = TC_1386_1397.G * TC_1386_1397.dT; TC_1386_1397.dT = TC_1386_1397.port_a.T - TC_1386_1397.port_b.T; TC_1386_1397.port_a.Q_flow = TC_1386_1397.Q_flow; TC_1386_1397.port_b.Q_flow = -TC_1386_1397.Q_flow; TC_1387_1388.Q_flow = TC_1387_1388.G * TC_1387_1388.dT; TC_1387_1388.dT = TC_1387_1388.port_a.T - TC_1387_1388.port_b.T; TC_1387_1388.port_a.Q_flow = TC_1387_1388.Q_flow; TC_1387_1388.port_b.Q_flow = -TC_1387_1388.Q_flow; TC_1387_1398.Q_flow = TC_1387_1398.G * TC_1387_1398.dT; TC_1387_1398.dT = TC_1387_1398.port_a.T - TC_1387_1398.port_b.T; TC_1387_1398.port_a.Q_flow = TC_1387_1398.Q_flow; TC_1387_1398.port_b.Q_flow = -TC_1387_1398.Q_flow; TC_1388_1389.Q_flow = TC_1388_1389.G * TC_1388_1389.dT; TC_1388_1389.dT = TC_1388_1389.port_a.T - TC_1388_1389.port_b.T; TC_1388_1389.port_a.Q_flow = TC_1388_1389.Q_flow; TC_1388_1389.port_b.Q_flow = -TC_1388_1389.Q_flow; TC_1388_1399.Q_flow = TC_1388_1399.G * TC_1388_1399.dT; TC_1388_1399.dT = TC_1388_1399.port_a.T - TC_1388_1399.port_b.T; TC_1388_1399.port_a.Q_flow = TC_1388_1399.Q_flow; TC_1388_1399.port_b.Q_flow = -TC_1388_1399.Q_flow; TC_1389_1390.Q_flow = TC_1389_1390.G * TC_1389_1390.dT; TC_1389_1390.dT = TC_1389_1390.port_a.T - TC_1389_1390.port_b.T; TC_1389_1390.port_a.Q_flow = TC_1389_1390.Q_flow; TC_1389_1390.port_b.Q_flow = -TC_1389_1390.Q_flow; TC_1389_1400.Q_flow = TC_1389_1400.G * TC_1389_1400.dT; TC_1389_1400.dT = TC_1389_1400.port_a.T - TC_1389_1400.port_b.T; TC_1389_1400.port_a.Q_flow = TC_1389_1400.Q_flow; TC_1389_1400.port_b.Q_flow = -TC_1389_1400.Q_flow; TC_1390_1391.Q_flow = TC_1390_1391.G * TC_1390_1391.dT; TC_1390_1391.dT = TC_1390_1391.port_a.T - TC_1390_1391.port_b.T; TC_1390_1391.port_a.Q_flow = TC_1390_1391.Q_flow; TC_1390_1391.port_b.Q_flow = -TC_1390_1391.Q_flow; TC_1390_1401.Q_flow = TC_1390_1401.G * TC_1390_1401.dT; TC_1390_1401.dT = TC_1390_1401.port_a.T - TC_1390_1401.port_b.T; TC_1390_1401.port_a.Q_flow = TC_1390_1401.Q_flow; TC_1390_1401.port_b.Q_flow = -TC_1390_1401.Q_flow; TC_1391_1402.Q_flow = TC_1391_1402.G * TC_1391_1402.dT; TC_1391_1402.dT = TC_1391_1402.port_a.T - TC_1391_1402.port_b.T; TC_1391_1402.port_a.Q_flow = TC_1391_1402.Q_flow; TC_1391_1402.port_b.Q_flow = -TC_1391_1402.Q_flow; TC_1391_1438.Q_flow = TC_1391_1438.G * TC_1391_1438.dT; TC_1391_1438.dT = TC_1391_1438.port_a.T - TC_1391_1438.port_b.T; TC_1391_1438.port_a.Q_flow = TC_1391_1438.Q_flow; TC_1391_1438.port_b.Q_flow = -TC_1391_1438.Q_flow; TC_1392_1393.Q_flow = TC_1392_1393.G * TC_1392_1393.dT; TC_1392_1393.dT = TC_1392_1393.port_a.T - TC_1392_1393.port_b.T; TC_1392_1393.port_a.Q_flow = TC_1392_1393.Q_flow; TC_1392_1393.port_b.Q_flow = -TC_1392_1393.Q_flow; TC_1392_1403.Q_flow = TC_1392_1403.G * TC_1392_1403.dT; TC_1392_1403.dT = TC_1392_1403.port_a.T - TC_1392_1403.port_b.T; TC_1392_1403.port_a.Q_flow = TC_1392_1403.Q_flow; TC_1392_1403.port_b.Q_flow = -TC_1392_1403.Q_flow; TC_1392_1439.Q_flow = TC_1392_1439.G * TC_1392_1439.dT; TC_1392_1439.dT = TC_1392_1439.port_a.T - TC_1392_1439.port_b.T; TC_1392_1439.port_a.Q_flow = TC_1392_1439.Q_flow; TC_1392_1439.port_b.Q_flow = -TC_1392_1439.Q_flow; TC_1393_1394.Q_flow = TC_1393_1394.G * TC_1393_1394.dT; TC_1393_1394.dT = TC_1393_1394.port_a.T - TC_1393_1394.port_b.T; TC_1393_1394.port_a.Q_flow = TC_1393_1394.Q_flow; TC_1393_1394.port_b.Q_flow = -TC_1393_1394.Q_flow; TC_1393_1404.Q_flow = TC_1393_1404.G * TC_1393_1404.dT; TC_1393_1404.dT = TC_1393_1404.port_a.T - TC_1393_1404.port_b.T; TC_1393_1404.port_a.Q_flow = TC_1393_1404.Q_flow; TC_1393_1404.port_b.Q_flow = -TC_1393_1404.Q_flow; TC_1393_1440.Q_flow = TC_1393_1440.G * TC_1393_1440.dT; TC_1393_1440.dT = TC_1393_1440.port_a.T - TC_1393_1440.port_b.T; TC_1393_1440.port_a.Q_flow = TC_1393_1440.Q_flow; TC_1393_1440.port_b.Q_flow = -TC_1393_1440.Q_flow; TC_1394_1395.Q_flow = TC_1394_1395.G * TC_1394_1395.dT; TC_1394_1395.dT = TC_1394_1395.port_a.T - TC_1394_1395.port_b.T; TC_1394_1395.port_a.Q_flow = TC_1394_1395.Q_flow; TC_1394_1395.port_b.Q_flow = -TC_1394_1395.Q_flow; TC_1394_1405.Q_flow = TC_1394_1405.G * TC_1394_1405.dT; TC_1394_1405.dT = TC_1394_1405.port_a.T - TC_1394_1405.port_b.T; TC_1394_1405.port_a.Q_flow = TC_1394_1405.Q_flow; TC_1394_1405.port_b.Q_flow = -TC_1394_1405.Q_flow; TC_1394_1441.Q_flow = TC_1394_1441.G * TC_1394_1441.dT; TC_1394_1441.dT = TC_1394_1441.port_a.T - TC_1394_1441.port_b.T; TC_1394_1441.port_a.Q_flow = TC_1394_1441.Q_flow; TC_1394_1441.port_b.Q_flow = -TC_1394_1441.Q_flow; TC_1395_1396.Q_flow = TC_1395_1396.G * TC_1395_1396.dT; TC_1395_1396.dT = TC_1395_1396.port_a.T - TC_1395_1396.port_b.T; TC_1395_1396.port_a.Q_flow = TC_1395_1396.Q_flow; TC_1395_1396.port_b.Q_flow = -TC_1395_1396.Q_flow; TC_1395_1406.Q_flow = TC_1395_1406.G * TC_1395_1406.dT; TC_1395_1406.dT = TC_1395_1406.port_a.T - TC_1395_1406.port_b.T; TC_1395_1406.port_a.Q_flow = TC_1395_1406.Q_flow; TC_1395_1406.port_b.Q_flow = -TC_1395_1406.Q_flow; TC_1395_1442.Q_flow = TC_1395_1442.G * TC_1395_1442.dT; TC_1395_1442.dT = TC_1395_1442.port_a.T - TC_1395_1442.port_b.T; TC_1395_1442.port_a.Q_flow = TC_1395_1442.Q_flow; TC_1395_1442.port_b.Q_flow = -TC_1395_1442.Q_flow; TC_1396_1397.Q_flow = TC_1396_1397.G * TC_1396_1397.dT; TC_1396_1397.dT = TC_1396_1397.port_a.T - TC_1396_1397.port_b.T; TC_1396_1397.port_a.Q_flow = TC_1396_1397.Q_flow; TC_1396_1397.port_b.Q_flow = -TC_1396_1397.Q_flow; TC_1396_1407.Q_flow = TC_1396_1407.G * TC_1396_1407.dT; TC_1396_1407.dT = TC_1396_1407.port_a.T - TC_1396_1407.port_b.T; TC_1396_1407.port_a.Q_flow = TC_1396_1407.Q_flow; TC_1396_1407.port_b.Q_flow = -TC_1396_1407.Q_flow; TC_1396_1443.Q_flow = TC_1396_1443.G * TC_1396_1443.dT; TC_1396_1443.dT = TC_1396_1443.port_a.T - TC_1396_1443.port_b.T; TC_1396_1443.port_a.Q_flow = TC_1396_1443.Q_flow; TC_1396_1443.port_b.Q_flow = -TC_1396_1443.Q_flow; TC_1397_1398.Q_flow = TC_1397_1398.G * TC_1397_1398.dT; TC_1397_1398.dT = TC_1397_1398.port_a.T - TC_1397_1398.port_b.T; TC_1397_1398.port_a.Q_flow = TC_1397_1398.Q_flow; TC_1397_1398.port_b.Q_flow = -TC_1397_1398.Q_flow; TC_1397_1408.Q_flow = TC_1397_1408.G * TC_1397_1408.dT; TC_1397_1408.dT = TC_1397_1408.port_a.T - TC_1397_1408.port_b.T; TC_1397_1408.port_a.Q_flow = TC_1397_1408.Q_flow; TC_1397_1408.port_b.Q_flow = -TC_1397_1408.Q_flow; TC_1397_1444.Q_flow = TC_1397_1444.G * TC_1397_1444.dT; TC_1397_1444.dT = TC_1397_1444.port_a.T - TC_1397_1444.port_b.T; TC_1397_1444.port_a.Q_flow = TC_1397_1444.Q_flow; TC_1397_1444.port_b.Q_flow = -TC_1397_1444.Q_flow; TC_1398_1399.Q_flow = TC_1398_1399.G * TC_1398_1399.dT; TC_1398_1399.dT = TC_1398_1399.port_a.T - TC_1398_1399.port_b.T; TC_1398_1399.port_a.Q_flow = TC_1398_1399.Q_flow; TC_1398_1399.port_b.Q_flow = -TC_1398_1399.Q_flow; TC_1398_1409.Q_flow = TC_1398_1409.G * TC_1398_1409.dT; TC_1398_1409.dT = TC_1398_1409.port_a.T - TC_1398_1409.port_b.T; TC_1398_1409.port_a.Q_flow = TC_1398_1409.Q_flow; TC_1398_1409.port_b.Q_flow = -TC_1398_1409.Q_flow; TC_1398_1445.Q_flow = TC_1398_1445.G * TC_1398_1445.dT; TC_1398_1445.dT = TC_1398_1445.port_a.T - TC_1398_1445.port_b.T; TC_1398_1445.port_a.Q_flow = TC_1398_1445.Q_flow; TC_1398_1445.port_b.Q_flow = -TC_1398_1445.Q_flow; TC_1399_1400.Q_flow = TC_1399_1400.G * TC_1399_1400.dT; TC_1399_1400.dT = TC_1399_1400.port_a.T - TC_1399_1400.port_b.T; TC_1399_1400.port_a.Q_flow = TC_1399_1400.Q_flow; TC_1399_1400.port_b.Q_flow = -TC_1399_1400.Q_flow; TC_1399_1410.Q_flow = TC_1399_1410.G * TC_1399_1410.dT; TC_1399_1410.dT = TC_1399_1410.port_a.T - TC_1399_1410.port_b.T; TC_1399_1410.port_a.Q_flow = TC_1399_1410.Q_flow; TC_1399_1410.port_b.Q_flow = -TC_1399_1410.Q_flow; TC_1399_1446.Q_flow = TC_1399_1446.G * TC_1399_1446.dT; TC_1399_1446.dT = TC_1399_1446.port_a.T - TC_1399_1446.port_b.T; TC_1399_1446.port_a.Q_flow = TC_1399_1446.Q_flow; TC_1399_1446.port_b.Q_flow = -TC_1399_1446.Q_flow; TC_1400_1401.Q_flow = TC_1400_1401.G * TC_1400_1401.dT; TC_1400_1401.dT = TC_1400_1401.port_a.T - TC_1400_1401.port_b.T; TC_1400_1401.port_a.Q_flow = TC_1400_1401.Q_flow; TC_1400_1401.port_b.Q_flow = -TC_1400_1401.Q_flow; TC_1400_1411.Q_flow = TC_1400_1411.G * TC_1400_1411.dT; TC_1400_1411.dT = TC_1400_1411.port_a.T - TC_1400_1411.port_b.T; TC_1400_1411.port_a.Q_flow = TC_1400_1411.Q_flow; TC_1400_1411.port_b.Q_flow = -TC_1400_1411.Q_flow; TC_1400_1447.Q_flow = TC_1400_1447.G * TC_1400_1447.dT; TC_1400_1447.dT = TC_1400_1447.port_a.T - TC_1400_1447.port_b.T; TC_1400_1447.port_a.Q_flow = TC_1400_1447.Q_flow; TC_1400_1447.port_b.Q_flow = -TC_1400_1447.Q_flow; TC_1401_1402.Q_flow = TC_1401_1402.G * TC_1401_1402.dT; TC_1401_1402.dT = TC_1401_1402.port_a.T - TC_1401_1402.port_b.T; TC_1401_1402.port_a.Q_flow = TC_1401_1402.Q_flow; TC_1401_1402.port_b.Q_flow = -TC_1401_1402.Q_flow; TC_1401_1412.Q_flow = TC_1401_1412.G * TC_1401_1412.dT; TC_1401_1412.dT = TC_1401_1412.port_a.T - TC_1401_1412.port_b.T; TC_1401_1412.port_a.Q_flow = TC_1401_1412.Q_flow; TC_1401_1412.port_b.Q_flow = -TC_1401_1412.Q_flow; TC_1401_1448.Q_flow = TC_1401_1448.G * TC_1401_1448.dT; TC_1401_1448.dT = TC_1401_1448.port_a.T - TC_1401_1448.port_b.T; TC_1401_1448.port_a.Q_flow = TC_1401_1448.Q_flow; TC_1401_1448.port_b.Q_flow = -TC_1401_1448.Q_flow; TC_1402_1413.Q_flow = TC_1402_1413.G * TC_1402_1413.dT; TC_1402_1413.dT = TC_1402_1413.port_a.T - TC_1402_1413.port_b.T; TC_1402_1413.port_a.Q_flow = TC_1402_1413.Q_flow; TC_1402_1413.port_b.Q_flow = -TC_1402_1413.Q_flow; TC_1402_1449.Q_flow = TC_1402_1449.G * TC_1402_1449.dT; TC_1402_1449.dT = TC_1402_1449.port_a.T - TC_1402_1449.port_b.T; TC_1402_1449.port_a.Q_flow = TC_1402_1449.Q_flow; TC_1402_1449.port_b.Q_flow = -TC_1402_1449.Q_flow; TC_1403_1404.Q_flow = TC_1403_1404.G * TC_1403_1404.dT; TC_1403_1404.dT = TC_1403_1404.port_a.T - TC_1403_1404.port_b.T; TC_1403_1404.port_a.Q_flow = TC_1403_1404.Q_flow; TC_1403_1404.port_b.Q_flow = -TC_1403_1404.Q_flow; TC_1403_1450.Q_flow = TC_1403_1450.G * TC_1403_1450.dT; TC_1403_1450.dT = TC_1403_1450.port_a.T - TC_1403_1450.port_b.T; TC_1403_1450.port_a.Q_flow = TC_1403_1450.Q_flow; TC_1403_1450.port_b.Q_flow = -TC_1403_1450.Q_flow; TC_1404_1405.Q_flow = TC_1404_1405.G * TC_1404_1405.dT; TC_1404_1405.dT = TC_1404_1405.port_a.T - TC_1404_1405.port_b.T; TC_1404_1405.port_a.Q_flow = TC_1404_1405.Q_flow; TC_1404_1405.port_b.Q_flow = -TC_1404_1405.Q_flow; TC_1404_1451.Q_flow = TC_1404_1451.G * TC_1404_1451.dT; TC_1404_1451.dT = TC_1404_1451.port_a.T - TC_1404_1451.port_b.T; TC_1404_1451.port_a.Q_flow = TC_1404_1451.Q_flow; TC_1404_1451.port_b.Q_flow = -TC_1404_1451.Q_flow; TC_1405_1406.Q_flow = TC_1405_1406.G * TC_1405_1406.dT; TC_1405_1406.dT = TC_1405_1406.port_a.T - TC_1405_1406.port_b.T; TC_1405_1406.port_a.Q_flow = TC_1405_1406.Q_flow; TC_1405_1406.port_b.Q_flow = -TC_1405_1406.Q_flow; TC_1405_1452.Q_flow = TC_1405_1452.G * TC_1405_1452.dT; TC_1405_1452.dT = TC_1405_1452.port_a.T - TC_1405_1452.port_b.T; TC_1405_1452.port_a.Q_flow = TC_1405_1452.Q_flow; TC_1405_1452.port_b.Q_flow = -TC_1405_1452.Q_flow; TC_1406_1407.Q_flow = TC_1406_1407.G * TC_1406_1407.dT; TC_1406_1407.dT = TC_1406_1407.port_a.T - TC_1406_1407.port_b.T; TC_1406_1407.port_a.Q_flow = TC_1406_1407.Q_flow; TC_1406_1407.port_b.Q_flow = -TC_1406_1407.Q_flow; TC_1406_1453.Q_flow = TC_1406_1453.G * TC_1406_1453.dT; TC_1406_1453.dT = TC_1406_1453.port_a.T - TC_1406_1453.port_b.T; TC_1406_1453.port_a.Q_flow = TC_1406_1453.Q_flow; TC_1406_1453.port_b.Q_flow = -TC_1406_1453.Q_flow; TC_1407_1408.Q_flow = TC_1407_1408.G * TC_1407_1408.dT; TC_1407_1408.dT = TC_1407_1408.port_a.T - TC_1407_1408.port_b.T; TC_1407_1408.port_a.Q_flow = TC_1407_1408.Q_flow; TC_1407_1408.port_b.Q_flow = -TC_1407_1408.Q_flow; TC_1407_1454.Q_flow = TC_1407_1454.G * TC_1407_1454.dT; TC_1407_1454.dT = TC_1407_1454.port_a.T - TC_1407_1454.port_b.T; TC_1407_1454.port_a.Q_flow = TC_1407_1454.Q_flow; TC_1407_1454.port_b.Q_flow = -TC_1407_1454.Q_flow; TC_1408_1409.Q_flow = TC_1408_1409.G * TC_1408_1409.dT; TC_1408_1409.dT = TC_1408_1409.port_a.T - TC_1408_1409.port_b.T; TC_1408_1409.port_a.Q_flow = TC_1408_1409.Q_flow; TC_1408_1409.port_b.Q_flow = -TC_1408_1409.Q_flow; TC_1408_1455.Q_flow = TC_1408_1455.G * TC_1408_1455.dT; TC_1408_1455.dT = TC_1408_1455.port_a.T - TC_1408_1455.port_b.T; TC_1408_1455.port_a.Q_flow = TC_1408_1455.Q_flow; TC_1408_1455.port_b.Q_flow = -TC_1408_1455.Q_flow; TC_1409_1410.Q_flow = TC_1409_1410.G * TC_1409_1410.dT; TC_1409_1410.dT = TC_1409_1410.port_a.T - TC_1409_1410.port_b.T; TC_1409_1410.port_a.Q_flow = TC_1409_1410.Q_flow; TC_1409_1410.port_b.Q_flow = -TC_1409_1410.Q_flow; TC_1409_1456.Q_flow = TC_1409_1456.G * TC_1409_1456.dT; TC_1409_1456.dT = TC_1409_1456.port_a.T - TC_1409_1456.port_b.T; TC_1409_1456.port_a.Q_flow = TC_1409_1456.Q_flow; TC_1409_1456.port_b.Q_flow = -TC_1409_1456.Q_flow; TC_1410_1411.Q_flow = TC_1410_1411.G * TC_1410_1411.dT; TC_1410_1411.dT = TC_1410_1411.port_a.T - TC_1410_1411.port_b.T; TC_1410_1411.port_a.Q_flow = TC_1410_1411.Q_flow; TC_1410_1411.port_b.Q_flow = -TC_1410_1411.Q_flow; TC_1410_1457.Q_flow = TC_1410_1457.G * TC_1410_1457.dT; TC_1410_1457.dT = TC_1410_1457.port_a.T - TC_1410_1457.port_b.T; TC_1410_1457.port_a.Q_flow = TC_1410_1457.Q_flow; TC_1410_1457.port_b.Q_flow = -TC_1410_1457.Q_flow; TC_1411_1412.Q_flow = TC_1411_1412.G * TC_1411_1412.dT; TC_1411_1412.dT = TC_1411_1412.port_a.T - TC_1411_1412.port_b.T; TC_1411_1412.port_a.Q_flow = TC_1411_1412.Q_flow; TC_1411_1412.port_b.Q_flow = -TC_1411_1412.Q_flow; TC_1411_1458.Q_flow = TC_1411_1458.G * TC_1411_1458.dT; TC_1411_1458.dT = TC_1411_1458.port_a.T - TC_1411_1458.port_b.T; TC_1411_1458.port_a.Q_flow = TC_1411_1458.Q_flow; TC_1411_1458.port_b.Q_flow = -TC_1411_1458.Q_flow; TC_1412_1413.Q_flow = TC_1412_1413.G * TC_1412_1413.dT; TC_1412_1413.dT = TC_1412_1413.port_a.T - TC_1412_1413.port_b.T; TC_1412_1413.port_a.Q_flow = TC_1412_1413.Q_flow; TC_1412_1413.port_b.Q_flow = -TC_1412_1413.Q_flow; TC_1412_1459.Q_flow = TC_1412_1459.G * TC_1412_1459.dT; TC_1412_1459.dT = TC_1412_1459.port_a.T - TC_1412_1459.port_b.T; TC_1412_1459.port_a.Q_flow = TC_1412_1459.Q_flow; TC_1412_1459.port_b.Q_flow = -TC_1412_1459.Q_flow; TC_1413_1460.Q_flow = TC_1413_1460.G * TC_1413_1460.dT; TC_1413_1460.dT = TC_1413_1460.port_a.T - TC_1413_1460.port_b.T; TC_1413_1460.port_a.Q_flow = TC_1413_1460.Q_flow; TC_1413_1460.port_b.Q_flow = -TC_1413_1460.Q_flow; TC_1414_1417.Q_flow = TC_1414_1417.G * TC_1414_1417.dT; TC_1414_1417.dT = TC_1414_1417.port_a.T - TC_1414_1417.port_b.T; TC_1414_1417.port_a.Q_flow = TC_1414_1417.Q_flow; TC_1414_1417.port_b.Q_flow = -TC_1414_1417.Q_flow; TC_1414_1463.Q_flow = TC_1414_1463.G * TC_1414_1463.dT; TC_1414_1463.dT = TC_1414_1463.port_a.T - TC_1414_1463.port_b.T; TC_1414_1463.port_a.Q_flow = TC_1414_1463.Q_flow; TC_1414_1463.port_b.Q_flow = -TC_1414_1463.Q_flow; TC_1415_1416.Q_flow = TC_1415_1416.G * TC_1415_1416.dT; TC_1415_1416.dT = TC_1415_1416.port_a.T - TC_1415_1416.port_b.T; TC_1415_1416.port_a.Q_flow = TC_1415_1416.Q_flow; TC_1415_1416.port_b.Q_flow = -TC_1415_1416.Q_flow; TC_1415_1418.Q_flow = TC_1415_1418.G * TC_1415_1418.dT; TC_1415_1418.dT = TC_1415_1418.port_a.T - TC_1415_1418.port_b.T; TC_1415_1418.port_a.Q_flow = TC_1415_1418.Q_flow; TC_1415_1418.port_b.Q_flow = -TC_1415_1418.Q_flow; TC_1415_1464.Q_flow = TC_1415_1464.G * TC_1415_1464.dT; TC_1415_1464.dT = TC_1415_1464.port_a.T - TC_1415_1464.port_b.T; TC_1415_1464.port_a.Q_flow = TC_1415_1464.Q_flow; TC_1415_1464.port_b.Q_flow = -TC_1415_1464.Q_flow; TC_1416_1419.Q_flow = TC_1416_1419.G * TC_1416_1419.dT; TC_1416_1419.dT = TC_1416_1419.port_a.T - TC_1416_1419.port_b.T; TC_1416_1419.port_a.Q_flow = TC_1416_1419.Q_flow; TC_1416_1419.port_b.Q_flow = -TC_1416_1419.Q_flow; TC_1416_1465.Q_flow = TC_1416_1465.G * TC_1416_1465.dT; TC_1416_1465.dT = TC_1416_1465.port_a.T - TC_1416_1465.port_b.T; TC_1416_1465.port_a.Q_flow = TC_1416_1465.Q_flow; TC_1416_1465.port_b.Q_flow = -TC_1416_1465.Q_flow; TC_1417_1420.Q_flow = TC_1417_1420.G * TC_1417_1420.dT; TC_1417_1420.dT = TC_1417_1420.port_a.T - TC_1417_1420.port_b.T; TC_1417_1420.port_a.Q_flow = TC_1417_1420.Q_flow; TC_1417_1420.port_b.Q_flow = -TC_1417_1420.Q_flow; TC_1418_1419.Q_flow = TC_1418_1419.G * TC_1418_1419.dT; TC_1418_1419.dT = TC_1418_1419.port_a.T - TC_1418_1419.port_b.T; TC_1418_1419.port_a.Q_flow = TC_1418_1419.Q_flow; TC_1418_1419.port_b.Q_flow = -TC_1418_1419.Q_flow; TC_1418_1421.Q_flow = TC_1418_1421.G * TC_1418_1421.dT; TC_1418_1421.dT = TC_1418_1421.port_a.T - TC_1418_1421.port_b.T; TC_1418_1421.port_a.Q_flow = TC_1418_1421.Q_flow; TC_1418_1421.port_b.Q_flow = -TC_1418_1421.Q_flow; TC_1419_1422.Q_flow = TC_1419_1422.G * TC_1419_1422.dT; TC_1419_1422.dT = TC_1419_1422.port_a.T - TC_1419_1422.port_b.T; TC_1419_1422.port_a.Q_flow = TC_1419_1422.Q_flow; TC_1419_1422.port_b.Q_flow = -TC_1419_1422.Q_flow; TC_1420_1423.Q_flow = TC_1420_1423.G * TC_1420_1423.dT; TC_1420_1423.dT = TC_1420_1423.port_a.T - TC_1420_1423.port_b.T; TC_1420_1423.port_a.Q_flow = TC_1420_1423.Q_flow; TC_1420_1423.port_b.Q_flow = -TC_1420_1423.Q_flow; TC_1421_1422.Q_flow = TC_1421_1422.G * TC_1421_1422.dT; TC_1421_1422.dT = TC_1421_1422.port_a.T - TC_1421_1422.port_b.T; TC_1421_1422.port_a.Q_flow = TC_1421_1422.Q_flow; TC_1421_1422.port_b.Q_flow = -TC_1421_1422.Q_flow; TC_1421_1424.Q_flow = TC_1421_1424.G * TC_1421_1424.dT; TC_1421_1424.dT = TC_1421_1424.port_a.T - TC_1421_1424.port_b.T; TC_1421_1424.port_a.Q_flow = TC_1421_1424.Q_flow; TC_1421_1424.port_b.Q_flow = -TC_1421_1424.Q_flow; TC_1422_1425.Q_flow = TC_1422_1425.G * TC_1422_1425.dT; TC_1422_1425.dT = TC_1422_1425.port_a.T - TC_1422_1425.port_b.T; TC_1422_1425.port_a.Q_flow = TC_1422_1425.Q_flow; TC_1422_1425.port_b.Q_flow = -TC_1422_1425.Q_flow; TC_1423_1426.Q_flow = TC_1423_1426.G * TC_1423_1426.dT; TC_1423_1426.dT = TC_1423_1426.port_a.T - TC_1423_1426.port_b.T; TC_1423_1426.port_a.Q_flow = TC_1423_1426.Q_flow; TC_1423_1426.port_b.Q_flow = -TC_1423_1426.Q_flow; TC_1424_1425.Q_flow = TC_1424_1425.G * TC_1424_1425.dT; TC_1424_1425.dT = TC_1424_1425.port_a.T - TC_1424_1425.port_b.T; TC_1424_1425.port_a.Q_flow = TC_1424_1425.Q_flow; TC_1424_1425.port_b.Q_flow = -TC_1424_1425.Q_flow; TC_1424_1427.Q_flow = TC_1424_1427.G * TC_1424_1427.dT; TC_1424_1427.dT = TC_1424_1427.port_a.T - TC_1424_1427.port_b.T; TC_1424_1427.port_a.Q_flow = TC_1424_1427.Q_flow; TC_1424_1427.port_b.Q_flow = -TC_1424_1427.Q_flow; TC_1425_1428.Q_flow = TC_1425_1428.G * TC_1425_1428.dT; TC_1425_1428.dT = TC_1425_1428.port_a.T - TC_1425_1428.port_b.T; TC_1425_1428.port_a.Q_flow = TC_1425_1428.Q_flow; TC_1425_1428.port_b.Q_flow = -TC_1425_1428.Q_flow; TC_1426_1429.Q_flow = TC_1426_1429.G * TC_1426_1429.dT; TC_1426_1429.dT = TC_1426_1429.port_a.T - TC_1426_1429.port_b.T; TC_1426_1429.port_a.Q_flow = TC_1426_1429.Q_flow; TC_1426_1429.port_b.Q_flow = -TC_1426_1429.Q_flow; TC_1427_1428.Q_flow = TC_1427_1428.G * TC_1427_1428.dT; TC_1427_1428.dT = TC_1427_1428.port_a.T - TC_1427_1428.port_b.T; TC_1427_1428.port_a.Q_flow = TC_1427_1428.Q_flow; TC_1427_1428.port_b.Q_flow = -TC_1427_1428.Q_flow; TC_1427_1430.Q_flow = TC_1427_1430.G * TC_1427_1430.dT; TC_1427_1430.dT = TC_1427_1430.port_a.T - TC_1427_1430.port_b.T; TC_1427_1430.port_a.Q_flow = TC_1427_1430.Q_flow; TC_1427_1430.port_b.Q_flow = -TC_1427_1430.Q_flow; TC_1428_1431.Q_flow = TC_1428_1431.G * TC_1428_1431.dT; TC_1428_1431.dT = TC_1428_1431.port_a.T - TC_1428_1431.port_b.T; TC_1428_1431.port_a.Q_flow = TC_1428_1431.Q_flow; TC_1428_1431.port_b.Q_flow = -TC_1428_1431.Q_flow; TC_1429_1432.Q_flow = TC_1429_1432.G * TC_1429_1432.dT; TC_1429_1432.dT = TC_1429_1432.port_a.T - TC_1429_1432.port_b.T; TC_1429_1432.port_a.Q_flow = TC_1429_1432.Q_flow; TC_1429_1432.port_b.Q_flow = -TC_1429_1432.Q_flow; TC_1430_1431.Q_flow = TC_1430_1431.G * TC_1430_1431.dT; TC_1430_1431.dT = TC_1430_1431.port_a.T - TC_1430_1431.port_b.T; TC_1430_1431.port_a.Q_flow = TC_1430_1431.Q_flow; TC_1430_1431.port_b.Q_flow = -TC_1430_1431.Q_flow; TC_1430_1433.Q_flow = TC_1430_1433.G * TC_1430_1433.dT; TC_1430_1433.dT = TC_1430_1433.port_a.T - TC_1430_1433.port_b.T; TC_1430_1433.port_a.Q_flow = TC_1430_1433.Q_flow; TC_1430_1433.port_b.Q_flow = -TC_1430_1433.Q_flow; TC_1431_1434.Q_flow = TC_1431_1434.G * TC_1431_1434.dT; TC_1431_1434.dT = TC_1431_1434.port_a.T - TC_1431_1434.port_b.T; TC_1431_1434.port_a.Q_flow = TC_1431_1434.Q_flow; TC_1431_1434.port_b.Q_flow = -TC_1431_1434.Q_flow; TC_1432_1435.Q_flow = TC_1432_1435.G * TC_1432_1435.dT; TC_1432_1435.dT = TC_1432_1435.port_a.T - TC_1432_1435.port_b.T; TC_1432_1435.port_a.Q_flow = TC_1432_1435.Q_flow; TC_1432_1435.port_b.Q_flow = -TC_1432_1435.Q_flow; TC_1433_1434.Q_flow = TC_1433_1434.G * TC_1433_1434.dT; TC_1433_1434.dT = TC_1433_1434.port_a.T - TC_1433_1434.port_b.T; TC_1433_1434.port_a.Q_flow = TC_1433_1434.Q_flow; TC_1433_1434.port_b.Q_flow = -TC_1433_1434.Q_flow; TC_1433_1436.Q_flow = TC_1433_1436.G * TC_1433_1436.dT; TC_1433_1436.dT = TC_1433_1436.port_a.T - TC_1433_1436.port_b.T; TC_1433_1436.port_a.Q_flow = TC_1433_1436.Q_flow; TC_1433_1436.port_b.Q_flow = -TC_1433_1436.Q_flow; TC_1434_1437.Q_flow = TC_1434_1437.G * TC_1434_1437.dT; TC_1434_1437.dT = TC_1434_1437.port_a.T - TC_1434_1437.port_b.T; TC_1434_1437.port_a.Q_flow = TC_1434_1437.Q_flow; TC_1434_1437.port_b.Q_flow = -TC_1434_1437.Q_flow; TC_1435_1438.Q_flow = TC_1435_1438.G * TC_1435_1438.dT; TC_1435_1438.dT = TC_1435_1438.port_a.T - TC_1435_1438.port_b.T; TC_1435_1438.port_a.Q_flow = TC_1435_1438.Q_flow; TC_1435_1438.port_b.Q_flow = -TC_1435_1438.Q_flow; TC_1436_1437.Q_flow = TC_1436_1437.G * TC_1436_1437.dT; TC_1436_1437.dT = TC_1436_1437.port_a.T - TC_1436_1437.port_b.T; TC_1436_1437.port_a.Q_flow = TC_1436_1437.Q_flow; TC_1436_1437.port_b.Q_flow = -TC_1436_1437.Q_flow; TC_1436_1439.Q_flow = TC_1436_1439.G * TC_1436_1439.dT; TC_1436_1439.dT = TC_1436_1439.port_a.T - TC_1436_1439.port_b.T; TC_1436_1439.port_a.Q_flow = TC_1436_1439.Q_flow; TC_1436_1439.port_b.Q_flow = -TC_1436_1439.Q_flow; TC_1437_1440.Q_flow = TC_1437_1440.G * TC_1437_1440.dT; TC_1437_1440.dT = TC_1437_1440.port_a.T - TC_1437_1440.port_b.T; TC_1437_1440.port_a.Q_flow = TC_1437_1440.Q_flow; TC_1437_1440.port_b.Q_flow = -TC_1437_1440.Q_flow; TC_1438_1449.Q_flow = TC_1438_1449.G * TC_1438_1449.dT; TC_1438_1449.dT = TC_1438_1449.port_a.T - TC_1438_1449.port_b.T; TC_1438_1449.port_a.Q_flow = TC_1438_1449.Q_flow; TC_1438_1449.port_b.Q_flow = -TC_1438_1449.Q_flow; TC_1439_1440.Q_flow = TC_1439_1440.G * TC_1439_1440.dT; TC_1439_1440.dT = TC_1439_1440.port_a.T - TC_1439_1440.port_b.T; TC_1439_1440.port_a.Q_flow = TC_1439_1440.Q_flow; TC_1439_1440.port_b.Q_flow = -TC_1439_1440.Q_flow; TC_1439_1450.Q_flow = TC_1439_1450.G * TC_1439_1450.dT; TC_1439_1450.dT = TC_1439_1450.port_a.T - TC_1439_1450.port_b.T; TC_1439_1450.port_a.Q_flow = TC_1439_1450.Q_flow; TC_1439_1450.port_b.Q_flow = -TC_1439_1450.Q_flow; TC_1440_1441.Q_flow = TC_1440_1441.G * TC_1440_1441.dT; TC_1440_1441.dT = TC_1440_1441.port_a.T - TC_1440_1441.port_b.T; TC_1440_1441.port_a.Q_flow = TC_1440_1441.Q_flow; TC_1440_1441.port_b.Q_flow = -TC_1440_1441.Q_flow; TC_1440_1451.Q_flow = TC_1440_1451.G * TC_1440_1451.dT; TC_1440_1451.dT = TC_1440_1451.port_a.T - TC_1440_1451.port_b.T; TC_1440_1451.port_a.Q_flow = TC_1440_1451.Q_flow; TC_1440_1451.port_b.Q_flow = -TC_1440_1451.Q_flow; TC_1441_1442.Q_flow = TC_1441_1442.G * TC_1441_1442.dT; TC_1441_1442.dT = TC_1441_1442.port_a.T - TC_1441_1442.port_b.T; TC_1441_1442.port_a.Q_flow = TC_1441_1442.Q_flow; TC_1441_1442.port_b.Q_flow = -TC_1441_1442.Q_flow; TC_1441_1452.Q_flow = TC_1441_1452.G * TC_1441_1452.dT; TC_1441_1452.dT = TC_1441_1452.port_a.T - TC_1441_1452.port_b.T; TC_1441_1452.port_a.Q_flow = TC_1441_1452.Q_flow; TC_1441_1452.port_b.Q_flow = -TC_1441_1452.Q_flow; TC_1442_1443.Q_flow = TC_1442_1443.G * TC_1442_1443.dT; TC_1442_1443.dT = TC_1442_1443.port_a.T - TC_1442_1443.port_b.T; TC_1442_1443.port_a.Q_flow = TC_1442_1443.Q_flow; TC_1442_1443.port_b.Q_flow = -TC_1442_1443.Q_flow; TC_1442_1453.Q_flow = TC_1442_1453.G * TC_1442_1453.dT; TC_1442_1453.dT = TC_1442_1453.port_a.T - TC_1442_1453.port_b.T; TC_1442_1453.port_a.Q_flow = TC_1442_1453.Q_flow; TC_1442_1453.port_b.Q_flow = -TC_1442_1453.Q_flow; TC_1443_1444.Q_flow = TC_1443_1444.G * TC_1443_1444.dT; TC_1443_1444.dT = TC_1443_1444.port_a.T - TC_1443_1444.port_b.T; TC_1443_1444.port_a.Q_flow = TC_1443_1444.Q_flow; TC_1443_1444.port_b.Q_flow = -TC_1443_1444.Q_flow; TC_1443_1454.Q_flow = TC_1443_1454.G * TC_1443_1454.dT; TC_1443_1454.dT = TC_1443_1454.port_a.T - TC_1443_1454.port_b.T; TC_1443_1454.port_a.Q_flow = TC_1443_1454.Q_flow; TC_1443_1454.port_b.Q_flow = -TC_1443_1454.Q_flow; TC_1444_1445.Q_flow = TC_1444_1445.G * TC_1444_1445.dT; TC_1444_1445.dT = TC_1444_1445.port_a.T - TC_1444_1445.port_b.T; TC_1444_1445.port_a.Q_flow = TC_1444_1445.Q_flow; TC_1444_1445.port_b.Q_flow = -TC_1444_1445.Q_flow; TC_1444_1455.Q_flow = TC_1444_1455.G * TC_1444_1455.dT; TC_1444_1455.dT = TC_1444_1455.port_a.T - TC_1444_1455.port_b.T; TC_1444_1455.port_a.Q_flow = TC_1444_1455.Q_flow; TC_1444_1455.port_b.Q_flow = -TC_1444_1455.Q_flow; TC_1445_1446.Q_flow = TC_1445_1446.G * TC_1445_1446.dT; TC_1445_1446.dT = TC_1445_1446.port_a.T - TC_1445_1446.port_b.T; TC_1445_1446.port_a.Q_flow = TC_1445_1446.Q_flow; TC_1445_1446.port_b.Q_flow = -TC_1445_1446.Q_flow; TC_1445_1456.Q_flow = TC_1445_1456.G * TC_1445_1456.dT; TC_1445_1456.dT = TC_1445_1456.port_a.T - TC_1445_1456.port_b.T; TC_1445_1456.port_a.Q_flow = TC_1445_1456.Q_flow; TC_1445_1456.port_b.Q_flow = -TC_1445_1456.Q_flow; TC_1446_1447.Q_flow = TC_1446_1447.G * TC_1446_1447.dT; TC_1446_1447.dT = TC_1446_1447.port_a.T - TC_1446_1447.port_b.T; TC_1446_1447.port_a.Q_flow = TC_1446_1447.Q_flow; TC_1446_1447.port_b.Q_flow = -TC_1446_1447.Q_flow; TC_1446_1457.Q_flow = TC_1446_1457.G * TC_1446_1457.dT; TC_1446_1457.dT = TC_1446_1457.port_a.T - TC_1446_1457.port_b.T; TC_1446_1457.port_a.Q_flow = TC_1446_1457.Q_flow; TC_1446_1457.port_b.Q_flow = -TC_1446_1457.Q_flow; TC_1447_1448.Q_flow = TC_1447_1448.G * TC_1447_1448.dT; TC_1447_1448.dT = TC_1447_1448.port_a.T - TC_1447_1448.port_b.T; TC_1447_1448.port_a.Q_flow = TC_1447_1448.Q_flow; TC_1447_1448.port_b.Q_flow = -TC_1447_1448.Q_flow; TC_1447_1458.Q_flow = TC_1447_1458.G * TC_1447_1458.dT; TC_1447_1458.dT = TC_1447_1458.port_a.T - TC_1447_1458.port_b.T; TC_1447_1458.port_a.Q_flow = TC_1447_1458.Q_flow; TC_1447_1458.port_b.Q_flow = -TC_1447_1458.Q_flow; TC_1448_1449.Q_flow = TC_1448_1449.G * TC_1448_1449.dT; TC_1448_1449.dT = TC_1448_1449.port_a.T - TC_1448_1449.port_b.T; TC_1448_1449.port_a.Q_flow = TC_1448_1449.Q_flow; TC_1448_1449.port_b.Q_flow = -TC_1448_1449.Q_flow; TC_1448_1459.Q_flow = TC_1448_1459.G * TC_1448_1459.dT; TC_1448_1459.dT = TC_1448_1459.port_a.T - TC_1448_1459.port_b.T; TC_1448_1459.port_a.Q_flow = TC_1448_1459.Q_flow; TC_1448_1459.port_b.Q_flow = -TC_1448_1459.Q_flow; TC_1449_1460.Q_flow = TC_1449_1460.G * TC_1449_1460.dT; TC_1449_1460.dT = TC_1449_1460.port_a.T - TC_1449_1460.port_b.T; TC_1449_1460.port_a.Q_flow = TC_1449_1460.Q_flow; TC_1449_1460.port_b.Q_flow = -TC_1449_1460.Q_flow; TC_1450_1451.Q_flow = TC_1450_1451.G * TC_1450_1451.dT; TC_1450_1451.dT = TC_1450_1451.port_a.T - TC_1450_1451.port_b.T; TC_1450_1451.port_a.Q_flow = TC_1450_1451.Q_flow; TC_1450_1451.port_b.Q_flow = -TC_1450_1451.Q_flow; TC_1451_1452.Q_flow = TC_1451_1452.G * TC_1451_1452.dT; TC_1451_1452.dT = TC_1451_1452.port_a.T - TC_1451_1452.port_b.T; TC_1451_1452.port_a.Q_flow = TC_1451_1452.Q_flow; TC_1451_1452.port_b.Q_flow = -TC_1451_1452.Q_flow; TC_1452_1453.Q_flow = TC_1452_1453.G * TC_1452_1453.dT; TC_1452_1453.dT = TC_1452_1453.port_a.T - TC_1452_1453.port_b.T; TC_1452_1453.port_a.Q_flow = TC_1452_1453.Q_flow; TC_1452_1453.port_b.Q_flow = -TC_1452_1453.Q_flow; TC_1453_1454.Q_flow = TC_1453_1454.G * TC_1453_1454.dT; TC_1453_1454.dT = TC_1453_1454.port_a.T - TC_1453_1454.port_b.T; TC_1453_1454.port_a.Q_flow = TC_1453_1454.Q_flow; TC_1453_1454.port_b.Q_flow = -TC_1453_1454.Q_flow; TC_1454_1455.Q_flow = TC_1454_1455.G * TC_1454_1455.dT; TC_1454_1455.dT = TC_1454_1455.port_a.T - TC_1454_1455.port_b.T; TC_1454_1455.port_a.Q_flow = TC_1454_1455.Q_flow; TC_1454_1455.port_b.Q_flow = -TC_1454_1455.Q_flow; TC_1455_1456.Q_flow = TC_1455_1456.G * TC_1455_1456.dT; TC_1455_1456.dT = TC_1455_1456.port_a.T - TC_1455_1456.port_b.T; TC_1455_1456.port_a.Q_flow = TC_1455_1456.Q_flow; TC_1455_1456.port_b.Q_flow = -TC_1455_1456.Q_flow; TC_1456_1457.Q_flow = TC_1456_1457.G * TC_1456_1457.dT; TC_1456_1457.dT = TC_1456_1457.port_a.T - TC_1456_1457.port_b.T; TC_1456_1457.port_a.Q_flow = TC_1456_1457.Q_flow; TC_1456_1457.port_b.Q_flow = -TC_1456_1457.Q_flow; TC_1457_1458.Q_flow = TC_1457_1458.G * TC_1457_1458.dT; TC_1457_1458.dT = TC_1457_1458.port_a.T - TC_1457_1458.port_b.T; TC_1457_1458.port_a.Q_flow = TC_1457_1458.Q_flow; TC_1457_1458.port_b.Q_flow = -TC_1457_1458.Q_flow; TC_1458_1459.Q_flow = TC_1458_1459.G * TC_1458_1459.dT; TC_1458_1459.dT = TC_1458_1459.port_a.T - TC_1458_1459.port_b.T; TC_1458_1459.port_a.Q_flow = TC_1458_1459.Q_flow; TC_1458_1459.port_b.Q_flow = -TC_1458_1459.Q_flow; TC_1459_1460.Q_flow = TC_1459_1460.G * TC_1459_1460.dT; TC_1459_1460.dT = TC_1459_1460.port_a.T - TC_1459_1460.port_b.T; TC_1459_1460.port_a.Q_flow = TC_1459_1460.Q_flow; TC_1459_1460.port_b.Q_flow = -TC_1459_1460.Q_flow; TC_1461_1462.Q_flow = TC_1461_1462.G * TC_1461_1462.dT; TC_1461_1462.dT = TC_1461_1462.port_a.T - TC_1461_1462.port_b.T; TC_1461_1462.port_a.Q_flow = TC_1461_1462.Q_flow; TC_1461_1462.port_b.Q_flow = -TC_1461_1462.Q_flow; TC_1461_1464.Q_flow = TC_1461_1464.G * TC_1461_1464.dT; TC_1461_1464.dT = TC_1461_1464.port_a.T - TC_1461_1464.port_b.T; TC_1461_1464.port_a.Q_flow = TC_1461_1464.Q_flow; TC_1461_1464.port_b.Q_flow = -TC_1461_1464.Q_flow; TC_1461_1466.Q_flow = TC_1461_1466.G * TC_1461_1466.dT; TC_1461_1466.dT = TC_1461_1466.port_a.T - TC_1461_1466.port_b.T; TC_1461_1466.port_a.Q_flow = TC_1461_1466.Q_flow; TC_1461_1466.port_b.Q_flow = -TC_1461_1466.Q_flow; TC_1462_1465.Q_flow = TC_1462_1465.G * TC_1462_1465.dT; TC_1462_1465.dT = TC_1462_1465.port_a.T - TC_1462_1465.port_b.T; TC_1462_1465.port_a.Q_flow = TC_1462_1465.Q_flow; TC_1462_1465.port_b.Q_flow = -TC_1462_1465.Q_flow; TC_1462_1467.Q_flow = TC_1462_1467.G * TC_1462_1467.dT; TC_1462_1467.dT = TC_1462_1467.port_a.T - TC_1462_1467.port_b.T; TC_1462_1467.port_a.Q_flow = TC_1462_1467.Q_flow; TC_1462_1467.port_b.Q_flow = -TC_1462_1467.Q_flow; TC_1463_1476.Q_flow = TC_1463_1476.G * TC_1463_1476.dT; TC_1463_1476.dT = TC_1463_1476.port_a.T - TC_1463_1476.port_b.T; TC_1463_1476.port_a.Q_flow = TC_1463_1476.Q_flow; TC_1463_1476.port_b.Q_flow = -TC_1463_1476.Q_flow; TC_1464_1465.Q_flow = TC_1464_1465.G * TC_1464_1465.dT; TC_1464_1465.dT = TC_1464_1465.port_a.T - TC_1464_1465.port_b.T; TC_1464_1465.port_a.Q_flow = TC_1464_1465.Q_flow; TC_1464_1465.port_b.Q_flow = -TC_1464_1465.Q_flow; TC_1466_1467.Q_flow = TC_1466_1467.G * TC_1466_1467.dT; TC_1466_1467.dT = TC_1466_1467.port_a.T - TC_1466_1467.port_b.T; TC_1466_1467.port_a.Q_flow = TC_1466_1467.Q_flow; TC_1466_1467.port_b.Q_flow = -TC_1466_1467.Q_flow; TC_1466_1477.Q_flow = TC_1466_1477.G * TC_1466_1477.dT; TC_1466_1477.dT = TC_1466_1477.port_a.T - TC_1466_1477.port_b.T; TC_1466_1477.port_a.Q_flow = TC_1466_1477.Q_flow; TC_1466_1477.port_b.Q_flow = -TC_1466_1477.Q_flow; TC_1467_1468.Q_flow = TC_1467_1468.G * TC_1467_1468.dT; TC_1467_1468.dT = TC_1467_1468.port_a.T - TC_1467_1468.port_b.T; TC_1467_1468.port_a.Q_flow = TC_1467_1468.Q_flow; TC_1467_1468.port_b.Q_flow = -TC_1467_1468.Q_flow; TC_1467_1478.Q_flow = TC_1467_1478.G * TC_1467_1478.dT; TC_1467_1478.dT = TC_1467_1478.port_a.T - TC_1467_1478.port_b.T; TC_1467_1478.port_a.Q_flow = TC_1467_1478.Q_flow; TC_1467_1478.port_b.Q_flow = -TC_1467_1478.Q_flow; TC_1468_1469.Q_flow = TC_1468_1469.G * TC_1468_1469.dT; TC_1468_1469.dT = TC_1468_1469.port_a.T - TC_1468_1469.port_b.T; TC_1468_1469.port_a.Q_flow = TC_1468_1469.Q_flow; TC_1468_1469.port_b.Q_flow = -TC_1468_1469.Q_flow; TC_1468_1479.Q_flow = TC_1468_1479.G * TC_1468_1479.dT; TC_1468_1479.dT = TC_1468_1479.port_a.T - TC_1468_1479.port_b.T; TC_1468_1479.port_a.Q_flow = TC_1468_1479.Q_flow; TC_1468_1479.port_b.Q_flow = -TC_1468_1479.Q_flow; TC_1469_1470.Q_flow = TC_1469_1470.G * TC_1469_1470.dT; TC_1469_1470.dT = TC_1469_1470.port_a.T - TC_1469_1470.port_b.T; TC_1469_1470.port_a.Q_flow = TC_1469_1470.Q_flow; TC_1469_1470.port_b.Q_flow = -TC_1469_1470.Q_flow; TC_1469_1480.Q_flow = TC_1469_1480.G * TC_1469_1480.dT; TC_1469_1480.dT = TC_1469_1480.port_a.T - TC_1469_1480.port_b.T; TC_1469_1480.port_a.Q_flow = TC_1469_1480.Q_flow; TC_1469_1480.port_b.Q_flow = -TC_1469_1480.Q_flow; TC_1470_1471.Q_flow = TC_1470_1471.G * TC_1470_1471.dT; TC_1470_1471.dT = TC_1470_1471.port_a.T - TC_1470_1471.port_b.T; TC_1470_1471.port_a.Q_flow = TC_1470_1471.Q_flow; TC_1470_1471.port_b.Q_flow = -TC_1470_1471.Q_flow; TC_1470_1481.Q_flow = TC_1470_1481.G * TC_1470_1481.dT; TC_1470_1481.dT = TC_1470_1481.port_a.T - TC_1470_1481.port_b.T; TC_1470_1481.port_a.Q_flow = TC_1470_1481.Q_flow; TC_1470_1481.port_b.Q_flow = -TC_1470_1481.Q_flow; TC_1471_1472.Q_flow = TC_1471_1472.G * TC_1471_1472.dT; TC_1471_1472.dT = TC_1471_1472.port_a.T - TC_1471_1472.port_b.T; TC_1471_1472.port_a.Q_flow = TC_1471_1472.Q_flow; TC_1471_1472.port_b.Q_flow = -TC_1471_1472.Q_flow; TC_1471_1482.Q_flow = TC_1471_1482.G * TC_1471_1482.dT; TC_1471_1482.dT = TC_1471_1482.port_a.T - TC_1471_1482.port_b.T; TC_1471_1482.port_a.Q_flow = TC_1471_1482.Q_flow; TC_1471_1482.port_b.Q_flow = -TC_1471_1482.Q_flow; TC_1472_1473.Q_flow = TC_1472_1473.G * TC_1472_1473.dT; TC_1472_1473.dT = TC_1472_1473.port_a.T - TC_1472_1473.port_b.T; TC_1472_1473.port_a.Q_flow = TC_1472_1473.Q_flow; TC_1472_1473.port_b.Q_flow = -TC_1472_1473.Q_flow; TC_1472_1483.Q_flow = TC_1472_1483.G * TC_1472_1483.dT; TC_1472_1483.dT = TC_1472_1483.port_a.T - TC_1472_1483.port_b.T; TC_1472_1483.port_a.Q_flow = TC_1472_1483.Q_flow; TC_1472_1483.port_b.Q_flow = -TC_1472_1483.Q_flow; TC_1473_1474.Q_flow = TC_1473_1474.G * TC_1473_1474.dT; TC_1473_1474.dT = TC_1473_1474.port_a.T - TC_1473_1474.port_b.T; TC_1473_1474.port_a.Q_flow = TC_1473_1474.Q_flow; TC_1473_1474.port_b.Q_flow = -TC_1473_1474.Q_flow; TC_1473_1484.Q_flow = TC_1473_1484.G * TC_1473_1484.dT; TC_1473_1484.dT = TC_1473_1484.port_a.T - TC_1473_1484.port_b.T; TC_1473_1484.port_a.Q_flow = TC_1473_1484.Q_flow; TC_1473_1484.port_b.Q_flow = -TC_1473_1484.Q_flow; TC_1474_1475.Q_flow = TC_1474_1475.G * TC_1474_1475.dT; TC_1474_1475.dT = TC_1474_1475.port_a.T - TC_1474_1475.port_b.T; TC_1474_1475.port_a.Q_flow = TC_1474_1475.Q_flow; TC_1474_1475.port_b.Q_flow = -TC_1474_1475.Q_flow; TC_1474_1485.Q_flow = TC_1474_1485.G * TC_1474_1485.dT; TC_1474_1485.dT = TC_1474_1485.port_a.T - TC_1474_1485.port_b.T; TC_1474_1485.port_a.Q_flow = TC_1474_1485.Q_flow; TC_1474_1485.port_b.Q_flow = -TC_1474_1485.Q_flow; TC_1475_1476.Q_flow = TC_1475_1476.G * TC_1475_1476.dT; TC_1475_1476.dT = TC_1475_1476.port_a.T - TC_1475_1476.port_b.T; TC_1475_1476.port_a.Q_flow = TC_1475_1476.Q_flow; TC_1475_1476.port_b.Q_flow = -TC_1475_1476.Q_flow; TC_1475_1486.Q_flow = TC_1475_1486.G * TC_1475_1486.dT; TC_1475_1486.dT = TC_1475_1486.port_a.T - TC_1475_1486.port_b.T; TC_1475_1486.port_a.Q_flow = TC_1475_1486.Q_flow; TC_1475_1486.port_b.Q_flow = -TC_1475_1486.Q_flow; TC_1476_1487.Q_flow = TC_1476_1487.G * TC_1476_1487.dT; TC_1476_1487.dT = TC_1476_1487.port_a.T - TC_1476_1487.port_b.T; TC_1476_1487.port_a.Q_flow = TC_1476_1487.Q_flow; TC_1476_1487.port_b.Q_flow = -TC_1476_1487.Q_flow; TC_1477_1478.Q_flow = TC_1477_1478.G * TC_1477_1478.dT; TC_1477_1478.dT = TC_1477_1478.port_a.T - TC_1477_1478.port_b.T; TC_1477_1478.port_a.Q_flow = TC_1477_1478.Q_flow; TC_1477_1478.port_b.Q_flow = -TC_1477_1478.Q_flow; TC_1478_1479.Q_flow = TC_1478_1479.G * TC_1478_1479.dT; TC_1478_1479.dT = TC_1478_1479.port_a.T - TC_1478_1479.port_b.T; TC_1478_1479.port_a.Q_flow = TC_1478_1479.Q_flow; TC_1478_1479.port_b.Q_flow = -TC_1478_1479.Q_flow; TC_1479_1480.Q_flow = TC_1479_1480.G * TC_1479_1480.dT; TC_1479_1480.dT = TC_1479_1480.port_a.T - TC_1479_1480.port_b.T; TC_1479_1480.port_a.Q_flow = TC_1479_1480.Q_flow; TC_1479_1480.port_b.Q_flow = -TC_1479_1480.Q_flow; TC_1480_1481.Q_flow = TC_1480_1481.G * TC_1480_1481.dT; TC_1480_1481.dT = TC_1480_1481.port_a.T - TC_1480_1481.port_b.T; TC_1480_1481.port_a.Q_flow = TC_1480_1481.Q_flow; TC_1480_1481.port_b.Q_flow = -TC_1480_1481.Q_flow; TC_1481_1482.Q_flow = TC_1481_1482.G * TC_1481_1482.dT; TC_1481_1482.dT = TC_1481_1482.port_a.T - TC_1481_1482.port_b.T; TC_1481_1482.port_a.Q_flow = TC_1481_1482.Q_flow; TC_1481_1482.port_b.Q_flow = -TC_1481_1482.Q_flow; TC_1482_1483.Q_flow = TC_1482_1483.G * TC_1482_1483.dT; TC_1482_1483.dT = TC_1482_1483.port_a.T - TC_1482_1483.port_b.T; TC_1482_1483.port_a.Q_flow = TC_1482_1483.Q_flow; TC_1482_1483.port_b.Q_flow = -TC_1482_1483.Q_flow; TC_1483_1484.Q_flow = TC_1483_1484.G * TC_1483_1484.dT; TC_1483_1484.dT = TC_1483_1484.port_a.T - TC_1483_1484.port_b.T; TC_1483_1484.port_a.Q_flow = TC_1483_1484.Q_flow; TC_1483_1484.port_b.Q_flow = -TC_1483_1484.Q_flow; TC_1484_1485.Q_flow = TC_1484_1485.G * TC_1484_1485.dT; TC_1484_1485.dT = TC_1484_1485.port_a.T - TC_1484_1485.port_b.T; TC_1484_1485.port_a.Q_flow = TC_1484_1485.Q_flow; TC_1484_1485.port_b.Q_flow = -TC_1484_1485.Q_flow; TC_1485_1486.Q_flow = TC_1485_1486.G * TC_1485_1486.dT; TC_1485_1486.dT = TC_1485_1486.port_a.T - TC_1485_1486.port_b.T; TC_1485_1486.port_a.Q_flow = TC_1485_1486.Q_flow; TC_1485_1486.port_b.Q_flow = -TC_1485_1486.Q_flow; TC_1486_1487.Q_flow = TC_1486_1487.G * TC_1486_1487.dT; TC_1486_1487.dT = TC_1486_1487.port_a.T - TC_1486_1487.port_b.T; TC_1486_1487.port_a.Q_flow = TC_1486_1487.Q_flow; TC_1486_1487.port_b.Q_flow = -TC_1486_1487.Q_flow; TC_1488_1489.Q_flow = TC_1488_1489.G * TC_1488_1489.dT; TC_1488_1489.dT = TC_1488_1489.port_a.T - TC_1488_1489.port_b.T; TC_1488_1489.port_a.Q_flow = TC_1488_1489.Q_flow; TC_1488_1489.port_b.Q_flow = -TC_1488_1489.Q_flow; TC_1488_1491.Q_flow = TC_1488_1491.G * TC_1488_1491.dT; TC_1488_1491.dT = TC_1488_1491.port_a.T - TC_1488_1491.port_b.T; TC_1488_1491.port_a.Q_flow = TC_1488_1491.Q_flow; TC_1488_1491.port_b.Q_flow = -TC_1488_1491.Q_flow; TC_1488_1509.Q_flow = TC_1488_1509.G * TC_1488_1509.dT; TC_1488_1509.dT = TC_1488_1509.port_a.T - TC_1488_1509.port_b.T; TC_1488_1509.port_a.Q_flow = TC_1488_1509.Q_flow; TC_1488_1509.port_b.Q_flow = -TC_1488_1509.Q_flow; TC_1489_1490.Q_flow = TC_1489_1490.G * TC_1489_1490.dT; TC_1489_1490.dT = TC_1489_1490.port_a.T - TC_1489_1490.port_b.T; TC_1489_1490.port_a.Q_flow = TC_1489_1490.Q_flow; TC_1489_1490.port_b.Q_flow = -TC_1489_1490.Q_flow; TC_1489_1492.Q_flow = TC_1489_1492.G * TC_1489_1492.dT; TC_1489_1492.dT = TC_1489_1492.port_a.T - TC_1489_1492.port_b.T; TC_1489_1492.port_a.Q_flow = TC_1489_1492.Q_flow; TC_1489_1492.port_b.Q_flow = -TC_1489_1492.Q_flow; TC_1489_1510.Q_flow = TC_1489_1510.G * TC_1489_1510.dT; TC_1489_1510.dT = TC_1489_1510.port_a.T - TC_1489_1510.port_b.T; TC_1489_1510.port_a.Q_flow = TC_1489_1510.Q_flow; TC_1489_1510.port_b.Q_flow = -TC_1489_1510.Q_flow; TC_1490_1493.Q_flow = TC_1490_1493.G * TC_1490_1493.dT; TC_1490_1493.dT = TC_1490_1493.port_a.T - TC_1490_1493.port_b.T; TC_1490_1493.port_a.Q_flow = TC_1490_1493.Q_flow; TC_1490_1493.port_b.Q_flow = -TC_1490_1493.Q_flow; TC_1490_1511.Q_flow = TC_1490_1511.G * TC_1490_1511.dT; TC_1490_1511.dT = TC_1490_1511.port_a.T - TC_1490_1511.port_b.T; TC_1490_1511.port_a.Q_flow = TC_1490_1511.Q_flow; TC_1490_1511.port_b.Q_flow = -TC_1490_1511.Q_flow; TC_1491_1492.Q_flow = TC_1491_1492.G * TC_1491_1492.dT; TC_1491_1492.dT = TC_1491_1492.port_a.T - TC_1491_1492.port_b.T; TC_1491_1492.port_a.Q_flow = TC_1491_1492.Q_flow; TC_1491_1492.port_b.Q_flow = -TC_1491_1492.Q_flow; TC_1491_1494.Q_flow = TC_1491_1494.G * TC_1491_1494.dT; TC_1491_1494.dT = TC_1491_1494.port_a.T - TC_1491_1494.port_b.T; TC_1491_1494.port_a.Q_flow = TC_1491_1494.Q_flow; TC_1491_1494.port_b.Q_flow = -TC_1491_1494.Q_flow; TC_1491_1512.Q_flow = TC_1491_1512.G * TC_1491_1512.dT; TC_1491_1512.dT = TC_1491_1512.port_a.T - TC_1491_1512.port_b.T; TC_1491_1512.port_a.Q_flow = TC_1491_1512.Q_flow; TC_1491_1512.port_b.Q_flow = -TC_1491_1512.Q_flow; TC_1492_1493.Q_flow = TC_1492_1493.G * TC_1492_1493.dT; TC_1492_1493.dT = TC_1492_1493.port_a.T - TC_1492_1493.port_b.T; TC_1492_1493.port_a.Q_flow = TC_1492_1493.Q_flow; TC_1492_1493.port_b.Q_flow = -TC_1492_1493.Q_flow; TC_1492_1495.Q_flow = TC_1492_1495.G * TC_1492_1495.dT; TC_1492_1495.dT = TC_1492_1495.port_a.T - TC_1492_1495.port_b.T; TC_1492_1495.port_a.Q_flow = TC_1492_1495.Q_flow; TC_1492_1495.port_b.Q_flow = -TC_1492_1495.Q_flow; TC_1492_1513.Q_flow = TC_1492_1513.G * TC_1492_1513.dT; TC_1492_1513.dT = TC_1492_1513.port_a.T - TC_1492_1513.port_b.T; TC_1492_1513.port_a.Q_flow = TC_1492_1513.Q_flow; TC_1492_1513.port_b.Q_flow = -TC_1492_1513.Q_flow; TC_1493_1496.Q_flow = TC_1493_1496.G * TC_1493_1496.dT; TC_1493_1496.dT = TC_1493_1496.port_a.T - TC_1493_1496.port_b.T; TC_1493_1496.port_a.Q_flow = TC_1493_1496.Q_flow; TC_1493_1496.port_b.Q_flow = -TC_1493_1496.Q_flow; TC_1493_1514.Q_flow = TC_1493_1514.G * TC_1493_1514.dT; TC_1493_1514.dT = TC_1493_1514.port_a.T - TC_1493_1514.port_b.T; TC_1493_1514.port_a.Q_flow = TC_1493_1514.Q_flow; TC_1493_1514.port_b.Q_flow = -TC_1493_1514.Q_flow; TC_1494_1495.Q_flow = TC_1494_1495.G * TC_1494_1495.dT; TC_1494_1495.dT = TC_1494_1495.port_a.T - TC_1494_1495.port_b.T; TC_1494_1495.port_a.Q_flow = TC_1494_1495.Q_flow; TC_1494_1495.port_b.Q_flow = -TC_1494_1495.Q_flow; TC_1494_1515.Q_flow = TC_1494_1515.G * TC_1494_1515.dT; TC_1494_1515.dT = TC_1494_1515.port_a.T - TC_1494_1515.port_b.T; TC_1494_1515.port_a.Q_flow = TC_1494_1515.Q_flow; TC_1494_1515.port_b.Q_flow = -TC_1494_1515.Q_flow; TC_1495_1496.Q_flow = TC_1495_1496.G * TC_1495_1496.dT; TC_1495_1496.dT = TC_1495_1496.port_a.T - TC_1495_1496.port_b.T; TC_1495_1496.port_a.Q_flow = TC_1495_1496.Q_flow; TC_1495_1496.port_b.Q_flow = -TC_1495_1496.Q_flow; TC_1495_1516.Q_flow = TC_1495_1516.G * TC_1495_1516.dT; TC_1495_1516.dT = TC_1495_1516.port_a.T - TC_1495_1516.port_b.T; TC_1495_1516.port_a.Q_flow = TC_1495_1516.Q_flow; TC_1495_1516.port_b.Q_flow = -TC_1495_1516.Q_flow; TC_1496_1517.Q_flow = TC_1496_1517.G * TC_1496_1517.dT; TC_1496_1517.dT = TC_1496_1517.port_a.T - TC_1496_1517.port_b.T; TC_1496_1517.port_a.Q_flow = TC_1496_1517.Q_flow; TC_1496_1517.port_b.Q_flow = -TC_1496_1517.Q_flow; TC_1497_1498.Q_flow = TC_1497_1498.G * TC_1497_1498.dT; TC_1497_1498.dT = TC_1497_1498.port_a.T - TC_1497_1498.port_b.T; TC_1497_1498.port_a.Q_flow = TC_1497_1498.Q_flow; TC_1497_1498.port_b.Q_flow = -TC_1497_1498.Q_flow; TC_1497_1501.Q_flow = TC_1497_1501.G * TC_1497_1501.dT; TC_1497_1501.dT = TC_1497_1501.port_a.T - TC_1497_1501.port_b.T; TC_1497_1501.port_a.Q_flow = TC_1497_1501.Q_flow; TC_1497_1501.port_b.Q_flow = -TC_1497_1501.Q_flow; TC_1497_1618.Q_flow = TC_1497_1618.G * TC_1497_1618.dT; TC_1497_1618.dT = TC_1497_1618.port_a.T - TC_1497_1618.port_b.T; TC_1497_1618.port_a.Q_flow = TC_1497_1618.Q_flow; TC_1497_1618.port_b.Q_flow = -TC_1497_1618.Q_flow; TC_1498_1499.Q_flow = TC_1498_1499.G * TC_1498_1499.dT; TC_1498_1499.dT = TC_1498_1499.port_a.T - TC_1498_1499.port_b.T; TC_1498_1499.port_a.Q_flow = TC_1498_1499.Q_flow; TC_1498_1499.port_b.Q_flow = -TC_1498_1499.Q_flow; TC_1498_1502.Q_flow = TC_1498_1502.G * TC_1498_1502.dT; TC_1498_1502.dT = TC_1498_1502.port_a.T - TC_1498_1502.port_b.T; TC_1498_1502.port_a.Q_flow = TC_1498_1502.Q_flow; TC_1498_1502.port_b.Q_flow = -TC_1498_1502.Q_flow; TC_1498_1619.Q_flow = TC_1498_1619.G * TC_1498_1619.dT; TC_1498_1619.dT = TC_1498_1619.port_a.T - TC_1498_1619.port_b.T; TC_1498_1619.port_a.Q_flow = TC_1498_1619.Q_flow; TC_1498_1619.port_b.Q_flow = -TC_1498_1619.Q_flow; TC_1499_1500.Q_flow = TC_1499_1500.G * TC_1499_1500.dT; TC_1499_1500.dT = TC_1499_1500.port_a.T - TC_1499_1500.port_b.T; TC_1499_1500.port_a.Q_flow = TC_1499_1500.Q_flow; TC_1499_1500.port_b.Q_flow = -TC_1499_1500.Q_flow; TC_1499_1503.Q_flow = TC_1499_1503.G * TC_1499_1503.dT; TC_1499_1503.dT = TC_1499_1503.port_a.T - TC_1499_1503.port_b.T; TC_1499_1503.port_a.Q_flow = TC_1499_1503.Q_flow; TC_1499_1503.port_b.Q_flow = -TC_1499_1503.Q_flow; TC_1499_1620.Q_flow = TC_1499_1620.G * TC_1499_1620.dT; TC_1499_1620.dT = TC_1499_1620.port_a.T - TC_1499_1620.port_b.T; TC_1499_1620.port_a.Q_flow = TC_1499_1620.Q_flow; TC_1499_1620.port_b.Q_flow = -TC_1499_1620.Q_flow; TC_1500_1504.Q_flow = TC_1500_1504.G * TC_1500_1504.dT; TC_1500_1504.dT = TC_1500_1504.port_a.T - TC_1500_1504.port_b.T; TC_1500_1504.port_a.Q_flow = TC_1500_1504.Q_flow; TC_1500_1504.port_b.Q_flow = -TC_1500_1504.Q_flow; TC_1500_1621.Q_flow = TC_1500_1621.G * TC_1500_1621.dT; TC_1500_1621.dT = TC_1500_1621.port_a.T - TC_1500_1621.port_b.T; TC_1500_1621.port_a.Q_flow = TC_1500_1621.Q_flow; TC_1500_1621.port_b.Q_flow = -TC_1500_1621.Q_flow; TC_1501_1502.Q_flow = TC_1501_1502.G * TC_1501_1502.dT; TC_1501_1502.dT = TC_1501_1502.port_a.T - TC_1501_1502.port_b.T; TC_1501_1502.port_a.Q_flow = TC_1501_1502.Q_flow; TC_1501_1502.port_b.Q_flow = -TC_1501_1502.Q_flow; TC_1501_1505.Q_flow = TC_1501_1505.G * TC_1501_1505.dT; TC_1501_1505.dT = TC_1501_1505.port_a.T - TC_1501_1505.port_b.T; TC_1501_1505.port_a.Q_flow = TC_1501_1505.Q_flow; TC_1501_1505.port_b.Q_flow = -TC_1501_1505.Q_flow; TC_1501_1627.Q_flow = TC_1501_1627.G * TC_1501_1627.dT; TC_1501_1627.dT = TC_1501_1627.port_a.T - TC_1501_1627.port_b.T; TC_1501_1627.port_a.Q_flow = TC_1501_1627.Q_flow; TC_1501_1627.port_b.Q_flow = -TC_1501_1627.Q_flow; TC_1502_1503.Q_flow = TC_1502_1503.G * TC_1502_1503.dT; TC_1502_1503.dT = TC_1502_1503.port_a.T - TC_1502_1503.port_b.T; TC_1502_1503.port_a.Q_flow = TC_1502_1503.Q_flow; TC_1502_1503.port_b.Q_flow = -TC_1502_1503.Q_flow; TC_1502_1506.Q_flow = TC_1502_1506.G * TC_1502_1506.dT; TC_1502_1506.dT = TC_1502_1506.port_a.T - TC_1502_1506.port_b.T; TC_1502_1506.port_a.Q_flow = TC_1502_1506.Q_flow; TC_1502_1506.port_b.Q_flow = -TC_1502_1506.Q_flow; TC_1502_1628.Q_flow = TC_1502_1628.G * TC_1502_1628.dT; TC_1502_1628.dT = TC_1502_1628.port_a.T - TC_1502_1628.port_b.T; TC_1502_1628.port_a.Q_flow = TC_1502_1628.Q_flow; TC_1502_1628.port_b.Q_flow = -TC_1502_1628.Q_flow; TC_1503_1504.Q_flow = TC_1503_1504.G * TC_1503_1504.dT; TC_1503_1504.dT = TC_1503_1504.port_a.T - TC_1503_1504.port_b.T; TC_1503_1504.port_a.Q_flow = TC_1503_1504.Q_flow; TC_1503_1504.port_b.Q_flow = -TC_1503_1504.Q_flow; TC_1503_1507.Q_flow = TC_1503_1507.G * TC_1503_1507.dT; TC_1503_1507.dT = TC_1503_1507.port_a.T - TC_1503_1507.port_b.T; TC_1503_1507.port_a.Q_flow = TC_1503_1507.Q_flow; TC_1503_1507.port_b.Q_flow = -TC_1503_1507.Q_flow; TC_1503_1629.Q_flow = TC_1503_1629.G * TC_1503_1629.dT; TC_1503_1629.dT = TC_1503_1629.port_a.T - TC_1503_1629.port_b.T; TC_1503_1629.port_a.Q_flow = TC_1503_1629.Q_flow; TC_1503_1629.port_b.Q_flow = -TC_1503_1629.Q_flow; TC_1504_1508.Q_flow = TC_1504_1508.G * TC_1504_1508.dT; TC_1504_1508.dT = TC_1504_1508.port_a.T - TC_1504_1508.port_b.T; TC_1504_1508.port_a.Q_flow = TC_1504_1508.Q_flow; TC_1504_1508.port_b.Q_flow = -TC_1504_1508.Q_flow; TC_1504_1630.Q_flow = TC_1504_1630.G * TC_1504_1630.dT; TC_1504_1630.dT = TC_1504_1630.port_a.T - TC_1504_1630.port_b.T; TC_1504_1630.port_a.Q_flow = TC_1504_1630.Q_flow; TC_1504_1630.port_b.Q_flow = -TC_1504_1630.Q_flow; TC_1505_1506.Q_flow = TC_1505_1506.G * TC_1505_1506.dT; TC_1505_1506.dT = TC_1505_1506.port_a.T - TC_1505_1506.port_b.T; TC_1505_1506.port_a.Q_flow = TC_1505_1506.Q_flow; TC_1505_1506.port_b.Q_flow = -TC_1505_1506.Q_flow; TC_1505_1564.Q_flow = TC_1505_1564.G * TC_1505_1564.dT; TC_1505_1564.dT = TC_1505_1564.port_a.T - TC_1505_1564.port_b.T; TC_1505_1564.port_a.Q_flow = TC_1505_1564.Q_flow; TC_1505_1564.port_b.Q_flow = -TC_1505_1564.Q_flow; TC_1506_1507.Q_flow = TC_1506_1507.G * TC_1506_1507.dT; TC_1506_1507.dT = TC_1506_1507.port_a.T - TC_1506_1507.port_b.T; TC_1506_1507.port_a.Q_flow = TC_1506_1507.Q_flow; TC_1506_1507.port_b.Q_flow = -TC_1506_1507.Q_flow; TC_1506_1565.Q_flow = TC_1506_1565.G * TC_1506_1565.dT; TC_1506_1565.dT = TC_1506_1565.port_a.T - TC_1506_1565.port_b.T; TC_1506_1565.port_a.Q_flow = TC_1506_1565.Q_flow; TC_1506_1565.port_b.Q_flow = -TC_1506_1565.Q_flow; TC_1507_1508.Q_flow = TC_1507_1508.G * TC_1507_1508.dT; TC_1507_1508.dT = TC_1507_1508.port_a.T - TC_1507_1508.port_b.T; TC_1507_1508.port_a.Q_flow = TC_1507_1508.Q_flow; TC_1507_1508.port_b.Q_flow = -TC_1507_1508.Q_flow; TC_1507_1566.Q_flow = TC_1507_1566.G * TC_1507_1566.dT; TC_1507_1566.dT = TC_1507_1566.port_a.T - TC_1507_1566.port_b.T; TC_1507_1566.port_a.Q_flow = TC_1507_1566.Q_flow; TC_1507_1566.port_b.Q_flow = -TC_1507_1566.Q_flow; TC_1508_1567.Q_flow = TC_1508_1567.G * TC_1508_1567.dT; TC_1508_1567.dT = TC_1508_1567.port_a.T - TC_1508_1567.port_b.T; TC_1508_1567.port_a.Q_flow = TC_1508_1567.Q_flow; TC_1508_1567.port_b.Q_flow = -TC_1508_1567.Q_flow; TC_1509_1510.Q_flow = TC_1509_1510.G * TC_1509_1510.dT; TC_1509_1510.dT = TC_1509_1510.port_a.T - TC_1509_1510.port_b.T; TC_1509_1510.port_a.Q_flow = TC_1509_1510.Q_flow; TC_1509_1510.port_b.Q_flow = -TC_1509_1510.Q_flow; TC_1509_1512.Q_flow = TC_1509_1512.G * TC_1509_1512.dT; TC_1509_1512.dT = TC_1509_1512.port_a.T - TC_1509_1512.port_b.T; TC_1509_1512.port_a.Q_flow = TC_1509_1512.Q_flow; TC_1509_1512.port_b.Q_flow = -TC_1509_1512.Q_flow; TC_1509_1586.Q_flow = TC_1509_1586.G * TC_1509_1586.dT; TC_1509_1586.dT = TC_1509_1586.port_a.T - TC_1509_1586.port_b.T; TC_1509_1586.port_a.Q_flow = TC_1509_1586.Q_flow; TC_1509_1586.port_b.Q_flow = -TC_1509_1586.Q_flow; TC_1510_1511.Q_flow = TC_1510_1511.G * TC_1510_1511.dT; TC_1510_1511.dT = TC_1510_1511.port_a.T - TC_1510_1511.port_b.T; TC_1510_1511.port_a.Q_flow = TC_1510_1511.Q_flow; TC_1510_1511.port_b.Q_flow = -TC_1510_1511.Q_flow; TC_1510_1513.Q_flow = TC_1510_1513.G * TC_1510_1513.dT; TC_1510_1513.dT = TC_1510_1513.port_a.T - TC_1510_1513.port_b.T; TC_1510_1513.port_a.Q_flow = TC_1510_1513.Q_flow; TC_1510_1513.port_b.Q_flow = -TC_1510_1513.Q_flow; TC_1510_1587.Q_flow = TC_1510_1587.G * TC_1510_1587.dT; TC_1510_1587.dT = TC_1510_1587.port_a.T - TC_1510_1587.port_b.T; TC_1510_1587.port_a.Q_flow = TC_1510_1587.Q_flow; TC_1510_1587.port_b.Q_flow = -TC_1510_1587.Q_flow; TC_1511_1514.Q_flow = TC_1511_1514.G * TC_1511_1514.dT; TC_1511_1514.dT = TC_1511_1514.port_a.T - TC_1511_1514.port_b.T; TC_1511_1514.port_a.Q_flow = TC_1511_1514.Q_flow; TC_1511_1514.port_b.Q_flow = -TC_1511_1514.Q_flow; TC_1511_1588.Q_flow = TC_1511_1588.G * TC_1511_1588.dT; TC_1511_1588.dT = TC_1511_1588.port_a.T - TC_1511_1588.port_b.T; TC_1511_1588.port_a.Q_flow = TC_1511_1588.Q_flow; TC_1511_1588.port_b.Q_flow = -TC_1511_1588.Q_flow; TC_1512_1513.Q_flow = TC_1512_1513.G * TC_1512_1513.dT; TC_1512_1513.dT = TC_1512_1513.port_a.T - TC_1512_1513.port_b.T; TC_1512_1513.port_a.Q_flow = TC_1512_1513.Q_flow; TC_1512_1513.port_b.Q_flow = -TC_1512_1513.Q_flow; TC_1512_1515.Q_flow = TC_1512_1515.G * TC_1512_1515.dT; TC_1512_1515.dT = TC_1512_1515.port_a.T - TC_1512_1515.port_b.T; TC_1512_1515.port_a.Q_flow = TC_1512_1515.Q_flow; TC_1512_1515.port_b.Q_flow = -TC_1512_1515.Q_flow; TC_1512_1595.Q_flow = TC_1512_1595.G * TC_1512_1595.dT; TC_1512_1595.dT = TC_1512_1595.port_a.T - TC_1512_1595.port_b.T; TC_1512_1595.port_a.Q_flow = TC_1512_1595.Q_flow; TC_1512_1595.port_b.Q_flow = -TC_1512_1595.Q_flow; TC_1513_1514.Q_flow = TC_1513_1514.G * TC_1513_1514.dT; TC_1513_1514.dT = TC_1513_1514.port_a.T - TC_1513_1514.port_b.T; TC_1513_1514.port_a.Q_flow = TC_1513_1514.Q_flow; TC_1513_1514.port_b.Q_flow = -TC_1513_1514.Q_flow; TC_1513_1516.Q_flow = TC_1513_1516.G * TC_1513_1516.dT; TC_1513_1516.dT = TC_1513_1516.port_a.T - TC_1513_1516.port_b.T; TC_1513_1516.port_a.Q_flow = TC_1513_1516.Q_flow; TC_1513_1516.port_b.Q_flow = -TC_1513_1516.Q_flow; TC_1513_1596.Q_flow = TC_1513_1596.G * TC_1513_1596.dT; TC_1513_1596.dT = TC_1513_1596.port_a.T - TC_1513_1596.port_b.T; TC_1513_1596.port_a.Q_flow = TC_1513_1596.Q_flow; TC_1513_1596.port_b.Q_flow = -TC_1513_1596.Q_flow; TC_1514_1517.Q_flow = TC_1514_1517.G * TC_1514_1517.dT; TC_1514_1517.dT = TC_1514_1517.port_a.T - TC_1514_1517.port_b.T; TC_1514_1517.port_a.Q_flow = TC_1514_1517.Q_flow; TC_1514_1517.port_b.Q_flow = -TC_1514_1517.Q_flow; TC_1514_1597.Q_flow = TC_1514_1597.G * TC_1514_1597.dT; TC_1514_1597.dT = TC_1514_1597.port_a.T - TC_1514_1597.port_b.T; TC_1514_1597.port_a.Q_flow = TC_1514_1597.Q_flow; TC_1514_1597.port_b.Q_flow = -TC_1514_1597.Q_flow; TC_1515_1516.Q_flow = TC_1515_1516.G * TC_1515_1516.dT; TC_1515_1516.dT = TC_1515_1516.port_a.T - TC_1515_1516.port_b.T; TC_1515_1516.port_a.Q_flow = TC_1515_1516.Q_flow; TC_1515_1516.port_b.Q_flow = -TC_1515_1516.Q_flow; TC_1515_1604.Q_flow = TC_1515_1604.G * TC_1515_1604.dT; TC_1515_1604.dT = TC_1515_1604.port_a.T - TC_1515_1604.port_b.T; TC_1515_1604.port_a.Q_flow = TC_1515_1604.Q_flow; TC_1515_1604.port_b.Q_flow = -TC_1515_1604.Q_flow; TC_1516_1517.Q_flow = TC_1516_1517.G * TC_1516_1517.dT; TC_1516_1517.dT = TC_1516_1517.port_a.T - TC_1516_1517.port_b.T; TC_1516_1517.port_a.Q_flow = TC_1516_1517.Q_flow; TC_1516_1517.port_b.Q_flow = -TC_1516_1517.Q_flow; TC_1516_1605.Q_flow = TC_1516_1605.G * TC_1516_1605.dT; TC_1516_1605.dT = TC_1516_1605.port_a.T - TC_1516_1605.port_b.T; TC_1516_1605.port_a.Q_flow = TC_1516_1605.Q_flow; TC_1516_1605.port_b.Q_flow = -TC_1516_1605.Q_flow; TC_1517_1606.Q_flow = TC_1517_1606.G * TC_1517_1606.dT; TC_1517_1606.dT = TC_1517_1606.port_a.T - TC_1517_1606.port_b.T; TC_1517_1606.port_a.Q_flow = TC_1517_1606.Q_flow; TC_1517_1606.port_b.Q_flow = -TC_1517_1606.Q_flow; TC_1518_1519.Q_flow = TC_1518_1519.G * TC_1518_1519.dT; TC_1518_1519.dT = TC_1518_1519.port_a.T - TC_1518_1519.port_b.T; TC_1518_1519.port_a.Q_flow = TC_1518_1519.Q_flow; TC_1518_1519.port_b.Q_flow = -TC_1518_1519.Q_flow; TC_1518_1521.Q_flow = TC_1518_1521.G * TC_1518_1521.dT; TC_1518_1521.dT = TC_1518_1521.port_a.T - TC_1518_1521.port_b.T; TC_1518_1521.port_a.Q_flow = TC_1518_1521.Q_flow; TC_1518_1521.port_b.Q_flow = -TC_1518_1521.Q_flow; TC_1518_1528.Q_flow = TC_1518_1528.G * TC_1518_1528.dT; TC_1518_1528.dT = TC_1518_1528.port_a.T - TC_1518_1528.port_b.T; TC_1518_1528.port_a.Q_flow = TC_1518_1528.Q_flow; TC_1518_1528.port_b.Q_flow = -TC_1518_1528.Q_flow; TC_1519_1520.Q_flow = TC_1519_1520.G * TC_1519_1520.dT; TC_1519_1520.dT = TC_1519_1520.port_a.T - TC_1519_1520.port_b.T; TC_1519_1520.port_a.Q_flow = TC_1519_1520.Q_flow; TC_1519_1520.port_b.Q_flow = -TC_1519_1520.Q_flow; TC_1519_1522.Q_flow = TC_1519_1522.G * TC_1519_1522.dT; TC_1519_1522.dT = TC_1519_1522.port_a.T - TC_1519_1522.port_b.T; TC_1519_1522.port_a.Q_flow = TC_1519_1522.Q_flow; TC_1519_1522.port_b.Q_flow = -TC_1519_1522.Q_flow; TC_1519_1529.Q_flow = TC_1519_1529.G * TC_1519_1529.dT; TC_1519_1529.dT = TC_1519_1529.port_a.T - TC_1519_1529.port_b.T; TC_1519_1529.port_a.Q_flow = TC_1519_1529.Q_flow; TC_1519_1529.port_b.Q_flow = -TC_1519_1529.Q_flow; TC_1520_1523.Q_flow = TC_1520_1523.G * TC_1520_1523.dT; TC_1520_1523.dT = TC_1520_1523.port_a.T - TC_1520_1523.port_b.T; TC_1520_1523.port_a.Q_flow = TC_1520_1523.Q_flow; TC_1520_1523.port_b.Q_flow = -TC_1520_1523.Q_flow; TC_1520_1530.Q_flow = TC_1520_1530.G * TC_1520_1530.dT; TC_1520_1530.dT = TC_1520_1530.port_a.T - TC_1520_1530.port_b.T; TC_1520_1530.port_a.Q_flow = TC_1520_1530.Q_flow; TC_1520_1530.port_b.Q_flow = -TC_1520_1530.Q_flow; TC_1521_1522.Q_flow = TC_1521_1522.G * TC_1521_1522.dT; TC_1521_1522.dT = TC_1521_1522.port_a.T - TC_1521_1522.port_b.T; TC_1521_1522.port_a.Q_flow = TC_1521_1522.Q_flow; TC_1521_1522.port_b.Q_flow = -TC_1521_1522.Q_flow; TC_1521_1524.Q_flow = TC_1521_1524.G * TC_1521_1524.dT; TC_1521_1524.dT = TC_1521_1524.port_a.T - TC_1521_1524.port_b.T; TC_1521_1524.port_a.Q_flow = TC_1521_1524.Q_flow; TC_1521_1524.port_b.Q_flow = -TC_1521_1524.Q_flow; TC_1521_1537.Q_flow = TC_1521_1537.G * TC_1521_1537.dT; TC_1521_1537.dT = TC_1521_1537.port_a.T - TC_1521_1537.port_b.T; TC_1521_1537.port_a.Q_flow = TC_1521_1537.Q_flow; TC_1521_1537.port_b.Q_flow = -TC_1521_1537.Q_flow; TC_1522_1523.Q_flow = TC_1522_1523.G * TC_1522_1523.dT; TC_1522_1523.dT = TC_1522_1523.port_a.T - TC_1522_1523.port_b.T; TC_1522_1523.port_a.Q_flow = TC_1522_1523.Q_flow; TC_1522_1523.port_b.Q_flow = -TC_1522_1523.Q_flow; TC_1522_1525.Q_flow = TC_1522_1525.G * TC_1522_1525.dT; TC_1522_1525.dT = TC_1522_1525.port_a.T - TC_1522_1525.port_b.T; TC_1522_1525.port_a.Q_flow = TC_1522_1525.Q_flow; TC_1522_1525.port_b.Q_flow = -TC_1522_1525.Q_flow; TC_1522_1538.Q_flow = TC_1522_1538.G * TC_1522_1538.dT; TC_1522_1538.dT = TC_1522_1538.port_a.T - TC_1522_1538.port_b.T; TC_1522_1538.port_a.Q_flow = TC_1522_1538.Q_flow; TC_1522_1538.port_b.Q_flow = -TC_1522_1538.Q_flow; TC_1523_1526.Q_flow = TC_1523_1526.G * TC_1523_1526.dT; TC_1523_1526.dT = TC_1523_1526.port_a.T - TC_1523_1526.port_b.T; TC_1523_1526.port_a.Q_flow = TC_1523_1526.Q_flow; TC_1523_1526.port_b.Q_flow = -TC_1523_1526.Q_flow; TC_1523_1539.Q_flow = TC_1523_1539.G * TC_1523_1539.dT; TC_1523_1539.dT = TC_1523_1539.port_a.T - TC_1523_1539.port_b.T; TC_1523_1539.port_a.Q_flow = TC_1523_1539.Q_flow; TC_1523_1539.port_b.Q_flow = -TC_1523_1539.Q_flow; TC_1524_1525.Q_flow = TC_1524_1525.G * TC_1524_1525.dT; TC_1524_1525.dT = TC_1524_1525.port_a.T - TC_1524_1525.port_b.T; TC_1524_1525.port_a.Q_flow = TC_1524_1525.Q_flow; TC_1524_1525.port_b.Q_flow = -TC_1524_1525.Q_flow; TC_1524_1546.Q_flow = TC_1524_1546.G * TC_1524_1546.dT; TC_1524_1546.dT = TC_1524_1546.port_a.T - TC_1524_1546.port_b.T; TC_1524_1546.port_a.Q_flow = TC_1524_1546.Q_flow; TC_1524_1546.port_b.Q_flow = -TC_1524_1546.Q_flow; TC_1525_1526.Q_flow = TC_1525_1526.G * TC_1525_1526.dT; TC_1525_1526.dT = TC_1525_1526.port_a.T - TC_1525_1526.port_b.T; TC_1525_1526.port_a.Q_flow = TC_1525_1526.Q_flow; TC_1525_1526.port_b.Q_flow = -TC_1525_1526.Q_flow; TC_1525_1547.Q_flow = TC_1525_1547.G * TC_1525_1547.dT; TC_1525_1547.dT = TC_1525_1547.port_a.T - TC_1525_1547.port_b.T; TC_1525_1547.port_a.Q_flow = TC_1525_1547.Q_flow; TC_1525_1547.port_b.Q_flow = -TC_1525_1547.Q_flow; TC_1526_1548.Q_flow = TC_1526_1548.G * TC_1526_1548.dT; TC_1526_1548.dT = TC_1526_1548.port_a.T - TC_1526_1548.port_b.T; TC_1526_1548.port_a.Q_flow = TC_1526_1548.Q_flow; TC_1526_1548.port_b.Q_flow = -TC_1526_1548.Q_flow; TC_1527_1528.Q_flow = TC_1527_1528.G * TC_1527_1528.dT; TC_1527_1528.dT = TC_1527_1528.port_a.T - TC_1527_1528.port_b.T; TC_1527_1528.port_a.Q_flow = TC_1527_1528.Q_flow; TC_1527_1528.port_b.Q_flow = -TC_1527_1528.Q_flow; TC_1527_1536.Q_flow = TC_1527_1536.G * TC_1527_1536.dT; TC_1527_1536.dT = TC_1527_1536.port_a.T - TC_1527_1536.port_b.T; TC_1527_1536.port_a.Q_flow = TC_1527_1536.Q_flow; TC_1527_1536.port_b.Q_flow = -TC_1527_1536.Q_flow; TC_1527_1599.Q_flow = TC_1527_1599.G * TC_1527_1599.dT; TC_1527_1599.dT = TC_1527_1599.port_a.T - TC_1527_1599.port_b.T; TC_1527_1599.port_a.Q_flow = TC_1527_1599.Q_flow; TC_1527_1599.port_b.Q_flow = -TC_1527_1599.Q_flow; TC_1528_1529.Q_flow = TC_1528_1529.G * TC_1528_1529.dT; TC_1528_1529.dT = TC_1528_1529.port_a.T - TC_1528_1529.port_b.T; TC_1528_1529.port_a.Q_flow = TC_1528_1529.Q_flow; TC_1528_1529.port_b.Q_flow = -TC_1528_1529.Q_flow; TC_1528_1537.Q_flow = TC_1528_1537.G * TC_1528_1537.dT; TC_1528_1537.dT = TC_1528_1537.port_a.T - TC_1528_1537.port_b.T; TC_1528_1537.port_a.Q_flow = TC_1528_1537.Q_flow; TC_1528_1537.port_b.Q_flow = -TC_1528_1537.Q_flow; TC_1528_1600.Q_flow = TC_1528_1600.G * TC_1528_1600.dT; TC_1528_1600.dT = TC_1528_1600.port_a.T - TC_1528_1600.port_b.T; TC_1528_1600.port_a.Q_flow = TC_1528_1600.Q_flow; TC_1528_1600.port_b.Q_flow = -TC_1528_1600.Q_flow; TC_1528_1656.Q_flow = TC_1528_1656.G * TC_1528_1656.dT; TC_1528_1656.dT = TC_1528_1656.port_a.T - TC_1528_1656.port_b.T; TC_1528_1656.port_a.Q_flow = TC_1528_1656.Q_flow; TC_1528_1656.port_b.Q_flow = -TC_1528_1656.Q_flow; TC_1529_1530.Q_flow = TC_1529_1530.G * TC_1529_1530.dT; TC_1529_1530.dT = TC_1529_1530.port_a.T - TC_1529_1530.port_b.T; TC_1529_1530.port_a.Q_flow = TC_1529_1530.Q_flow; TC_1529_1530.port_b.Q_flow = -TC_1529_1530.Q_flow; TC_1529_1538.Q_flow = TC_1529_1538.G * TC_1529_1538.dT; TC_1529_1538.dT = TC_1529_1538.port_a.T - TC_1529_1538.port_b.T; TC_1529_1538.port_a.Q_flow = TC_1529_1538.Q_flow; TC_1529_1538.port_b.Q_flow = -TC_1529_1538.Q_flow; TC_1529_1601.Q_flow = TC_1529_1601.G * TC_1529_1601.dT; TC_1529_1601.dT = TC_1529_1601.port_a.T - TC_1529_1601.port_b.T; TC_1529_1601.port_a.Q_flow = TC_1529_1601.Q_flow; TC_1529_1601.port_b.Q_flow = -TC_1529_1601.Q_flow; TC_1529_1657.Q_flow = TC_1529_1657.G * TC_1529_1657.dT; TC_1529_1657.dT = TC_1529_1657.port_a.T - TC_1529_1657.port_b.T; TC_1529_1657.port_a.Q_flow = TC_1529_1657.Q_flow; TC_1529_1657.port_b.Q_flow = -TC_1529_1657.Q_flow; TC_1530_1531.Q_flow = TC_1530_1531.G * TC_1530_1531.dT; TC_1530_1531.dT = TC_1530_1531.port_a.T - TC_1530_1531.port_b.T; TC_1530_1531.port_a.Q_flow = TC_1530_1531.Q_flow; TC_1530_1531.port_b.Q_flow = -TC_1530_1531.Q_flow; TC_1530_1539.Q_flow = TC_1530_1539.G * TC_1530_1539.dT; TC_1530_1539.dT = TC_1530_1539.port_a.T - TC_1530_1539.port_b.T; TC_1530_1539.port_a.Q_flow = TC_1530_1539.Q_flow; TC_1530_1539.port_b.Q_flow = -TC_1530_1539.Q_flow; TC_1530_1602.Q_flow = TC_1530_1602.G * TC_1530_1602.dT; TC_1530_1602.dT = TC_1530_1602.port_a.T - TC_1530_1602.port_b.T; TC_1530_1602.port_a.Q_flow = TC_1530_1602.Q_flow; TC_1530_1602.port_b.Q_flow = -TC_1530_1602.Q_flow; TC_1530_1658.Q_flow = TC_1530_1658.G * TC_1530_1658.dT; TC_1530_1658.dT = TC_1530_1658.port_a.T - TC_1530_1658.port_b.T; TC_1530_1658.port_a.Q_flow = TC_1530_1658.Q_flow; TC_1530_1658.port_b.Q_flow = -TC_1530_1658.Q_flow; TC_1531_1532.Q_flow = TC_1531_1532.G * TC_1531_1532.dT; TC_1531_1532.dT = TC_1531_1532.port_a.T - TC_1531_1532.port_b.T; TC_1531_1532.port_a.Q_flow = TC_1531_1532.Q_flow; TC_1531_1532.port_b.Q_flow = -TC_1531_1532.Q_flow; TC_1531_1540.Q_flow = TC_1531_1540.G * TC_1531_1540.dT; TC_1531_1540.dT = TC_1531_1540.port_a.T - TC_1531_1540.port_b.T; TC_1531_1540.port_a.Q_flow = TC_1531_1540.Q_flow; TC_1531_1540.port_b.Q_flow = -TC_1531_1540.Q_flow; TC_1531_1603.Q_flow = TC_1531_1603.G * TC_1531_1603.dT; TC_1531_1603.dT = TC_1531_1603.port_a.T - TC_1531_1603.port_b.T; TC_1531_1603.port_a.Q_flow = TC_1531_1603.Q_flow; TC_1531_1603.port_b.Q_flow = -TC_1531_1603.Q_flow; TC_1532_1533.Q_flow = TC_1532_1533.G * TC_1532_1533.dT; TC_1532_1533.dT = TC_1532_1533.port_a.T - TC_1532_1533.port_b.T; TC_1532_1533.port_a.Q_flow = TC_1532_1533.Q_flow; TC_1532_1533.port_b.Q_flow = -TC_1532_1533.Q_flow; TC_1532_1541.Q_flow = TC_1532_1541.G * TC_1532_1541.dT; TC_1532_1541.dT = TC_1532_1541.port_a.T - TC_1532_1541.port_b.T; TC_1532_1541.port_a.Q_flow = TC_1532_1541.Q_flow; TC_1532_1541.port_b.Q_flow = -TC_1532_1541.Q_flow; TC_1532_1604.Q_flow = TC_1532_1604.G * TC_1532_1604.dT; TC_1532_1604.dT = TC_1532_1604.port_a.T - TC_1532_1604.port_b.T; TC_1532_1604.port_a.Q_flow = TC_1532_1604.Q_flow; TC_1532_1604.port_b.Q_flow = -TC_1532_1604.Q_flow; TC_1532_1653.Q_flow = TC_1532_1653.G * TC_1532_1653.dT; TC_1532_1653.dT = TC_1532_1653.port_a.T - TC_1532_1653.port_b.T; TC_1532_1653.port_a.Q_flow = TC_1532_1653.Q_flow; TC_1532_1653.port_b.Q_flow = -TC_1532_1653.Q_flow; TC_1533_1534.Q_flow = TC_1533_1534.G * TC_1533_1534.dT; TC_1533_1534.dT = TC_1533_1534.port_a.T - TC_1533_1534.port_b.T; TC_1533_1534.port_a.Q_flow = TC_1533_1534.Q_flow; TC_1533_1534.port_b.Q_flow = -TC_1533_1534.Q_flow; TC_1533_1542.Q_flow = TC_1533_1542.G * TC_1533_1542.dT; TC_1533_1542.dT = TC_1533_1542.port_a.T - TC_1533_1542.port_b.T; TC_1533_1542.port_a.Q_flow = TC_1533_1542.Q_flow; TC_1533_1542.port_b.Q_flow = -TC_1533_1542.Q_flow; TC_1533_1605.Q_flow = TC_1533_1605.G * TC_1533_1605.dT; TC_1533_1605.dT = TC_1533_1605.port_a.T - TC_1533_1605.port_b.T; TC_1533_1605.port_a.Q_flow = TC_1533_1605.Q_flow; TC_1533_1605.port_b.Q_flow = -TC_1533_1605.Q_flow; TC_1533_1654.Q_flow = TC_1533_1654.G * TC_1533_1654.dT; TC_1533_1654.dT = TC_1533_1654.port_a.T - TC_1533_1654.port_b.T; TC_1533_1654.port_a.Q_flow = TC_1533_1654.Q_flow; TC_1533_1654.port_b.Q_flow = -TC_1533_1654.Q_flow; TC_1534_1535.Q_flow = TC_1534_1535.G * TC_1534_1535.dT; TC_1534_1535.dT = TC_1534_1535.port_a.T - TC_1534_1535.port_b.T; TC_1534_1535.port_a.Q_flow = TC_1534_1535.Q_flow; TC_1534_1535.port_b.Q_flow = -TC_1534_1535.Q_flow; TC_1534_1543.Q_flow = TC_1534_1543.G * TC_1534_1543.dT; TC_1534_1543.dT = TC_1534_1543.port_a.T - TC_1534_1543.port_b.T; TC_1534_1543.port_a.Q_flow = TC_1534_1543.Q_flow; TC_1534_1543.port_b.Q_flow = -TC_1534_1543.Q_flow; TC_1534_1606.Q_flow = TC_1534_1606.G * TC_1534_1606.dT; TC_1534_1606.dT = TC_1534_1606.port_a.T - TC_1534_1606.port_b.T; TC_1534_1606.port_a.Q_flow = TC_1534_1606.Q_flow; TC_1534_1606.port_b.Q_flow = -TC_1534_1606.Q_flow; TC_1534_1655.Q_flow = TC_1534_1655.G * TC_1534_1655.dT; TC_1534_1655.dT = TC_1534_1655.port_a.T - TC_1534_1655.port_b.T; TC_1534_1655.port_a.Q_flow = TC_1534_1655.Q_flow; TC_1534_1655.port_b.Q_flow = -TC_1534_1655.Q_flow; TC_1535_1544.Q_flow = TC_1535_1544.G * TC_1535_1544.dT; TC_1535_1544.dT = TC_1535_1544.port_a.T - TC_1535_1544.port_b.T; TC_1535_1544.port_a.Q_flow = TC_1535_1544.Q_flow; TC_1535_1544.port_b.Q_flow = -TC_1535_1544.Q_flow; TC_1535_1607.Q_flow = TC_1535_1607.G * TC_1535_1607.dT; TC_1535_1607.dT = TC_1535_1607.port_a.T - TC_1535_1607.port_b.T; TC_1535_1607.port_a.Q_flow = TC_1535_1607.Q_flow; TC_1535_1607.port_b.Q_flow = -TC_1535_1607.Q_flow; TC_1536_1537.Q_flow = TC_1536_1537.G * TC_1536_1537.dT; TC_1536_1537.dT = TC_1536_1537.port_a.T - TC_1536_1537.port_b.T; TC_1536_1537.port_a.Q_flow = TC_1536_1537.Q_flow; TC_1536_1537.port_b.Q_flow = -TC_1536_1537.Q_flow; TC_1536_1545.Q_flow = TC_1536_1545.G * TC_1536_1545.dT; TC_1536_1545.dT = TC_1536_1545.port_a.T - TC_1536_1545.port_b.T; TC_1536_1545.port_a.Q_flow = TC_1536_1545.Q_flow; TC_1536_1545.port_b.Q_flow = -TC_1536_1545.Q_flow; TC_1537_1538.Q_flow = TC_1537_1538.G * TC_1537_1538.dT; TC_1537_1538.dT = TC_1537_1538.port_a.T - TC_1537_1538.port_b.T; TC_1537_1538.port_a.Q_flow = TC_1537_1538.Q_flow; TC_1537_1538.port_b.Q_flow = -TC_1537_1538.Q_flow; TC_1537_1546.Q_flow = TC_1537_1546.G * TC_1537_1546.dT; TC_1537_1546.dT = TC_1537_1546.port_a.T - TC_1537_1546.port_b.T; TC_1537_1546.port_a.Q_flow = TC_1537_1546.Q_flow; TC_1537_1546.port_b.Q_flow = -TC_1537_1546.Q_flow; TC_1537_1659.Q_flow = TC_1537_1659.G * TC_1537_1659.dT; TC_1537_1659.dT = TC_1537_1659.port_a.T - TC_1537_1659.port_b.T; TC_1537_1659.port_a.Q_flow = TC_1537_1659.Q_flow; TC_1537_1659.port_b.Q_flow = -TC_1537_1659.Q_flow; TC_1538_1539.Q_flow = TC_1538_1539.G * TC_1538_1539.dT; TC_1538_1539.dT = TC_1538_1539.port_a.T - TC_1538_1539.port_b.T; TC_1538_1539.port_a.Q_flow = TC_1538_1539.Q_flow; TC_1538_1539.port_b.Q_flow = -TC_1538_1539.Q_flow; TC_1538_1547.Q_flow = TC_1538_1547.G * TC_1538_1547.dT; TC_1538_1547.dT = TC_1538_1547.port_a.T - TC_1538_1547.port_b.T; TC_1538_1547.port_a.Q_flow = TC_1538_1547.Q_flow; TC_1538_1547.port_b.Q_flow = -TC_1538_1547.Q_flow; TC_1538_1660.Q_flow = TC_1538_1660.G * TC_1538_1660.dT; TC_1538_1660.dT = TC_1538_1660.port_a.T - TC_1538_1660.port_b.T; TC_1538_1660.port_a.Q_flow = TC_1538_1660.Q_flow; TC_1538_1660.port_b.Q_flow = -TC_1538_1660.Q_flow; TC_1539_1540.Q_flow = TC_1539_1540.G * TC_1539_1540.dT; TC_1539_1540.dT = TC_1539_1540.port_a.T - TC_1539_1540.port_b.T; TC_1539_1540.port_a.Q_flow = TC_1539_1540.Q_flow; TC_1539_1540.port_b.Q_flow = -TC_1539_1540.Q_flow; TC_1539_1548.Q_flow = TC_1539_1548.G * TC_1539_1548.dT; TC_1539_1548.dT = TC_1539_1548.port_a.T - TC_1539_1548.port_b.T; TC_1539_1548.port_a.Q_flow = TC_1539_1548.Q_flow; TC_1539_1548.port_b.Q_flow = -TC_1539_1548.Q_flow; TC_1539_1661.Q_flow = TC_1539_1661.G * TC_1539_1661.dT; TC_1539_1661.dT = TC_1539_1661.port_a.T - TC_1539_1661.port_b.T; TC_1539_1661.port_a.Q_flow = TC_1539_1661.Q_flow; TC_1539_1661.port_b.Q_flow = -TC_1539_1661.Q_flow; TC_1540_1541.Q_flow = TC_1540_1541.G * TC_1540_1541.dT; TC_1540_1541.dT = TC_1540_1541.port_a.T - TC_1540_1541.port_b.T; TC_1540_1541.port_a.Q_flow = TC_1540_1541.Q_flow; TC_1540_1541.port_b.Q_flow = -TC_1540_1541.Q_flow; TC_1540_1549.Q_flow = TC_1540_1549.G * TC_1540_1549.dT; TC_1540_1549.dT = TC_1540_1549.port_a.T - TC_1540_1549.port_b.T; TC_1540_1549.port_a.Q_flow = TC_1540_1549.Q_flow; TC_1540_1549.port_b.Q_flow = -TC_1540_1549.Q_flow; TC_1541_1542.Q_flow = TC_1541_1542.G * TC_1541_1542.dT; TC_1541_1542.dT = TC_1541_1542.port_a.T - TC_1541_1542.port_b.T; TC_1541_1542.port_a.Q_flow = TC_1541_1542.Q_flow; TC_1541_1542.port_b.Q_flow = -TC_1541_1542.Q_flow; TC_1541_1550.Q_flow = TC_1541_1550.G * TC_1541_1550.dT; TC_1541_1550.dT = TC_1541_1550.port_a.T - TC_1541_1550.port_b.T; TC_1541_1550.port_a.Q_flow = TC_1541_1550.Q_flow; TC_1541_1550.port_b.Q_flow = -TC_1541_1550.Q_flow; TC_1542_1543.Q_flow = TC_1542_1543.G * TC_1542_1543.dT; TC_1542_1543.dT = TC_1542_1543.port_a.T - TC_1542_1543.port_b.T; TC_1542_1543.port_a.Q_flow = TC_1542_1543.Q_flow; TC_1542_1543.port_b.Q_flow = -TC_1542_1543.Q_flow; TC_1542_1551.Q_flow = TC_1542_1551.G * TC_1542_1551.dT; TC_1542_1551.dT = TC_1542_1551.port_a.T - TC_1542_1551.port_b.T; TC_1542_1551.port_a.Q_flow = TC_1542_1551.Q_flow; TC_1542_1551.port_b.Q_flow = -TC_1542_1551.Q_flow; TC_1543_1544.Q_flow = TC_1543_1544.G * TC_1543_1544.dT; TC_1543_1544.dT = TC_1543_1544.port_a.T - TC_1543_1544.port_b.T; TC_1543_1544.port_a.Q_flow = TC_1543_1544.Q_flow; TC_1543_1544.port_b.Q_flow = -TC_1543_1544.Q_flow; TC_1543_1552.Q_flow = TC_1543_1552.G * TC_1543_1552.dT; TC_1543_1552.dT = TC_1543_1552.port_a.T - TC_1543_1552.port_b.T; TC_1543_1552.port_a.Q_flow = TC_1543_1552.Q_flow; TC_1543_1552.port_b.Q_flow = -TC_1543_1552.Q_flow; TC_1544_1553.Q_flow = TC_1544_1553.G * TC_1544_1553.dT; TC_1544_1553.dT = TC_1544_1553.port_a.T - TC_1544_1553.port_b.T; TC_1544_1553.port_a.Q_flow = TC_1544_1553.Q_flow; TC_1544_1553.port_b.Q_flow = -TC_1544_1553.Q_flow; TC_1545_1546.Q_flow = TC_1545_1546.G * TC_1545_1546.dT; TC_1545_1546.dT = TC_1545_1546.port_a.T - TC_1545_1546.port_b.T; TC_1545_1546.port_a.Q_flow = TC_1545_1546.Q_flow; TC_1545_1546.port_b.Q_flow = -TC_1545_1546.Q_flow; TC_1545_1554.Q_flow = TC_1545_1554.G * TC_1545_1554.dT; TC_1545_1554.dT = TC_1545_1554.port_a.T - TC_1545_1554.port_b.T; TC_1545_1554.port_a.Q_flow = TC_1545_1554.Q_flow; TC_1545_1554.port_b.Q_flow = -TC_1545_1554.Q_flow; TC_1546_1547.Q_flow = TC_1546_1547.G * TC_1546_1547.dT; TC_1546_1547.dT = TC_1546_1547.port_a.T - TC_1546_1547.port_b.T; TC_1546_1547.port_a.Q_flow = TC_1546_1547.Q_flow; TC_1546_1547.port_b.Q_flow = -TC_1546_1547.Q_flow; TC_1546_1555.Q_flow = TC_1546_1555.G * TC_1546_1555.dT; TC_1546_1555.dT = TC_1546_1555.port_a.T - TC_1546_1555.port_b.T; TC_1546_1555.port_a.Q_flow = TC_1546_1555.Q_flow; TC_1546_1555.port_b.Q_flow = -TC_1546_1555.Q_flow; TC_1546_1662.Q_flow = TC_1546_1662.G * TC_1546_1662.dT; TC_1546_1662.dT = TC_1546_1662.port_a.T - TC_1546_1662.port_b.T; TC_1546_1662.port_a.Q_flow = TC_1546_1662.Q_flow; TC_1546_1662.port_b.Q_flow = -TC_1546_1662.Q_flow; TC_1547_1548.Q_flow = TC_1547_1548.G * TC_1547_1548.dT; TC_1547_1548.dT = TC_1547_1548.port_a.T - TC_1547_1548.port_b.T; TC_1547_1548.port_a.Q_flow = TC_1547_1548.Q_flow; TC_1547_1548.port_b.Q_flow = -TC_1547_1548.Q_flow; TC_1547_1556.Q_flow = TC_1547_1556.G * TC_1547_1556.dT; TC_1547_1556.dT = TC_1547_1556.port_a.T - TC_1547_1556.port_b.T; TC_1547_1556.port_a.Q_flow = TC_1547_1556.Q_flow; TC_1547_1556.port_b.Q_flow = -TC_1547_1556.Q_flow; TC_1547_1663.Q_flow = TC_1547_1663.G * TC_1547_1663.dT; TC_1547_1663.dT = TC_1547_1663.port_a.T - TC_1547_1663.port_b.T; TC_1547_1663.port_a.Q_flow = TC_1547_1663.Q_flow; TC_1547_1663.port_b.Q_flow = -TC_1547_1663.Q_flow; TC_1548_1549.Q_flow = TC_1548_1549.G * TC_1548_1549.dT; TC_1548_1549.dT = TC_1548_1549.port_a.T - TC_1548_1549.port_b.T; TC_1548_1549.port_a.Q_flow = TC_1548_1549.Q_flow; TC_1548_1549.port_b.Q_flow = -TC_1548_1549.Q_flow; TC_1548_1557.Q_flow = TC_1548_1557.G * TC_1548_1557.dT; TC_1548_1557.dT = TC_1548_1557.port_a.T - TC_1548_1557.port_b.T; TC_1548_1557.port_a.Q_flow = TC_1548_1557.Q_flow; TC_1548_1557.port_b.Q_flow = -TC_1548_1557.Q_flow; TC_1548_1664.Q_flow = TC_1548_1664.G * TC_1548_1664.dT; TC_1548_1664.dT = TC_1548_1664.port_a.T - TC_1548_1664.port_b.T; TC_1548_1664.port_a.Q_flow = TC_1548_1664.Q_flow; TC_1548_1664.port_b.Q_flow = -TC_1548_1664.Q_flow; TC_1549_1550.Q_flow = TC_1549_1550.G * TC_1549_1550.dT; TC_1549_1550.dT = TC_1549_1550.port_a.T - TC_1549_1550.port_b.T; TC_1549_1550.port_a.Q_flow = TC_1549_1550.Q_flow; TC_1549_1550.port_b.Q_flow = -TC_1549_1550.Q_flow; TC_1549_1558.Q_flow = TC_1549_1558.G * TC_1549_1558.dT; TC_1549_1558.dT = TC_1549_1558.port_a.T - TC_1549_1558.port_b.T; TC_1549_1558.port_a.Q_flow = TC_1549_1558.Q_flow; TC_1549_1558.port_b.Q_flow = -TC_1549_1558.Q_flow; TC_1550_1551.Q_flow = TC_1550_1551.G * TC_1550_1551.dT; TC_1550_1551.dT = TC_1550_1551.port_a.T - TC_1550_1551.port_b.T; TC_1550_1551.port_a.Q_flow = TC_1550_1551.Q_flow; TC_1550_1551.port_b.Q_flow = -TC_1550_1551.Q_flow; TC_1550_1559.Q_flow = TC_1550_1559.G * TC_1550_1559.dT; TC_1550_1559.dT = TC_1550_1559.port_a.T - TC_1550_1559.port_b.T; TC_1550_1559.port_a.Q_flow = TC_1550_1559.Q_flow; TC_1550_1559.port_b.Q_flow = -TC_1550_1559.Q_flow; TC_1551_1552.Q_flow = TC_1551_1552.G * TC_1551_1552.dT; TC_1551_1552.dT = TC_1551_1552.port_a.T - TC_1551_1552.port_b.T; TC_1551_1552.port_a.Q_flow = TC_1551_1552.Q_flow; TC_1551_1552.port_b.Q_flow = -TC_1551_1552.Q_flow; TC_1551_1560.Q_flow = TC_1551_1560.G * TC_1551_1560.dT; TC_1551_1560.dT = TC_1551_1560.port_a.T - TC_1551_1560.port_b.T; TC_1551_1560.port_a.Q_flow = TC_1551_1560.Q_flow; TC_1551_1560.port_b.Q_flow = -TC_1551_1560.Q_flow; TC_1552_1553.Q_flow = TC_1552_1553.G * TC_1552_1553.dT; TC_1552_1553.dT = TC_1552_1553.port_a.T - TC_1552_1553.port_b.T; TC_1552_1553.port_a.Q_flow = TC_1552_1553.Q_flow; TC_1552_1553.port_b.Q_flow = -TC_1552_1553.Q_flow; TC_1552_1561.Q_flow = TC_1552_1561.G * TC_1552_1561.dT; TC_1552_1561.dT = TC_1552_1561.port_a.T - TC_1552_1561.port_b.T; TC_1552_1561.port_a.Q_flow = TC_1552_1561.Q_flow; TC_1552_1561.port_b.Q_flow = -TC_1552_1561.Q_flow; TC_1553_1562.Q_flow = TC_1553_1562.G * TC_1553_1562.dT; TC_1553_1562.dT = TC_1553_1562.port_a.T - TC_1553_1562.port_b.T; TC_1553_1562.port_a.Q_flow = TC_1553_1562.Q_flow; TC_1553_1562.port_b.Q_flow = -TC_1553_1562.Q_flow; TC_1554_1555.Q_flow = TC_1554_1555.G * TC_1554_1555.dT; TC_1554_1555.dT = TC_1554_1555.port_a.T - TC_1554_1555.port_b.T; TC_1554_1555.port_a.Q_flow = TC_1554_1555.Q_flow; TC_1554_1555.port_b.Q_flow = -TC_1554_1555.Q_flow; TC_1555_1556.Q_flow = TC_1555_1556.G * TC_1555_1556.dT; TC_1555_1556.dT = TC_1555_1556.port_a.T - TC_1555_1556.port_b.T; TC_1555_1556.port_a.Q_flow = TC_1555_1556.Q_flow; TC_1555_1556.port_b.Q_flow = -TC_1555_1556.Q_flow; TC_1556_1557.Q_flow = TC_1556_1557.G * TC_1556_1557.dT; TC_1556_1557.dT = TC_1556_1557.port_a.T - TC_1556_1557.port_b.T; TC_1556_1557.port_a.Q_flow = TC_1556_1557.Q_flow; TC_1556_1557.port_b.Q_flow = -TC_1556_1557.Q_flow; TC_1557_1558.Q_flow = TC_1557_1558.G * TC_1557_1558.dT; TC_1557_1558.dT = TC_1557_1558.port_a.T - TC_1557_1558.port_b.T; TC_1557_1558.port_a.Q_flow = TC_1557_1558.Q_flow; TC_1557_1558.port_b.Q_flow = -TC_1557_1558.Q_flow; TC_1558_1559.Q_flow = TC_1558_1559.G * TC_1558_1559.dT; TC_1558_1559.dT = TC_1558_1559.port_a.T - TC_1558_1559.port_b.T; TC_1558_1559.port_a.Q_flow = TC_1558_1559.Q_flow; TC_1558_1559.port_b.Q_flow = -TC_1558_1559.Q_flow; TC_1559_1560.Q_flow = TC_1559_1560.G * TC_1559_1560.dT; TC_1559_1560.dT = TC_1559_1560.port_a.T - TC_1559_1560.port_b.T; TC_1559_1560.port_a.Q_flow = TC_1559_1560.Q_flow; TC_1559_1560.port_b.Q_flow = -TC_1559_1560.Q_flow; TC_1560_1561.Q_flow = TC_1560_1561.G * TC_1560_1561.dT; TC_1560_1561.dT = TC_1560_1561.port_a.T - TC_1560_1561.port_b.T; TC_1560_1561.port_a.Q_flow = TC_1560_1561.Q_flow; TC_1560_1561.port_b.Q_flow = -TC_1560_1561.Q_flow; TC_1561_1562.Q_flow = TC_1561_1562.G * TC_1561_1562.dT; TC_1561_1562.dT = TC_1561_1562.port_a.T - TC_1561_1562.port_b.T; TC_1561_1562.port_a.Q_flow = TC_1561_1562.Q_flow; TC_1561_1562.port_b.Q_flow = -TC_1561_1562.Q_flow; TC_1563_1564.Q_flow = TC_1563_1564.G * TC_1563_1564.dT; TC_1563_1564.dT = TC_1563_1564.port_a.T - TC_1563_1564.port_b.T; TC_1563_1564.port_a.Q_flow = TC_1563_1564.Q_flow; TC_1563_1564.port_b.Q_flow = -TC_1563_1564.Q_flow; TC_1563_1572.Q_flow = TC_1563_1572.G * TC_1563_1572.dT; TC_1563_1572.dT = TC_1563_1572.port_a.T - TC_1563_1572.port_b.T; TC_1563_1572.port_a.Q_flow = TC_1563_1572.Q_flow; TC_1563_1572.port_b.Q_flow = -TC_1563_1572.Q_flow; TC_1563_1626.Q_flow = TC_1563_1626.G * TC_1563_1626.dT; TC_1563_1626.dT = TC_1563_1626.port_a.T - TC_1563_1626.port_b.T; TC_1563_1626.port_a.Q_flow = TC_1563_1626.Q_flow; TC_1563_1626.port_b.Q_flow = -TC_1563_1626.Q_flow; TC_1564_1565.Q_flow = TC_1564_1565.G * TC_1564_1565.dT; TC_1564_1565.dT = TC_1564_1565.port_a.T - TC_1564_1565.port_b.T; TC_1564_1565.port_a.Q_flow = TC_1564_1565.Q_flow; TC_1564_1565.port_b.Q_flow = -TC_1564_1565.Q_flow; TC_1564_1573.Q_flow = TC_1564_1573.G * TC_1564_1573.dT; TC_1564_1573.dT = TC_1564_1573.port_a.T - TC_1564_1573.port_b.T; TC_1564_1573.port_a.Q_flow = TC_1564_1573.Q_flow; TC_1564_1573.port_b.Q_flow = -TC_1564_1573.Q_flow; TC_1564_1627.Q_flow = TC_1564_1627.G * TC_1564_1627.dT; TC_1564_1627.dT = TC_1564_1627.port_a.T - TC_1564_1627.port_b.T; TC_1564_1627.port_a.Q_flow = TC_1564_1627.Q_flow; TC_1564_1627.port_b.Q_flow = -TC_1564_1627.Q_flow; TC_1565_1566.Q_flow = TC_1565_1566.G * TC_1565_1566.dT; TC_1565_1566.dT = TC_1565_1566.port_a.T - TC_1565_1566.port_b.T; TC_1565_1566.port_a.Q_flow = TC_1565_1566.Q_flow; TC_1565_1566.port_b.Q_flow = -TC_1565_1566.Q_flow; TC_1565_1574.Q_flow = TC_1565_1574.G * TC_1565_1574.dT; TC_1565_1574.dT = TC_1565_1574.port_a.T - TC_1565_1574.port_b.T; TC_1565_1574.port_a.Q_flow = TC_1565_1574.Q_flow; TC_1565_1574.port_b.Q_flow = -TC_1565_1574.Q_flow; TC_1565_1628.Q_flow = TC_1565_1628.G * TC_1565_1628.dT; TC_1565_1628.dT = TC_1565_1628.port_a.T - TC_1565_1628.port_b.T; TC_1565_1628.port_a.Q_flow = TC_1565_1628.Q_flow; TC_1565_1628.port_b.Q_flow = -TC_1565_1628.Q_flow; TC_1566_1567.Q_flow = TC_1566_1567.G * TC_1566_1567.dT; TC_1566_1567.dT = TC_1566_1567.port_a.T - TC_1566_1567.port_b.T; TC_1566_1567.port_a.Q_flow = TC_1566_1567.Q_flow; TC_1566_1567.port_b.Q_flow = -TC_1566_1567.Q_flow; TC_1566_1575.Q_flow = TC_1566_1575.G * TC_1566_1575.dT; TC_1566_1575.dT = TC_1566_1575.port_a.T - TC_1566_1575.port_b.T; TC_1566_1575.port_a.Q_flow = TC_1566_1575.Q_flow; TC_1566_1575.port_b.Q_flow = -TC_1566_1575.Q_flow; TC_1566_1629.Q_flow = TC_1566_1629.G * TC_1566_1629.dT; TC_1566_1629.dT = TC_1566_1629.port_a.T - TC_1566_1629.port_b.T; TC_1566_1629.port_a.Q_flow = TC_1566_1629.Q_flow; TC_1566_1629.port_b.Q_flow = -TC_1566_1629.Q_flow; TC_1566_1643.Q_flow = TC_1566_1643.G * TC_1566_1643.dT; TC_1566_1643.dT = TC_1566_1643.port_a.T - TC_1566_1643.port_b.T; TC_1566_1643.port_a.Q_flow = TC_1566_1643.Q_flow; TC_1566_1643.port_b.Q_flow = -TC_1566_1643.Q_flow; TC_1567_1568.Q_flow = TC_1567_1568.G * TC_1567_1568.dT; TC_1567_1568.dT = TC_1567_1568.port_a.T - TC_1567_1568.port_b.T; TC_1567_1568.port_a.Q_flow = TC_1567_1568.Q_flow; TC_1567_1568.port_b.Q_flow = -TC_1567_1568.Q_flow; TC_1567_1576.Q_flow = TC_1567_1576.G * TC_1567_1576.dT; TC_1567_1576.dT = TC_1567_1576.port_a.T - TC_1567_1576.port_b.T; TC_1567_1576.port_a.Q_flow = TC_1567_1576.Q_flow; TC_1567_1576.port_b.Q_flow = -TC_1567_1576.Q_flow; TC_1567_1630.Q_flow = TC_1567_1630.G * TC_1567_1630.dT; TC_1567_1630.dT = TC_1567_1630.port_a.T - TC_1567_1630.port_b.T; TC_1567_1630.port_a.Q_flow = TC_1567_1630.Q_flow; TC_1567_1630.port_b.Q_flow = -TC_1567_1630.Q_flow; TC_1567_1644.Q_flow = TC_1567_1644.G * TC_1567_1644.dT; TC_1567_1644.dT = TC_1567_1644.port_a.T - TC_1567_1644.port_b.T; TC_1567_1644.port_a.Q_flow = TC_1567_1644.Q_flow; TC_1567_1644.port_b.Q_flow = -TC_1567_1644.Q_flow; TC_1568_1569.Q_flow = TC_1568_1569.G * TC_1568_1569.dT; TC_1568_1569.dT = TC_1568_1569.port_a.T - TC_1568_1569.port_b.T; TC_1568_1569.port_a.Q_flow = TC_1568_1569.Q_flow; TC_1568_1569.port_b.Q_flow = -TC_1568_1569.Q_flow; TC_1568_1577.Q_flow = TC_1568_1577.G * TC_1568_1577.dT; TC_1568_1577.dT = TC_1568_1577.port_a.T - TC_1568_1577.port_b.T; TC_1568_1577.port_a.Q_flow = TC_1568_1577.Q_flow; TC_1568_1577.port_b.Q_flow = -TC_1568_1577.Q_flow; TC_1568_1631.Q_flow = TC_1568_1631.G * TC_1568_1631.dT; TC_1568_1631.dT = TC_1568_1631.port_a.T - TC_1568_1631.port_b.T; TC_1568_1631.port_a.Q_flow = TC_1568_1631.Q_flow; TC_1568_1631.port_b.Q_flow = -TC_1568_1631.Q_flow; TC_1568_1645.Q_flow = TC_1568_1645.G * TC_1568_1645.dT; TC_1568_1645.dT = TC_1568_1645.port_a.T - TC_1568_1645.port_b.T; TC_1568_1645.port_a.Q_flow = TC_1568_1645.Q_flow; TC_1568_1645.port_b.Q_flow = -TC_1568_1645.Q_flow; TC_1569_1570.Q_flow = TC_1569_1570.G * TC_1569_1570.dT; TC_1569_1570.dT = TC_1569_1570.port_a.T - TC_1569_1570.port_b.T; TC_1569_1570.port_a.Q_flow = TC_1569_1570.Q_flow; TC_1569_1570.port_b.Q_flow = -TC_1569_1570.Q_flow; TC_1569_1578.Q_flow = TC_1569_1578.G * TC_1569_1578.dT; TC_1569_1578.dT = TC_1569_1578.port_a.T - TC_1569_1578.port_b.T; TC_1569_1578.port_a.Q_flow = TC_1569_1578.Q_flow; TC_1569_1578.port_b.Q_flow = -TC_1569_1578.Q_flow; TC_1569_1632.Q_flow = TC_1569_1632.G * TC_1569_1632.dT; TC_1569_1632.dT = TC_1569_1632.port_a.T - TC_1569_1632.port_b.T; TC_1569_1632.port_a.Q_flow = TC_1569_1632.Q_flow; TC_1569_1632.port_b.Q_flow = -TC_1569_1632.Q_flow; TC_1569_1646.Q_flow = TC_1569_1646.G * TC_1569_1646.dT; TC_1569_1646.dT = TC_1569_1646.port_a.T - TC_1569_1646.port_b.T; TC_1569_1646.port_a.Q_flow = TC_1569_1646.Q_flow; TC_1569_1646.port_b.Q_flow = -TC_1569_1646.Q_flow; TC_1570_1571.Q_flow = TC_1570_1571.G * TC_1570_1571.dT; TC_1570_1571.dT = TC_1570_1571.port_a.T - TC_1570_1571.port_b.T; TC_1570_1571.port_a.Q_flow = TC_1570_1571.Q_flow; TC_1570_1571.port_b.Q_flow = -TC_1570_1571.Q_flow; TC_1570_1579.Q_flow = TC_1570_1579.G * TC_1570_1579.dT; TC_1570_1579.dT = TC_1570_1579.port_a.T - TC_1570_1579.port_b.T; TC_1570_1579.port_a.Q_flow = TC_1570_1579.Q_flow; TC_1570_1579.port_b.Q_flow = -TC_1570_1579.Q_flow; TC_1570_1633.Q_flow = TC_1570_1633.G * TC_1570_1633.dT; TC_1570_1633.dT = TC_1570_1633.port_a.T - TC_1570_1633.port_b.T; TC_1570_1633.port_a.Q_flow = TC_1570_1633.Q_flow; TC_1570_1633.port_b.Q_flow = -TC_1570_1633.Q_flow; TC_1571_1580.Q_flow = TC_1571_1580.G * TC_1571_1580.dT; TC_1571_1580.dT = TC_1571_1580.port_a.T - TC_1571_1580.port_b.T; TC_1571_1580.port_a.Q_flow = TC_1571_1580.Q_flow; TC_1571_1580.port_b.Q_flow = -TC_1571_1580.Q_flow; TC_1571_1634.Q_flow = TC_1571_1634.G * TC_1571_1634.dT; TC_1571_1634.dT = TC_1571_1634.port_a.T - TC_1571_1634.port_b.T; TC_1571_1634.port_a.Q_flow = TC_1571_1634.Q_flow; TC_1571_1634.port_b.Q_flow = -TC_1571_1634.Q_flow; TC_1572_1573.Q_flow = TC_1572_1573.G * TC_1572_1573.dT; TC_1572_1573.dT = TC_1572_1573.port_a.T - TC_1572_1573.port_b.T; TC_1572_1573.port_a.Q_flow = TC_1572_1573.Q_flow; TC_1572_1573.port_b.Q_flow = -TC_1572_1573.Q_flow; TC_1572_1581.Q_flow = TC_1572_1581.G * TC_1572_1581.dT; TC_1572_1581.dT = TC_1572_1581.port_a.T - TC_1572_1581.port_b.T; TC_1572_1581.port_a.Q_flow = TC_1572_1581.Q_flow; TC_1572_1581.port_b.Q_flow = -TC_1572_1581.Q_flow; TC_1573_1574.Q_flow = TC_1573_1574.G * TC_1573_1574.dT; TC_1573_1574.dT = TC_1573_1574.port_a.T - TC_1573_1574.port_b.T; TC_1573_1574.port_a.Q_flow = TC_1573_1574.Q_flow; TC_1573_1574.port_b.Q_flow = -TC_1573_1574.Q_flow; TC_1573_1582.Q_flow = TC_1573_1582.G * TC_1573_1582.dT; TC_1573_1582.dT = TC_1573_1582.port_a.T - TC_1573_1582.port_b.T; TC_1573_1582.port_a.Q_flow = TC_1573_1582.Q_flow; TC_1573_1582.port_b.Q_flow = -TC_1573_1582.Q_flow; TC_1574_1575.Q_flow = TC_1574_1575.G * TC_1574_1575.dT; TC_1574_1575.dT = TC_1574_1575.port_a.T - TC_1574_1575.port_b.T; TC_1574_1575.port_a.Q_flow = TC_1574_1575.Q_flow; TC_1574_1575.port_b.Q_flow = -TC_1574_1575.Q_flow; TC_1574_1583.Q_flow = TC_1574_1583.G * TC_1574_1583.dT; TC_1574_1583.dT = TC_1574_1583.port_a.T - TC_1574_1583.port_b.T; TC_1574_1583.port_a.Q_flow = TC_1574_1583.Q_flow; TC_1574_1583.port_b.Q_flow = -TC_1574_1583.Q_flow; TC_1575_1576.Q_flow = TC_1575_1576.G * TC_1575_1576.dT; TC_1575_1576.dT = TC_1575_1576.port_a.T - TC_1575_1576.port_b.T; TC_1575_1576.port_a.Q_flow = TC_1575_1576.Q_flow; TC_1575_1576.port_b.Q_flow = -TC_1575_1576.Q_flow; TC_1575_1584.Q_flow = TC_1575_1584.G * TC_1575_1584.dT; TC_1575_1584.dT = TC_1575_1584.port_a.T - TC_1575_1584.port_b.T; TC_1575_1584.port_a.Q_flow = TC_1575_1584.Q_flow; TC_1575_1584.port_b.Q_flow = -TC_1575_1584.Q_flow; TC_1576_1577.Q_flow = TC_1576_1577.G * TC_1576_1577.dT; TC_1576_1577.dT = TC_1576_1577.port_a.T - TC_1576_1577.port_b.T; TC_1576_1577.port_a.Q_flow = TC_1576_1577.Q_flow; TC_1576_1577.port_b.Q_flow = -TC_1576_1577.Q_flow; TC_1576_1585.Q_flow = TC_1576_1585.G * TC_1576_1585.dT; TC_1576_1585.dT = TC_1576_1585.port_a.T - TC_1576_1585.port_b.T; TC_1576_1585.port_a.Q_flow = TC_1576_1585.Q_flow; TC_1576_1585.port_b.Q_flow = -TC_1576_1585.Q_flow; TC_1577_1578.Q_flow = TC_1577_1578.G * TC_1577_1578.dT; TC_1577_1578.dT = TC_1577_1578.port_a.T - TC_1577_1578.port_b.T; TC_1577_1578.port_a.Q_flow = TC_1577_1578.Q_flow; TC_1577_1578.port_b.Q_flow = -TC_1577_1578.Q_flow; TC_1577_1586.Q_flow = TC_1577_1586.G * TC_1577_1586.dT; TC_1577_1586.dT = TC_1577_1586.port_a.T - TC_1577_1586.port_b.T; TC_1577_1586.port_a.Q_flow = TC_1577_1586.Q_flow; TC_1577_1586.port_b.Q_flow = -TC_1577_1586.Q_flow; TC_1578_1579.Q_flow = TC_1578_1579.G * TC_1578_1579.dT; TC_1578_1579.dT = TC_1578_1579.port_a.T - TC_1578_1579.port_b.T; TC_1578_1579.port_a.Q_flow = TC_1578_1579.Q_flow; TC_1578_1579.port_b.Q_flow = -TC_1578_1579.Q_flow; TC_1578_1587.Q_flow = TC_1578_1587.G * TC_1578_1587.dT; TC_1578_1587.dT = TC_1578_1587.port_a.T - TC_1578_1587.port_b.T; TC_1578_1587.port_a.Q_flow = TC_1578_1587.Q_flow; TC_1578_1587.port_b.Q_flow = -TC_1578_1587.Q_flow; TC_1579_1580.Q_flow = TC_1579_1580.G * TC_1579_1580.dT; TC_1579_1580.dT = TC_1579_1580.port_a.T - TC_1579_1580.port_b.T; TC_1579_1580.port_a.Q_flow = TC_1579_1580.Q_flow; TC_1579_1580.port_b.Q_flow = -TC_1579_1580.Q_flow; TC_1579_1588.Q_flow = TC_1579_1588.G * TC_1579_1588.dT; TC_1579_1588.dT = TC_1579_1588.port_a.T - TC_1579_1588.port_b.T; TC_1579_1588.port_a.Q_flow = TC_1579_1588.Q_flow; TC_1579_1588.port_b.Q_flow = -TC_1579_1588.Q_flow; TC_1580_1589.Q_flow = TC_1580_1589.G * TC_1580_1589.dT; TC_1580_1589.dT = TC_1580_1589.port_a.T - TC_1580_1589.port_b.T; TC_1580_1589.port_a.Q_flow = TC_1580_1589.Q_flow; TC_1580_1589.port_b.Q_flow = -TC_1580_1589.Q_flow; TC_1581_1582.Q_flow = TC_1581_1582.G * TC_1581_1582.dT; TC_1581_1582.dT = TC_1581_1582.port_a.T - TC_1581_1582.port_b.T; TC_1581_1582.port_a.Q_flow = TC_1581_1582.Q_flow; TC_1581_1582.port_b.Q_flow = -TC_1581_1582.Q_flow; TC_1581_1590.Q_flow = TC_1581_1590.G * TC_1581_1590.dT; TC_1581_1590.dT = TC_1581_1590.port_a.T - TC_1581_1590.port_b.T; TC_1581_1590.port_a.Q_flow = TC_1581_1590.Q_flow; TC_1581_1590.port_b.Q_flow = -TC_1581_1590.Q_flow; TC_1582_1583.Q_flow = TC_1582_1583.G * TC_1582_1583.dT; TC_1582_1583.dT = TC_1582_1583.port_a.T - TC_1582_1583.port_b.T; TC_1582_1583.port_a.Q_flow = TC_1582_1583.Q_flow; TC_1582_1583.port_b.Q_flow = -TC_1582_1583.Q_flow; TC_1582_1591.Q_flow = TC_1582_1591.G * TC_1582_1591.dT; TC_1582_1591.dT = TC_1582_1591.port_a.T - TC_1582_1591.port_b.T; TC_1582_1591.port_a.Q_flow = TC_1582_1591.Q_flow; TC_1582_1591.port_b.Q_flow = -TC_1582_1591.Q_flow; TC_1583_1584.Q_flow = TC_1583_1584.G * TC_1583_1584.dT; TC_1583_1584.dT = TC_1583_1584.port_a.T - TC_1583_1584.port_b.T; TC_1583_1584.port_a.Q_flow = TC_1583_1584.Q_flow; TC_1583_1584.port_b.Q_flow = -TC_1583_1584.Q_flow; TC_1583_1592.Q_flow = TC_1583_1592.G * TC_1583_1592.dT; TC_1583_1592.dT = TC_1583_1592.port_a.T - TC_1583_1592.port_b.T; TC_1583_1592.port_a.Q_flow = TC_1583_1592.Q_flow; TC_1583_1592.port_b.Q_flow = -TC_1583_1592.Q_flow; TC_1584_1585.Q_flow = TC_1584_1585.G * TC_1584_1585.dT; TC_1584_1585.dT = TC_1584_1585.port_a.T - TC_1584_1585.port_b.T; TC_1584_1585.port_a.Q_flow = TC_1584_1585.Q_flow; TC_1584_1585.port_b.Q_flow = -TC_1584_1585.Q_flow; TC_1584_1593.Q_flow = TC_1584_1593.G * TC_1584_1593.dT; TC_1584_1593.dT = TC_1584_1593.port_a.T - TC_1584_1593.port_b.T; TC_1584_1593.port_a.Q_flow = TC_1584_1593.Q_flow; TC_1584_1593.port_b.Q_flow = -TC_1584_1593.Q_flow; TC_1585_1586.Q_flow = TC_1585_1586.G * TC_1585_1586.dT; TC_1585_1586.dT = TC_1585_1586.port_a.T - TC_1585_1586.port_b.T; TC_1585_1586.port_a.Q_flow = TC_1585_1586.Q_flow; TC_1585_1586.port_b.Q_flow = -TC_1585_1586.Q_flow; TC_1585_1594.Q_flow = TC_1585_1594.G * TC_1585_1594.dT; TC_1585_1594.dT = TC_1585_1594.port_a.T - TC_1585_1594.port_b.T; TC_1585_1594.port_a.Q_flow = TC_1585_1594.Q_flow; TC_1585_1594.port_b.Q_flow = -TC_1585_1594.Q_flow; TC_1586_1587.Q_flow = TC_1586_1587.G * TC_1586_1587.dT; TC_1586_1587.dT = TC_1586_1587.port_a.T - TC_1586_1587.port_b.T; TC_1586_1587.port_a.Q_flow = TC_1586_1587.Q_flow; TC_1586_1587.port_b.Q_flow = -TC_1586_1587.Q_flow; TC_1586_1595.Q_flow = TC_1586_1595.G * TC_1586_1595.dT; TC_1586_1595.dT = TC_1586_1595.port_a.T - TC_1586_1595.port_b.T; TC_1586_1595.port_a.Q_flow = TC_1586_1595.Q_flow; TC_1586_1595.port_b.Q_flow = -TC_1586_1595.Q_flow; TC_1587_1588.Q_flow = TC_1587_1588.G * TC_1587_1588.dT; TC_1587_1588.dT = TC_1587_1588.port_a.T - TC_1587_1588.port_b.T; TC_1587_1588.port_a.Q_flow = TC_1587_1588.Q_flow; TC_1587_1588.port_b.Q_flow = -TC_1587_1588.Q_flow; TC_1587_1596.Q_flow = TC_1587_1596.G * TC_1587_1596.dT; TC_1587_1596.dT = TC_1587_1596.port_a.T - TC_1587_1596.port_b.T; TC_1587_1596.port_a.Q_flow = TC_1587_1596.Q_flow; TC_1587_1596.port_b.Q_flow = -TC_1587_1596.Q_flow; TC_1588_1589.Q_flow = TC_1588_1589.G * TC_1588_1589.dT; TC_1588_1589.dT = TC_1588_1589.port_a.T - TC_1588_1589.port_b.T; TC_1588_1589.port_a.Q_flow = TC_1588_1589.Q_flow; TC_1588_1589.port_b.Q_flow = -TC_1588_1589.Q_flow; TC_1588_1597.Q_flow = TC_1588_1597.G * TC_1588_1597.dT; TC_1588_1597.dT = TC_1588_1597.port_a.T - TC_1588_1597.port_b.T; TC_1588_1597.port_a.Q_flow = TC_1588_1597.Q_flow; TC_1588_1597.port_b.Q_flow = -TC_1588_1597.Q_flow; TC_1589_1598.Q_flow = TC_1589_1598.G * TC_1589_1598.dT; TC_1589_1598.dT = TC_1589_1598.port_a.T - TC_1589_1598.port_b.T; TC_1589_1598.port_a.Q_flow = TC_1589_1598.Q_flow; TC_1589_1598.port_b.Q_flow = -TC_1589_1598.Q_flow; TC_1590_1591.Q_flow = TC_1590_1591.G * TC_1590_1591.dT; TC_1590_1591.dT = TC_1590_1591.port_a.T - TC_1590_1591.port_b.T; TC_1590_1591.port_a.Q_flow = TC_1590_1591.Q_flow; TC_1590_1591.port_b.Q_flow = -TC_1590_1591.Q_flow; TC_1590_1599.Q_flow = TC_1590_1599.G * TC_1590_1599.dT; TC_1590_1599.dT = TC_1590_1599.port_a.T - TC_1590_1599.port_b.T; TC_1590_1599.port_a.Q_flow = TC_1590_1599.Q_flow; TC_1590_1599.port_b.Q_flow = -TC_1590_1599.Q_flow; TC_1591_1592.Q_flow = TC_1591_1592.G * TC_1591_1592.dT; TC_1591_1592.dT = TC_1591_1592.port_a.T - TC_1591_1592.port_b.T; TC_1591_1592.port_a.Q_flow = TC_1591_1592.Q_flow; TC_1591_1592.port_b.Q_flow = -TC_1591_1592.Q_flow; TC_1591_1600.Q_flow = TC_1591_1600.G * TC_1591_1600.dT; TC_1591_1600.dT = TC_1591_1600.port_a.T - TC_1591_1600.port_b.T; TC_1591_1600.port_a.Q_flow = TC_1591_1600.Q_flow; TC_1591_1600.port_b.Q_flow = -TC_1591_1600.Q_flow; TC_1592_1593.Q_flow = TC_1592_1593.G * TC_1592_1593.dT; TC_1592_1593.dT = TC_1592_1593.port_a.T - TC_1592_1593.port_b.T; TC_1592_1593.port_a.Q_flow = TC_1592_1593.Q_flow; TC_1592_1593.port_b.Q_flow = -TC_1592_1593.Q_flow; TC_1592_1601.Q_flow = TC_1592_1601.G * TC_1592_1601.dT; TC_1592_1601.dT = TC_1592_1601.port_a.T - TC_1592_1601.port_b.T; TC_1592_1601.port_a.Q_flow = TC_1592_1601.Q_flow; TC_1592_1601.port_b.Q_flow = -TC_1592_1601.Q_flow; TC_1593_1594.Q_flow = TC_1593_1594.G * TC_1593_1594.dT; TC_1593_1594.dT = TC_1593_1594.port_a.T - TC_1593_1594.port_b.T; TC_1593_1594.port_a.Q_flow = TC_1593_1594.Q_flow; TC_1593_1594.port_b.Q_flow = -TC_1593_1594.Q_flow; TC_1593_1602.Q_flow = TC_1593_1602.G * TC_1593_1602.dT; TC_1593_1602.dT = TC_1593_1602.port_a.T - TC_1593_1602.port_b.T; TC_1593_1602.port_a.Q_flow = TC_1593_1602.Q_flow; TC_1593_1602.port_b.Q_flow = -TC_1593_1602.Q_flow; TC_1594_1595.Q_flow = TC_1594_1595.G * TC_1594_1595.dT; TC_1594_1595.dT = TC_1594_1595.port_a.T - TC_1594_1595.port_b.T; TC_1594_1595.port_a.Q_flow = TC_1594_1595.Q_flow; TC_1594_1595.port_b.Q_flow = -TC_1594_1595.Q_flow; TC_1594_1603.Q_flow = TC_1594_1603.G * TC_1594_1603.dT; TC_1594_1603.dT = TC_1594_1603.port_a.T - TC_1594_1603.port_b.T; TC_1594_1603.port_a.Q_flow = TC_1594_1603.Q_flow; TC_1594_1603.port_b.Q_flow = -TC_1594_1603.Q_flow; TC_1595_1596.Q_flow = TC_1595_1596.G * TC_1595_1596.dT; TC_1595_1596.dT = TC_1595_1596.port_a.T - TC_1595_1596.port_b.T; TC_1595_1596.port_a.Q_flow = TC_1595_1596.Q_flow; TC_1595_1596.port_b.Q_flow = -TC_1595_1596.Q_flow; TC_1595_1604.Q_flow = TC_1595_1604.G * TC_1595_1604.dT; TC_1595_1604.dT = TC_1595_1604.port_a.T - TC_1595_1604.port_b.T; TC_1595_1604.port_a.Q_flow = TC_1595_1604.Q_flow; TC_1595_1604.port_b.Q_flow = -TC_1595_1604.Q_flow; TC_1595_1647.Q_flow = TC_1595_1647.G * TC_1595_1647.dT; TC_1595_1647.dT = TC_1595_1647.port_a.T - TC_1595_1647.port_b.T; TC_1595_1647.port_a.Q_flow = TC_1595_1647.Q_flow; TC_1595_1647.port_b.Q_flow = -TC_1595_1647.Q_flow; TC_1596_1597.Q_flow = TC_1596_1597.G * TC_1596_1597.dT; TC_1596_1597.dT = TC_1596_1597.port_a.T - TC_1596_1597.port_b.T; TC_1596_1597.port_a.Q_flow = TC_1596_1597.Q_flow; TC_1596_1597.port_b.Q_flow = -TC_1596_1597.Q_flow; TC_1596_1605.Q_flow = TC_1596_1605.G * TC_1596_1605.dT; TC_1596_1605.dT = TC_1596_1605.port_a.T - TC_1596_1605.port_b.T; TC_1596_1605.port_a.Q_flow = TC_1596_1605.Q_flow; TC_1596_1605.port_b.Q_flow = -TC_1596_1605.Q_flow; TC_1596_1648.Q_flow = TC_1596_1648.G * TC_1596_1648.dT; TC_1596_1648.dT = TC_1596_1648.port_a.T - TC_1596_1648.port_b.T; TC_1596_1648.port_a.Q_flow = TC_1596_1648.Q_flow; TC_1596_1648.port_b.Q_flow = -TC_1596_1648.Q_flow; TC_1597_1598.Q_flow = TC_1597_1598.G * TC_1597_1598.dT; TC_1597_1598.dT = TC_1597_1598.port_a.T - TC_1597_1598.port_b.T; TC_1597_1598.port_a.Q_flow = TC_1597_1598.Q_flow; TC_1597_1598.port_b.Q_flow = -TC_1597_1598.Q_flow; TC_1597_1606.Q_flow = TC_1597_1606.G * TC_1597_1606.dT; TC_1597_1606.dT = TC_1597_1606.port_a.T - TC_1597_1606.port_b.T; TC_1597_1606.port_a.Q_flow = TC_1597_1606.Q_flow; TC_1597_1606.port_b.Q_flow = -TC_1597_1606.Q_flow; TC_1597_1649.Q_flow = TC_1597_1649.G * TC_1597_1649.dT; TC_1597_1649.dT = TC_1597_1649.port_a.T - TC_1597_1649.port_b.T; TC_1597_1649.port_a.Q_flow = TC_1597_1649.Q_flow; TC_1597_1649.port_b.Q_flow = -TC_1597_1649.Q_flow; TC_1598_1607.Q_flow = TC_1598_1607.G * TC_1598_1607.dT; TC_1598_1607.dT = TC_1598_1607.port_a.T - TC_1598_1607.port_b.T; TC_1598_1607.port_a.Q_flow = TC_1598_1607.Q_flow; TC_1598_1607.port_b.Q_flow = -TC_1598_1607.Q_flow; TC_1599_1600.Q_flow = TC_1599_1600.G * TC_1599_1600.dT; TC_1599_1600.dT = TC_1599_1600.port_a.T - TC_1599_1600.port_b.T; TC_1599_1600.port_a.Q_flow = TC_1599_1600.Q_flow; TC_1599_1600.port_b.Q_flow = -TC_1599_1600.Q_flow; TC_1600_1601.Q_flow = TC_1600_1601.G * TC_1600_1601.dT; TC_1600_1601.dT = TC_1600_1601.port_a.T - TC_1600_1601.port_b.T; TC_1600_1601.port_a.Q_flow = TC_1600_1601.Q_flow; TC_1600_1601.port_b.Q_flow = -TC_1600_1601.Q_flow; TC_1601_1602.Q_flow = TC_1601_1602.G * TC_1601_1602.dT; TC_1601_1602.dT = TC_1601_1602.port_a.T - TC_1601_1602.port_b.T; TC_1601_1602.port_a.Q_flow = TC_1601_1602.Q_flow; TC_1601_1602.port_b.Q_flow = -TC_1601_1602.Q_flow; TC_1602_1603.Q_flow = TC_1602_1603.G * TC_1602_1603.dT; TC_1602_1603.dT = TC_1602_1603.port_a.T - TC_1602_1603.port_b.T; TC_1602_1603.port_a.Q_flow = TC_1602_1603.Q_flow; TC_1602_1603.port_b.Q_flow = -TC_1602_1603.Q_flow; TC_1603_1604.Q_flow = TC_1603_1604.G * TC_1603_1604.dT; TC_1603_1604.dT = TC_1603_1604.port_a.T - TC_1603_1604.port_b.T; TC_1603_1604.port_a.Q_flow = TC_1603_1604.Q_flow; TC_1603_1604.port_b.Q_flow = -TC_1603_1604.Q_flow; TC_1604_1605.Q_flow = TC_1604_1605.G * TC_1604_1605.dT; TC_1604_1605.dT = TC_1604_1605.port_a.T - TC_1604_1605.port_b.T; TC_1604_1605.port_a.Q_flow = TC_1604_1605.Q_flow; TC_1604_1605.port_b.Q_flow = -TC_1604_1605.Q_flow; TC_1604_1650.Q_flow = TC_1604_1650.G * TC_1604_1650.dT; TC_1604_1650.dT = TC_1604_1650.port_a.T - TC_1604_1650.port_b.T; TC_1604_1650.port_a.Q_flow = TC_1604_1650.Q_flow; TC_1604_1650.port_b.Q_flow = -TC_1604_1650.Q_flow; TC_1605_1606.Q_flow = TC_1605_1606.G * TC_1605_1606.dT; TC_1605_1606.dT = TC_1605_1606.port_a.T - TC_1605_1606.port_b.T; TC_1605_1606.port_a.Q_flow = TC_1605_1606.Q_flow; TC_1605_1606.port_b.Q_flow = -TC_1605_1606.Q_flow; TC_1605_1651.Q_flow = TC_1605_1651.G * TC_1605_1651.dT; TC_1605_1651.dT = TC_1605_1651.port_a.T - TC_1605_1651.port_b.T; TC_1605_1651.port_a.Q_flow = TC_1605_1651.Q_flow; TC_1605_1651.port_b.Q_flow = -TC_1605_1651.Q_flow; TC_1606_1607.Q_flow = TC_1606_1607.G * TC_1606_1607.dT; TC_1606_1607.dT = TC_1606_1607.port_a.T - TC_1606_1607.port_b.T; TC_1606_1607.port_a.Q_flow = TC_1606_1607.Q_flow; TC_1606_1607.port_b.Q_flow = -TC_1606_1607.Q_flow; TC_1606_1652.Q_flow = TC_1606_1652.G * TC_1606_1652.dT; TC_1606_1652.dT = TC_1606_1652.port_a.T - TC_1606_1652.port_b.T; TC_1606_1652.port_a.Q_flow = TC_1606_1652.Q_flow; TC_1606_1652.port_b.Q_flow = -TC_1606_1652.Q_flow; TC_1608_1609.Q_flow = TC_1608_1609.G * TC_1608_1609.dT; TC_1608_1609.dT = TC_1608_1609.port_a.T - TC_1608_1609.port_b.T; TC_1608_1609.port_a.Q_flow = TC_1608_1609.Q_flow; TC_1608_1609.port_b.Q_flow = -TC_1608_1609.Q_flow; TC_1608_1617.Q_flow = TC_1608_1617.G * TC_1608_1617.dT; TC_1608_1617.dT = TC_1608_1617.port_a.T - TC_1608_1617.port_b.T; TC_1608_1617.port_a.Q_flow = TC_1608_1617.Q_flow; TC_1608_1617.port_b.Q_flow = -TC_1608_1617.Q_flow; TC_1609_1610.Q_flow = TC_1609_1610.G * TC_1609_1610.dT; TC_1609_1610.dT = TC_1609_1610.port_a.T - TC_1609_1610.port_b.T; TC_1609_1610.port_a.Q_flow = TC_1609_1610.Q_flow; TC_1609_1610.port_b.Q_flow = -TC_1609_1610.Q_flow; TC_1609_1618.Q_flow = TC_1609_1618.G * TC_1609_1618.dT; TC_1609_1618.dT = TC_1609_1618.port_a.T - TC_1609_1618.port_b.T; TC_1609_1618.port_a.Q_flow = TC_1609_1618.Q_flow; TC_1609_1618.port_b.Q_flow = -TC_1609_1618.Q_flow; TC_1610_1611.Q_flow = TC_1610_1611.G * TC_1610_1611.dT; TC_1610_1611.dT = TC_1610_1611.port_a.T - TC_1610_1611.port_b.T; TC_1610_1611.port_a.Q_flow = TC_1610_1611.Q_flow; TC_1610_1611.port_b.Q_flow = -TC_1610_1611.Q_flow; TC_1610_1619.Q_flow = TC_1610_1619.G * TC_1610_1619.dT; TC_1610_1619.dT = TC_1610_1619.port_a.T - TC_1610_1619.port_b.T; TC_1610_1619.port_a.Q_flow = TC_1610_1619.Q_flow; TC_1610_1619.port_b.Q_flow = -TC_1610_1619.Q_flow; TC_1611_1612.Q_flow = TC_1611_1612.G * TC_1611_1612.dT; TC_1611_1612.dT = TC_1611_1612.port_a.T - TC_1611_1612.port_b.T; TC_1611_1612.port_a.Q_flow = TC_1611_1612.Q_flow; TC_1611_1612.port_b.Q_flow = -TC_1611_1612.Q_flow; TC_1611_1620.Q_flow = TC_1611_1620.G * TC_1611_1620.dT; TC_1611_1620.dT = TC_1611_1620.port_a.T - TC_1611_1620.port_b.T; TC_1611_1620.port_a.Q_flow = TC_1611_1620.Q_flow; TC_1611_1620.port_b.Q_flow = -TC_1611_1620.Q_flow; TC_1612_1613.Q_flow = TC_1612_1613.G * TC_1612_1613.dT; TC_1612_1613.dT = TC_1612_1613.port_a.T - TC_1612_1613.port_b.T; TC_1612_1613.port_a.Q_flow = TC_1612_1613.Q_flow; TC_1612_1613.port_b.Q_flow = -TC_1612_1613.Q_flow; TC_1612_1621.Q_flow = TC_1612_1621.G * TC_1612_1621.dT; TC_1612_1621.dT = TC_1612_1621.port_a.T - TC_1612_1621.port_b.T; TC_1612_1621.port_a.Q_flow = TC_1612_1621.Q_flow; TC_1612_1621.port_b.Q_flow = -TC_1612_1621.Q_flow; TC_1613_1614.Q_flow = TC_1613_1614.G * TC_1613_1614.dT; TC_1613_1614.dT = TC_1613_1614.port_a.T - TC_1613_1614.port_b.T; TC_1613_1614.port_a.Q_flow = TC_1613_1614.Q_flow; TC_1613_1614.port_b.Q_flow = -TC_1613_1614.Q_flow; TC_1613_1622.Q_flow = TC_1613_1622.G * TC_1613_1622.dT; TC_1613_1622.dT = TC_1613_1622.port_a.T - TC_1613_1622.port_b.T; TC_1613_1622.port_a.Q_flow = TC_1613_1622.Q_flow; TC_1613_1622.port_b.Q_flow = -TC_1613_1622.Q_flow; TC_1614_1615.Q_flow = TC_1614_1615.G * TC_1614_1615.dT; TC_1614_1615.dT = TC_1614_1615.port_a.T - TC_1614_1615.port_b.T; TC_1614_1615.port_a.Q_flow = TC_1614_1615.Q_flow; TC_1614_1615.port_b.Q_flow = -TC_1614_1615.Q_flow; TC_1614_1623.Q_flow = TC_1614_1623.G * TC_1614_1623.dT; TC_1614_1623.dT = TC_1614_1623.port_a.T - TC_1614_1623.port_b.T; TC_1614_1623.port_a.Q_flow = TC_1614_1623.Q_flow; TC_1614_1623.port_b.Q_flow = -TC_1614_1623.Q_flow; TC_1615_1616.Q_flow = TC_1615_1616.G * TC_1615_1616.dT; TC_1615_1616.dT = TC_1615_1616.port_a.T - TC_1615_1616.port_b.T; TC_1615_1616.port_a.Q_flow = TC_1615_1616.Q_flow; TC_1615_1616.port_b.Q_flow = -TC_1615_1616.Q_flow; TC_1615_1624.Q_flow = TC_1615_1624.G * TC_1615_1624.dT; TC_1615_1624.dT = TC_1615_1624.port_a.T - TC_1615_1624.port_b.T; TC_1615_1624.port_a.Q_flow = TC_1615_1624.Q_flow; TC_1615_1624.port_b.Q_flow = -TC_1615_1624.Q_flow; TC_1616_1625.Q_flow = TC_1616_1625.G * TC_1616_1625.dT; TC_1616_1625.dT = TC_1616_1625.port_a.T - TC_1616_1625.port_b.T; TC_1616_1625.port_a.Q_flow = TC_1616_1625.Q_flow; TC_1616_1625.port_b.Q_flow = -TC_1616_1625.Q_flow; TC_1617_1618.Q_flow = TC_1617_1618.G * TC_1617_1618.dT; TC_1617_1618.dT = TC_1617_1618.port_a.T - TC_1617_1618.port_b.T; TC_1617_1618.port_a.Q_flow = TC_1617_1618.Q_flow; TC_1617_1618.port_b.Q_flow = -TC_1617_1618.Q_flow; TC_1617_1626.Q_flow = TC_1617_1626.G * TC_1617_1626.dT; TC_1617_1626.dT = TC_1617_1626.port_a.T - TC_1617_1626.port_b.T; TC_1617_1626.port_a.Q_flow = TC_1617_1626.Q_flow; TC_1617_1626.port_b.Q_flow = -TC_1617_1626.Q_flow; TC_1618_1619.Q_flow = TC_1618_1619.G * TC_1618_1619.dT; TC_1618_1619.dT = TC_1618_1619.port_a.T - TC_1618_1619.port_b.T; TC_1618_1619.port_a.Q_flow = TC_1618_1619.Q_flow; TC_1618_1619.port_b.Q_flow = -TC_1618_1619.Q_flow; TC_1618_1627.Q_flow = TC_1618_1627.G * TC_1618_1627.dT; TC_1618_1627.dT = TC_1618_1627.port_a.T - TC_1618_1627.port_b.T; TC_1618_1627.port_a.Q_flow = TC_1618_1627.Q_flow; TC_1618_1627.port_b.Q_flow = -TC_1618_1627.Q_flow; TC_1619_1620.Q_flow = TC_1619_1620.G * TC_1619_1620.dT; TC_1619_1620.dT = TC_1619_1620.port_a.T - TC_1619_1620.port_b.T; TC_1619_1620.port_a.Q_flow = TC_1619_1620.Q_flow; TC_1619_1620.port_b.Q_flow = -TC_1619_1620.Q_flow; TC_1619_1628.Q_flow = TC_1619_1628.G * TC_1619_1628.dT; TC_1619_1628.dT = TC_1619_1628.port_a.T - TC_1619_1628.port_b.T; TC_1619_1628.port_a.Q_flow = TC_1619_1628.Q_flow; TC_1619_1628.port_b.Q_flow = -TC_1619_1628.Q_flow; TC_1620_1621.Q_flow = TC_1620_1621.G * TC_1620_1621.dT; TC_1620_1621.dT = TC_1620_1621.port_a.T - TC_1620_1621.port_b.T; TC_1620_1621.port_a.Q_flow = TC_1620_1621.Q_flow; TC_1620_1621.port_b.Q_flow = -TC_1620_1621.Q_flow; TC_1620_1629.Q_flow = TC_1620_1629.G * TC_1620_1629.dT; TC_1620_1629.dT = TC_1620_1629.port_a.T - TC_1620_1629.port_b.T; TC_1620_1629.port_a.Q_flow = TC_1620_1629.Q_flow; TC_1620_1629.port_b.Q_flow = -TC_1620_1629.Q_flow; TC_1620_1635.Q_flow = TC_1620_1635.G * TC_1620_1635.dT; TC_1620_1635.dT = TC_1620_1635.port_a.T - TC_1620_1635.port_b.T; TC_1620_1635.port_a.Q_flow = TC_1620_1635.Q_flow; TC_1620_1635.port_b.Q_flow = -TC_1620_1635.Q_flow; TC_1621_1622.Q_flow = TC_1621_1622.G * TC_1621_1622.dT; TC_1621_1622.dT = TC_1621_1622.port_a.T - TC_1621_1622.port_b.T; TC_1621_1622.port_a.Q_flow = TC_1621_1622.Q_flow; TC_1621_1622.port_b.Q_flow = -TC_1621_1622.Q_flow; TC_1621_1630.Q_flow = TC_1621_1630.G * TC_1621_1630.dT; TC_1621_1630.dT = TC_1621_1630.port_a.T - TC_1621_1630.port_b.T; TC_1621_1630.port_a.Q_flow = TC_1621_1630.Q_flow; TC_1621_1630.port_b.Q_flow = -TC_1621_1630.Q_flow; TC_1621_1636.Q_flow = TC_1621_1636.G * TC_1621_1636.dT; TC_1621_1636.dT = TC_1621_1636.port_a.T - TC_1621_1636.port_b.T; TC_1621_1636.port_a.Q_flow = TC_1621_1636.Q_flow; TC_1621_1636.port_b.Q_flow = -TC_1621_1636.Q_flow; TC_1622_1623.Q_flow = TC_1622_1623.G * TC_1622_1623.dT; TC_1622_1623.dT = TC_1622_1623.port_a.T - TC_1622_1623.port_b.T; TC_1622_1623.port_a.Q_flow = TC_1622_1623.Q_flow; TC_1622_1623.port_b.Q_flow = -TC_1622_1623.Q_flow; TC_1622_1631.Q_flow = TC_1622_1631.G * TC_1622_1631.dT; TC_1622_1631.dT = TC_1622_1631.port_a.T - TC_1622_1631.port_b.T; TC_1622_1631.port_a.Q_flow = TC_1622_1631.Q_flow; TC_1622_1631.port_b.Q_flow = -TC_1622_1631.Q_flow; TC_1622_1637.Q_flow = TC_1622_1637.G * TC_1622_1637.dT; TC_1622_1637.dT = TC_1622_1637.port_a.T - TC_1622_1637.port_b.T; TC_1622_1637.port_a.Q_flow = TC_1622_1637.Q_flow; TC_1622_1637.port_b.Q_flow = -TC_1622_1637.Q_flow; TC_1623_1624.Q_flow = TC_1623_1624.G * TC_1623_1624.dT; TC_1623_1624.dT = TC_1623_1624.port_a.T - TC_1623_1624.port_b.T; TC_1623_1624.port_a.Q_flow = TC_1623_1624.Q_flow; TC_1623_1624.port_b.Q_flow = -TC_1623_1624.Q_flow; TC_1623_1632.Q_flow = TC_1623_1632.G * TC_1623_1632.dT; TC_1623_1632.dT = TC_1623_1632.port_a.T - TC_1623_1632.port_b.T; TC_1623_1632.port_a.Q_flow = TC_1623_1632.Q_flow; TC_1623_1632.port_b.Q_flow = -TC_1623_1632.Q_flow; TC_1623_1638.Q_flow = TC_1623_1638.G * TC_1623_1638.dT; TC_1623_1638.dT = TC_1623_1638.port_a.T - TC_1623_1638.port_b.T; TC_1623_1638.port_a.Q_flow = TC_1623_1638.Q_flow; TC_1623_1638.port_b.Q_flow = -TC_1623_1638.Q_flow; TC_1624_1625.Q_flow = TC_1624_1625.G * TC_1624_1625.dT; TC_1624_1625.dT = TC_1624_1625.port_a.T - TC_1624_1625.port_b.T; TC_1624_1625.port_a.Q_flow = TC_1624_1625.Q_flow; TC_1624_1625.port_b.Q_flow = -TC_1624_1625.Q_flow; TC_1624_1633.Q_flow = TC_1624_1633.G * TC_1624_1633.dT; TC_1624_1633.dT = TC_1624_1633.port_a.T - TC_1624_1633.port_b.T; TC_1624_1633.port_a.Q_flow = TC_1624_1633.Q_flow; TC_1624_1633.port_b.Q_flow = -TC_1624_1633.Q_flow; TC_1625_1634.Q_flow = TC_1625_1634.G * TC_1625_1634.dT; TC_1625_1634.dT = TC_1625_1634.port_a.T - TC_1625_1634.port_b.T; TC_1625_1634.port_a.Q_flow = TC_1625_1634.Q_flow; TC_1625_1634.port_b.Q_flow = -TC_1625_1634.Q_flow; TC_1626_1627.Q_flow = TC_1626_1627.G * TC_1626_1627.dT; TC_1626_1627.dT = TC_1626_1627.port_a.T - TC_1626_1627.port_b.T; TC_1626_1627.port_a.Q_flow = TC_1626_1627.Q_flow; TC_1626_1627.port_b.Q_flow = -TC_1626_1627.Q_flow; TC_1627_1628.Q_flow = TC_1627_1628.G * TC_1627_1628.dT; TC_1627_1628.dT = TC_1627_1628.port_a.T - TC_1627_1628.port_b.T; TC_1627_1628.port_a.Q_flow = TC_1627_1628.Q_flow; TC_1627_1628.port_b.Q_flow = -TC_1627_1628.Q_flow; TC_1628_1629.Q_flow = TC_1628_1629.G * TC_1628_1629.dT; TC_1628_1629.dT = TC_1628_1629.port_a.T - TC_1628_1629.port_b.T; TC_1628_1629.port_a.Q_flow = TC_1628_1629.Q_flow; TC_1628_1629.port_b.Q_flow = -TC_1628_1629.Q_flow; TC_1629_1630.Q_flow = TC_1629_1630.G * TC_1629_1630.dT; TC_1629_1630.dT = TC_1629_1630.port_a.T - TC_1629_1630.port_b.T; TC_1629_1630.port_a.Q_flow = TC_1629_1630.Q_flow; TC_1629_1630.port_b.Q_flow = -TC_1629_1630.Q_flow; TC_1629_1639.Q_flow = TC_1629_1639.G * TC_1629_1639.dT; TC_1629_1639.dT = TC_1629_1639.port_a.T - TC_1629_1639.port_b.T; TC_1629_1639.port_a.Q_flow = TC_1629_1639.Q_flow; TC_1629_1639.port_b.Q_flow = -TC_1629_1639.Q_flow; TC_1630_1631.Q_flow = TC_1630_1631.G * TC_1630_1631.dT; TC_1630_1631.dT = TC_1630_1631.port_a.T - TC_1630_1631.port_b.T; TC_1630_1631.port_a.Q_flow = TC_1630_1631.Q_flow; TC_1630_1631.port_b.Q_flow = -TC_1630_1631.Q_flow; TC_1630_1640.Q_flow = TC_1630_1640.G * TC_1630_1640.dT; TC_1630_1640.dT = TC_1630_1640.port_a.T - TC_1630_1640.port_b.T; TC_1630_1640.port_a.Q_flow = TC_1630_1640.Q_flow; TC_1630_1640.port_b.Q_flow = -TC_1630_1640.Q_flow; TC_1631_1632.Q_flow = TC_1631_1632.G * TC_1631_1632.dT; TC_1631_1632.dT = TC_1631_1632.port_a.T - TC_1631_1632.port_b.T; TC_1631_1632.port_a.Q_flow = TC_1631_1632.Q_flow; TC_1631_1632.port_b.Q_flow = -TC_1631_1632.Q_flow; TC_1631_1641.Q_flow = TC_1631_1641.G * TC_1631_1641.dT; TC_1631_1641.dT = TC_1631_1641.port_a.T - TC_1631_1641.port_b.T; TC_1631_1641.port_a.Q_flow = TC_1631_1641.Q_flow; TC_1631_1641.port_b.Q_flow = -TC_1631_1641.Q_flow; TC_1632_1633.Q_flow = TC_1632_1633.G * TC_1632_1633.dT; TC_1632_1633.dT = TC_1632_1633.port_a.T - TC_1632_1633.port_b.T; TC_1632_1633.port_a.Q_flow = TC_1632_1633.Q_flow; TC_1632_1633.port_b.Q_flow = -TC_1632_1633.Q_flow; TC_1632_1642.Q_flow = TC_1632_1642.G * TC_1632_1642.dT; TC_1632_1642.dT = TC_1632_1642.port_a.T - TC_1632_1642.port_b.T; TC_1632_1642.port_a.Q_flow = TC_1632_1642.Q_flow; TC_1632_1642.port_b.Q_flow = -TC_1632_1642.Q_flow; TC_1633_1634.Q_flow = TC_1633_1634.G * TC_1633_1634.dT; TC_1633_1634.dT = TC_1633_1634.port_a.T - TC_1633_1634.port_b.T; TC_1633_1634.port_a.Q_flow = TC_1633_1634.Q_flow; TC_1633_1634.port_b.Q_flow = -TC_1633_1634.Q_flow; TC_1635_1636.Q_flow = TC_1635_1636.G * TC_1635_1636.dT; TC_1635_1636.dT = TC_1635_1636.port_a.T - TC_1635_1636.port_b.T; TC_1635_1636.port_a.Q_flow = TC_1635_1636.Q_flow; TC_1635_1636.port_b.Q_flow = -TC_1635_1636.Q_flow; TC_1635_1639.Q_flow = TC_1635_1639.G * TC_1635_1639.dT; TC_1635_1639.dT = TC_1635_1639.port_a.T - TC_1635_1639.port_b.T; TC_1635_1639.port_a.Q_flow = TC_1635_1639.Q_flow; TC_1635_1639.port_b.Q_flow = -TC_1635_1639.Q_flow; TC_1636_1637.Q_flow = TC_1636_1637.G * TC_1636_1637.dT; TC_1636_1637.dT = TC_1636_1637.port_a.T - TC_1636_1637.port_b.T; TC_1636_1637.port_a.Q_flow = TC_1636_1637.Q_flow; TC_1636_1637.port_b.Q_flow = -TC_1636_1637.Q_flow; TC_1636_1640.Q_flow = TC_1636_1640.G * TC_1636_1640.dT; TC_1636_1640.dT = TC_1636_1640.port_a.T - TC_1636_1640.port_b.T; TC_1636_1640.port_a.Q_flow = TC_1636_1640.Q_flow; TC_1636_1640.port_b.Q_flow = -TC_1636_1640.Q_flow; TC_1637_1638.Q_flow = TC_1637_1638.G * TC_1637_1638.dT; TC_1637_1638.dT = TC_1637_1638.port_a.T - TC_1637_1638.port_b.T; TC_1637_1638.port_a.Q_flow = TC_1637_1638.Q_flow; TC_1637_1638.port_b.Q_flow = -TC_1637_1638.Q_flow; TC_1637_1641.Q_flow = TC_1637_1641.G * TC_1637_1641.dT; TC_1637_1641.dT = TC_1637_1641.port_a.T - TC_1637_1641.port_b.T; TC_1637_1641.port_a.Q_flow = TC_1637_1641.Q_flow; TC_1637_1641.port_b.Q_flow = -TC_1637_1641.Q_flow; TC_1638_1642.Q_flow = TC_1638_1642.G * TC_1638_1642.dT; TC_1638_1642.dT = TC_1638_1642.port_a.T - TC_1638_1642.port_b.T; TC_1638_1642.port_a.Q_flow = TC_1638_1642.Q_flow; TC_1638_1642.port_b.Q_flow = -TC_1638_1642.Q_flow; TC_1639_1640.Q_flow = TC_1639_1640.G * TC_1639_1640.dT; TC_1639_1640.dT = TC_1639_1640.port_a.T - TC_1639_1640.port_b.T; TC_1639_1640.port_a.Q_flow = TC_1639_1640.Q_flow; TC_1639_1640.port_b.Q_flow = -TC_1639_1640.Q_flow; TC_1639_1643.Q_flow = TC_1639_1643.G * TC_1639_1643.dT; TC_1639_1643.dT = TC_1639_1643.port_a.T - TC_1639_1643.port_b.T; TC_1639_1643.port_a.Q_flow = TC_1639_1643.Q_flow; TC_1639_1643.port_b.Q_flow = -TC_1639_1643.Q_flow; TC_1640_1641.Q_flow = TC_1640_1641.G * TC_1640_1641.dT; TC_1640_1641.dT = TC_1640_1641.port_a.T - TC_1640_1641.port_b.T; TC_1640_1641.port_a.Q_flow = TC_1640_1641.Q_flow; TC_1640_1641.port_b.Q_flow = -TC_1640_1641.Q_flow; TC_1640_1644.Q_flow = TC_1640_1644.G * TC_1640_1644.dT; TC_1640_1644.dT = TC_1640_1644.port_a.T - TC_1640_1644.port_b.T; TC_1640_1644.port_a.Q_flow = TC_1640_1644.Q_flow; TC_1640_1644.port_b.Q_flow = -TC_1640_1644.Q_flow; TC_1641_1642.Q_flow = TC_1641_1642.G * TC_1641_1642.dT; TC_1641_1642.dT = TC_1641_1642.port_a.T - TC_1641_1642.port_b.T; TC_1641_1642.port_a.Q_flow = TC_1641_1642.Q_flow; TC_1641_1642.port_b.Q_flow = -TC_1641_1642.Q_flow; TC_1641_1645.Q_flow = TC_1641_1645.G * TC_1641_1645.dT; TC_1641_1645.dT = TC_1641_1645.port_a.T - TC_1641_1645.port_b.T; TC_1641_1645.port_a.Q_flow = TC_1641_1645.Q_flow; TC_1641_1645.port_b.Q_flow = -TC_1641_1645.Q_flow; TC_1642_1646.Q_flow = TC_1642_1646.G * TC_1642_1646.dT; TC_1642_1646.dT = TC_1642_1646.port_a.T - TC_1642_1646.port_b.T; TC_1642_1646.port_a.Q_flow = TC_1642_1646.Q_flow; TC_1642_1646.port_b.Q_flow = -TC_1642_1646.Q_flow; TC_1643_1644.Q_flow = TC_1643_1644.G * TC_1643_1644.dT; TC_1643_1644.dT = TC_1643_1644.port_a.T - TC_1643_1644.port_b.T; TC_1643_1644.port_a.Q_flow = TC_1643_1644.Q_flow; TC_1643_1644.port_b.Q_flow = -TC_1643_1644.Q_flow; TC_1644_1645.Q_flow = TC_1644_1645.G * TC_1644_1645.dT; TC_1644_1645.dT = TC_1644_1645.port_a.T - TC_1644_1645.port_b.T; TC_1644_1645.port_a.Q_flow = TC_1644_1645.Q_flow; TC_1644_1645.port_b.Q_flow = -TC_1644_1645.Q_flow; TC_1645_1646.Q_flow = TC_1645_1646.G * TC_1645_1646.dT; TC_1645_1646.dT = TC_1645_1646.port_a.T - TC_1645_1646.port_b.T; TC_1645_1646.port_a.Q_flow = TC_1645_1646.Q_flow; TC_1645_1646.port_b.Q_flow = -TC_1645_1646.Q_flow; TC_1647_1648.Q_flow = TC_1647_1648.G * TC_1647_1648.dT; TC_1647_1648.dT = TC_1647_1648.port_a.T - TC_1647_1648.port_b.T; TC_1647_1648.port_a.Q_flow = TC_1647_1648.Q_flow; TC_1647_1648.port_b.Q_flow = -TC_1647_1648.Q_flow; TC_1647_1650.Q_flow = TC_1647_1650.G * TC_1647_1650.dT; TC_1647_1650.dT = TC_1647_1650.port_a.T - TC_1647_1650.port_b.T; TC_1647_1650.port_a.Q_flow = TC_1647_1650.Q_flow; TC_1647_1650.port_b.Q_flow = -TC_1647_1650.Q_flow; TC_1648_1649.Q_flow = TC_1648_1649.G * TC_1648_1649.dT; TC_1648_1649.dT = TC_1648_1649.port_a.T - TC_1648_1649.port_b.T; TC_1648_1649.port_a.Q_flow = TC_1648_1649.Q_flow; TC_1648_1649.port_b.Q_flow = -TC_1648_1649.Q_flow; TC_1648_1651.Q_flow = TC_1648_1651.G * TC_1648_1651.dT; TC_1648_1651.dT = TC_1648_1651.port_a.T - TC_1648_1651.port_b.T; TC_1648_1651.port_a.Q_flow = TC_1648_1651.Q_flow; TC_1648_1651.port_b.Q_flow = -TC_1648_1651.Q_flow; TC_1649_1652.Q_flow = TC_1649_1652.G * TC_1649_1652.dT; TC_1649_1652.dT = TC_1649_1652.port_a.T - TC_1649_1652.port_b.T; TC_1649_1652.port_a.Q_flow = TC_1649_1652.Q_flow; TC_1649_1652.port_b.Q_flow = -TC_1649_1652.Q_flow; TC_1650_1651.Q_flow = TC_1650_1651.G * TC_1650_1651.dT; TC_1650_1651.dT = TC_1650_1651.port_a.T - TC_1650_1651.port_b.T; TC_1650_1651.port_a.Q_flow = TC_1650_1651.Q_flow; TC_1650_1651.port_b.Q_flow = -TC_1650_1651.Q_flow; TC_1650_1653.Q_flow = TC_1650_1653.G * TC_1650_1653.dT; TC_1650_1653.dT = TC_1650_1653.port_a.T - TC_1650_1653.port_b.T; TC_1650_1653.port_a.Q_flow = TC_1650_1653.Q_flow; TC_1650_1653.port_b.Q_flow = -TC_1650_1653.Q_flow; TC_1651_1652.Q_flow = TC_1651_1652.G * TC_1651_1652.dT; TC_1651_1652.dT = TC_1651_1652.port_a.T - TC_1651_1652.port_b.T; TC_1651_1652.port_a.Q_flow = TC_1651_1652.Q_flow; TC_1651_1652.port_b.Q_flow = -TC_1651_1652.Q_flow; TC_1651_1654.Q_flow = TC_1651_1654.G * TC_1651_1654.dT; TC_1651_1654.dT = TC_1651_1654.port_a.T - TC_1651_1654.port_b.T; TC_1651_1654.port_a.Q_flow = TC_1651_1654.Q_flow; TC_1651_1654.port_b.Q_flow = -TC_1651_1654.Q_flow; TC_1652_1655.Q_flow = TC_1652_1655.G * TC_1652_1655.dT; TC_1652_1655.dT = TC_1652_1655.port_a.T - TC_1652_1655.port_b.T; TC_1652_1655.port_a.Q_flow = TC_1652_1655.Q_flow; TC_1652_1655.port_b.Q_flow = -TC_1652_1655.Q_flow; TC_1653_1654.Q_flow = TC_1653_1654.G * TC_1653_1654.dT; TC_1653_1654.dT = TC_1653_1654.port_a.T - TC_1653_1654.port_b.T; TC_1653_1654.port_a.Q_flow = TC_1653_1654.Q_flow; TC_1653_1654.port_b.Q_flow = -TC_1653_1654.Q_flow; TC_1654_1655.Q_flow = TC_1654_1655.G * TC_1654_1655.dT; TC_1654_1655.dT = TC_1654_1655.port_a.T - TC_1654_1655.port_b.T; TC_1654_1655.port_a.Q_flow = TC_1654_1655.Q_flow; TC_1654_1655.port_b.Q_flow = -TC_1654_1655.Q_flow; TC_1656_1657.Q_flow = TC_1656_1657.G * TC_1656_1657.dT; TC_1656_1657.dT = TC_1656_1657.port_a.T - TC_1656_1657.port_b.T; TC_1656_1657.port_a.Q_flow = TC_1656_1657.Q_flow; TC_1656_1657.port_b.Q_flow = -TC_1656_1657.Q_flow; TC_1656_1659.Q_flow = TC_1656_1659.G * TC_1656_1659.dT; TC_1656_1659.dT = TC_1656_1659.port_a.T - TC_1656_1659.port_b.T; TC_1656_1659.port_a.Q_flow = TC_1656_1659.Q_flow; TC_1656_1659.port_b.Q_flow = -TC_1656_1659.Q_flow; TC_1657_1658.Q_flow = TC_1657_1658.G * TC_1657_1658.dT; TC_1657_1658.dT = TC_1657_1658.port_a.T - TC_1657_1658.port_b.T; TC_1657_1658.port_a.Q_flow = TC_1657_1658.Q_flow; TC_1657_1658.port_b.Q_flow = -TC_1657_1658.Q_flow; TC_1657_1660.Q_flow = TC_1657_1660.G * TC_1657_1660.dT; TC_1657_1660.dT = TC_1657_1660.port_a.T - TC_1657_1660.port_b.T; TC_1657_1660.port_a.Q_flow = TC_1657_1660.Q_flow; TC_1657_1660.port_b.Q_flow = -TC_1657_1660.Q_flow; TC_1658_1661.Q_flow = TC_1658_1661.G * TC_1658_1661.dT; TC_1658_1661.dT = TC_1658_1661.port_a.T - TC_1658_1661.port_b.T; TC_1658_1661.port_a.Q_flow = TC_1658_1661.Q_flow; TC_1658_1661.port_b.Q_flow = -TC_1658_1661.Q_flow; TC_1659_1660.Q_flow = TC_1659_1660.G * TC_1659_1660.dT; TC_1659_1660.dT = TC_1659_1660.port_a.T - TC_1659_1660.port_b.T; TC_1659_1660.port_a.Q_flow = TC_1659_1660.Q_flow; TC_1659_1660.port_b.Q_flow = -TC_1659_1660.Q_flow; TC_1659_1662.Q_flow = TC_1659_1662.G * TC_1659_1662.dT; TC_1659_1662.dT = TC_1659_1662.port_a.T - TC_1659_1662.port_b.T; TC_1659_1662.port_a.Q_flow = TC_1659_1662.Q_flow; TC_1659_1662.port_b.Q_flow = -TC_1659_1662.Q_flow; TC_1660_1661.Q_flow = TC_1660_1661.G * TC_1660_1661.dT; TC_1660_1661.dT = TC_1660_1661.port_a.T - TC_1660_1661.port_b.T; TC_1660_1661.port_a.Q_flow = TC_1660_1661.Q_flow; TC_1660_1661.port_b.Q_flow = -TC_1660_1661.Q_flow; TC_1660_1663.Q_flow = TC_1660_1663.G * TC_1660_1663.dT; TC_1660_1663.dT = TC_1660_1663.port_a.T - TC_1660_1663.port_b.T; TC_1660_1663.port_a.Q_flow = TC_1660_1663.Q_flow; TC_1660_1663.port_b.Q_flow = -TC_1660_1663.Q_flow; TC_1661_1664.Q_flow = TC_1661_1664.G * TC_1661_1664.dT; TC_1661_1664.dT = TC_1661_1664.port_a.T - TC_1661_1664.port_b.T; TC_1661_1664.port_a.Q_flow = TC_1661_1664.Q_flow; TC_1661_1664.port_b.Q_flow = -TC_1661_1664.Q_flow; TC_1662_1663.Q_flow = TC_1662_1663.G * TC_1662_1663.dT; TC_1662_1663.dT = TC_1662_1663.port_a.T - TC_1662_1663.port_b.T; TC_1662_1663.port_a.Q_flow = TC_1662_1663.Q_flow; TC_1662_1663.port_b.Q_flow = -TC_1662_1663.Q_flow; TC_1663_1664.Q_flow = TC_1663_1664.G * TC_1663_1664.dT; TC_1663_1664.dT = TC_1663_1664.port_a.T - TC_1663_1664.port_b.T; TC_1663_1664.port_a.Q_flow = TC_1663_1664.Q_flow; TC_1663_1664.port_b.Q_flow = -TC_1663_1664.Q_flow; TC_1_0.Q_flow = TC_1_0.G * TC_1_0.dT; TC_1_0.dT = TC_1_0.port_a.T - TC_1_0.port_b.T; TC_1_0.port_a.Q_flow = TC_1_0.Q_flow; TC_1_0.port_b.Q_flow = -TC_1_0.Q_flow; TC_2_0.Q_flow = TC_2_0.G * TC_2_0.dT; TC_2_0.dT = TC_2_0.port_a.T - TC_2_0.port_b.T; TC_2_0.port_a.Q_flow = TC_2_0.Q_flow; TC_2_0.port_b.Q_flow = -TC_2_0.Q_flow; TC_3_0.Q_flow = TC_3_0.G * TC_3_0.dT; TC_3_0.dT = TC_3_0.port_a.T - TC_3_0.port_b.T; TC_3_0.port_a.Q_flow = TC_3_0.Q_flow; TC_3_0.port_b.Q_flow = -TC_3_0.Q_flow; TC_4_0.Q_flow = TC_4_0.G * TC_4_0.dT; TC_4_0.dT = TC_4_0.port_a.T - TC_4_0.port_b.T; TC_4_0.port_a.Q_flow = TC_4_0.Q_flow; TC_4_0.port_b.Q_flow = -TC_4_0.Q_flow; TC_5_0.Q_flow = TC_5_0.G * TC_5_0.dT; TC_5_0.dT = TC_5_0.port_a.T - TC_5_0.port_b.T; TC_5_0.port_a.Q_flow = TC_5_0.Q_flow; TC_5_0.port_b.Q_flow = -TC_5_0.Q_flow; TC_6_0.Q_flow = TC_6_0.G * TC_6_0.dT; TC_6_0.dT = TC_6_0.port_a.T - TC_6_0.port_b.T; TC_6_0.port_a.Q_flow = TC_6_0.Q_flow; TC_6_0.port_b.Q_flow = -TC_6_0.Q_flow; TC_7_0.Q_flow = TC_7_0.G * TC_7_0.dT; TC_7_0.dT = TC_7_0.port_a.T - TC_7_0.port_b.T; TC_7_0.port_a.Q_flow = TC_7_0.Q_flow; TC_7_0.port_b.Q_flow = -TC_7_0.Q_flow; TC_8_0.Q_flow = TC_8_0.G * TC_8_0.dT; TC_8_0.dT = TC_8_0.port_a.T - TC_8_0.port_b.T; TC_8_0.port_a.Q_flow = TC_8_0.Q_flow; TC_8_0.port_b.Q_flow = -TC_8_0.Q_flow; TC_9_0.Q_flow = TC_9_0.G * TC_9_0.dT; TC_9_0.dT = TC_9_0.port_a.T - TC_9_0.port_b.T; TC_9_0.port_a.Q_flow = TC_9_0.Q_flow; TC_9_0.port_b.Q_flow = -TC_9_0.Q_flow; TC_10_0.Q_flow = TC_10_0.G * TC_10_0.dT; TC_10_0.dT = TC_10_0.port_a.T - TC_10_0.port_b.T; TC_10_0.port_a.Q_flow = TC_10_0.Q_flow; TC_10_0.port_b.Q_flow = -TC_10_0.Q_flow; TC_11_0.Q_flow = TC_11_0.G * TC_11_0.dT; TC_11_0.dT = TC_11_0.port_a.T - TC_11_0.port_b.T; TC_11_0.port_a.Q_flow = TC_11_0.Q_flow; TC_11_0.port_b.Q_flow = -TC_11_0.Q_flow; TC_12_0.Q_flow = TC_12_0.G * TC_12_0.dT; TC_12_0.dT = TC_12_0.port_a.T - TC_12_0.port_b.T; TC_12_0.port_a.Q_flow = TC_12_0.Q_flow; TC_12_0.port_b.Q_flow = -TC_12_0.Q_flow; TC_13_0.Q_flow = TC_13_0.G * TC_13_0.dT; TC_13_0.dT = TC_13_0.port_a.T - TC_13_0.port_b.T; TC_13_0.port_a.Q_flow = TC_13_0.Q_flow; TC_13_0.port_b.Q_flow = -TC_13_0.Q_flow; TC_14_0.Q_flow = TC_14_0.G * TC_14_0.dT; TC_14_0.dT = TC_14_0.port_a.T - TC_14_0.port_b.T; TC_14_0.port_a.Q_flow = TC_14_0.Q_flow; TC_14_0.port_b.Q_flow = -TC_14_0.Q_flow; TC_15_0.Q_flow = TC_15_0.G * TC_15_0.dT; TC_15_0.dT = TC_15_0.port_a.T - TC_15_0.port_b.T; TC_15_0.port_a.Q_flow = TC_15_0.Q_flow; TC_15_0.port_b.Q_flow = -TC_15_0.Q_flow; TC_16_0.Q_flow = TC_16_0.G * TC_16_0.dT; TC_16_0.dT = TC_16_0.port_a.T - TC_16_0.port_b.T; TC_16_0.port_a.Q_flow = TC_16_0.Q_flow; TC_16_0.port_b.Q_flow = -TC_16_0.Q_flow; TC_17_0.Q_flow = TC_17_0.G * TC_17_0.dT; TC_17_0.dT = TC_17_0.port_a.T - TC_17_0.port_b.T; TC_17_0.port_a.Q_flow = TC_17_0.Q_flow; TC_17_0.port_b.Q_flow = -TC_17_0.Q_flow; TC_18_0.Q_flow = TC_18_0.G * TC_18_0.dT; TC_18_0.dT = TC_18_0.port_a.T - TC_18_0.port_b.T; TC_18_0.port_a.Q_flow = TC_18_0.Q_flow; TC_18_0.port_b.Q_flow = -TC_18_0.Q_flow; TC_19_0.Q_flow = TC_19_0.G * TC_19_0.dT; TC_19_0.dT = TC_19_0.port_a.T - TC_19_0.port_b.T; TC_19_0.port_a.Q_flow = TC_19_0.Q_flow; TC_19_0.port_b.Q_flow = -TC_19_0.Q_flow; TC_20_0.Q_flow = TC_20_0.G * TC_20_0.dT; TC_20_0.dT = TC_20_0.port_a.T - TC_20_0.port_b.T; TC_20_0.port_a.Q_flow = TC_20_0.Q_flow; TC_20_0.port_b.Q_flow = -TC_20_0.Q_flow; TC_21_0.Q_flow = TC_21_0.G * TC_21_0.dT; TC_21_0.dT = TC_21_0.port_a.T - TC_21_0.port_b.T; TC_21_0.port_a.Q_flow = TC_21_0.Q_flow; TC_21_0.port_b.Q_flow = -TC_21_0.Q_flow; TC_22_0.Q_flow = TC_22_0.G * TC_22_0.dT; TC_22_0.dT = TC_22_0.port_a.T - TC_22_0.port_b.T; TC_22_0.port_a.Q_flow = TC_22_0.Q_flow; TC_22_0.port_b.Q_flow = -TC_22_0.Q_flow; TC_23_0.Q_flow = TC_23_0.G * TC_23_0.dT; TC_23_0.dT = TC_23_0.port_a.T - TC_23_0.port_b.T; TC_23_0.port_a.Q_flow = TC_23_0.Q_flow; TC_23_0.port_b.Q_flow = -TC_23_0.Q_flow; TC_24_0.Q_flow = TC_24_0.G * TC_24_0.dT; TC_24_0.dT = TC_24_0.port_a.T - TC_24_0.port_b.T; TC_24_0.port_a.Q_flow = TC_24_0.Q_flow; TC_24_0.port_b.Q_flow = -TC_24_0.Q_flow; TC_25_0.Q_flow = TC_25_0.G * TC_25_0.dT; TC_25_0.dT = TC_25_0.port_a.T - TC_25_0.port_b.T; TC_25_0.port_a.Q_flow = TC_25_0.Q_flow; TC_25_0.port_b.Q_flow = -TC_25_0.Q_flow; TC_26_0.Q_flow = TC_26_0.G * TC_26_0.dT; TC_26_0.dT = TC_26_0.port_a.T - TC_26_0.port_b.T; TC_26_0.port_a.Q_flow = TC_26_0.Q_flow; TC_26_0.port_b.Q_flow = -TC_26_0.Q_flow; TC_27_0.Q_flow = TC_27_0.G * TC_27_0.dT; TC_27_0.dT = TC_27_0.port_a.T - TC_27_0.port_b.T; TC_27_0.port_a.Q_flow = TC_27_0.Q_flow; TC_27_0.port_b.Q_flow = -TC_27_0.Q_flow; TC_28_0.Q_flow = TC_28_0.G * TC_28_0.dT; TC_28_0.dT = TC_28_0.port_a.T - TC_28_0.port_b.T; TC_28_0.port_a.Q_flow = TC_28_0.Q_flow; TC_28_0.port_b.Q_flow = -TC_28_0.Q_flow; TC_29_0.Q_flow = TC_29_0.G * TC_29_0.dT; TC_29_0.dT = TC_29_0.port_a.T - TC_29_0.port_b.T; TC_29_0.port_a.Q_flow = TC_29_0.Q_flow; TC_29_0.port_b.Q_flow = -TC_29_0.Q_flow; TC_30_0.Q_flow = TC_30_0.G * TC_30_0.dT; TC_30_0.dT = TC_30_0.port_a.T - TC_30_0.port_b.T; TC_30_0.port_a.Q_flow = TC_30_0.Q_flow; TC_30_0.port_b.Q_flow = -TC_30_0.Q_flow; TC_31_0.Q_flow = TC_31_0.G * TC_31_0.dT; TC_31_0.dT = TC_31_0.port_a.T - TC_31_0.port_b.T; TC_31_0.port_a.Q_flow = TC_31_0.Q_flow; TC_31_0.port_b.Q_flow = -TC_31_0.Q_flow; TC_32_0.Q_flow = TC_32_0.G * TC_32_0.dT; TC_32_0.dT = TC_32_0.port_a.T - TC_32_0.port_b.T; TC_32_0.port_a.Q_flow = TC_32_0.Q_flow; TC_32_0.port_b.Q_flow = -TC_32_0.Q_flow; TC_33_0.Q_flow = TC_33_0.G * TC_33_0.dT; TC_33_0.dT = TC_33_0.port_a.T - TC_33_0.port_b.T; TC_33_0.port_a.Q_flow = TC_33_0.Q_flow; TC_33_0.port_b.Q_flow = -TC_33_0.Q_flow; TC_34_0.Q_flow = TC_34_0.G * TC_34_0.dT; TC_34_0.dT = TC_34_0.port_a.T - TC_34_0.port_b.T; TC_34_0.port_a.Q_flow = TC_34_0.Q_flow; TC_34_0.port_b.Q_flow = -TC_34_0.Q_flow; TC_35_0.Q_flow = TC_35_0.G * TC_35_0.dT; TC_35_0.dT = TC_35_0.port_a.T - TC_35_0.port_b.T; TC_35_0.port_a.Q_flow = TC_35_0.Q_flow; TC_35_0.port_b.Q_flow = -TC_35_0.Q_flow; TC_36_0.Q_flow = TC_36_0.G * TC_36_0.dT; TC_36_0.dT = TC_36_0.port_a.T - TC_36_0.port_b.T; TC_36_0.port_a.Q_flow = TC_36_0.Q_flow; TC_36_0.port_b.Q_flow = -TC_36_0.Q_flow; TC_37_0.Q_flow = TC_37_0.G * TC_37_0.dT; TC_37_0.dT = TC_37_0.port_a.T - TC_37_0.port_b.T; TC_37_0.port_a.Q_flow = TC_37_0.Q_flow; TC_37_0.port_b.Q_flow = -TC_37_0.Q_flow; TC_38_0.Q_flow = TC_38_0.G * TC_38_0.dT; TC_38_0.dT = TC_38_0.port_a.T - TC_38_0.port_b.T; TC_38_0.port_a.Q_flow = TC_38_0.Q_flow; TC_38_0.port_b.Q_flow = -TC_38_0.Q_flow; TC_39_0.Q_flow = TC_39_0.G * TC_39_0.dT; TC_39_0.dT = TC_39_0.port_a.T - TC_39_0.port_b.T; TC_39_0.port_a.Q_flow = TC_39_0.Q_flow; TC_39_0.port_b.Q_flow = -TC_39_0.Q_flow; TC_40_0.Q_flow = TC_40_0.G * TC_40_0.dT; TC_40_0.dT = TC_40_0.port_a.T - TC_40_0.port_b.T; TC_40_0.port_a.Q_flow = TC_40_0.Q_flow; TC_40_0.port_b.Q_flow = -TC_40_0.Q_flow; TC_41_0.Q_flow = TC_41_0.G * TC_41_0.dT; TC_41_0.dT = TC_41_0.port_a.T - TC_41_0.port_b.T; TC_41_0.port_a.Q_flow = TC_41_0.Q_flow; TC_41_0.port_b.Q_flow = -TC_41_0.Q_flow; TC_42_0.Q_flow = TC_42_0.G * TC_42_0.dT; TC_42_0.dT = TC_42_0.port_a.T - TC_42_0.port_b.T; TC_42_0.port_a.Q_flow = TC_42_0.Q_flow; TC_42_0.port_b.Q_flow = -TC_42_0.Q_flow; TC_43_0.Q_flow = TC_43_0.G * TC_43_0.dT; TC_43_0.dT = TC_43_0.port_a.T - TC_43_0.port_b.T; TC_43_0.port_a.Q_flow = TC_43_0.Q_flow; TC_43_0.port_b.Q_flow = -TC_43_0.Q_flow; TC_44_0.Q_flow = TC_44_0.G * TC_44_0.dT; TC_44_0.dT = TC_44_0.port_a.T - TC_44_0.port_b.T; TC_44_0.port_a.Q_flow = TC_44_0.Q_flow; TC_44_0.port_b.Q_flow = -TC_44_0.Q_flow; TC_45_0.Q_flow = TC_45_0.G * TC_45_0.dT; TC_45_0.dT = TC_45_0.port_a.T - TC_45_0.port_b.T; TC_45_0.port_a.Q_flow = TC_45_0.Q_flow; TC_45_0.port_b.Q_flow = -TC_45_0.Q_flow; TC_46_0.Q_flow = TC_46_0.G * TC_46_0.dT; TC_46_0.dT = TC_46_0.port_a.T - TC_46_0.port_b.T; TC_46_0.port_a.Q_flow = TC_46_0.Q_flow; TC_46_0.port_b.Q_flow = -TC_46_0.Q_flow; TC_47_0.Q_flow = TC_47_0.G * TC_47_0.dT; TC_47_0.dT = TC_47_0.port_a.T - TC_47_0.port_b.T; TC_47_0.port_a.Q_flow = TC_47_0.Q_flow; TC_47_0.port_b.Q_flow = -TC_47_0.Q_flow; TC_48_0.Q_flow = TC_48_0.G * TC_48_0.dT; TC_48_0.dT = TC_48_0.port_a.T - TC_48_0.port_b.T; TC_48_0.port_a.Q_flow = TC_48_0.Q_flow; TC_48_0.port_b.Q_flow = -TC_48_0.Q_flow; TC_49_0.Q_flow = TC_49_0.G * TC_49_0.dT; TC_49_0.dT = TC_49_0.port_a.T - TC_49_0.port_b.T; TC_49_0.port_a.Q_flow = TC_49_0.Q_flow; TC_49_0.port_b.Q_flow = -TC_49_0.Q_flow; TC_50_0.Q_flow = TC_50_0.G * TC_50_0.dT; TC_50_0.dT = TC_50_0.port_a.T - TC_50_0.port_b.T; TC_50_0.port_a.Q_flow = TC_50_0.Q_flow; TC_50_0.port_b.Q_flow = -TC_50_0.Q_flow; TC_51_0.Q_flow = TC_51_0.G * TC_51_0.dT; TC_51_0.dT = TC_51_0.port_a.T - TC_51_0.port_b.T; TC_51_0.port_a.Q_flow = TC_51_0.Q_flow; TC_51_0.port_b.Q_flow = -TC_51_0.Q_flow; TC_52_0.Q_flow = TC_52_0.G * TC_52_0.dT; TC_52_0.dT = TC_52_0.port_a.T - TC_52_0.port_b.T; TC_52_0.port_a.Q_flow = TC_52_0.Q_flow; TC_52_0.port_b.Q_flow = -TC_52_0.Q_flow; TC_53_0.Q_flow = TC_53_0.G * TC_53_0.dT; TC_53_0.dT = TC_53_0.port_a.T - TC_53_0.port_b.T; TC_53_0.port_a.Q_flow = TC_53_0.Q_flow; TC_53_0.port_b.Q_flow = -TC_53_0.Q_flow; TC_54_0.Q_flow = TC_54_0.G * TC_54_0.dT; TC_54_0.dT = TC_54_0.port_a.T - TC_54_0.port_b.T; TC_54_0.port_a.Q_flow = TC_54_0.Q_flow; TC_54_0.port_b.Q_flow = -TC_54_0.Q_flow; TC_55_0.Q_flow = TC_55_0.G * TC_55_0.dT; TC_55_0.dT = TC_55_0.port_a.T - TC_55_0.port_b.T; TC_55_0.port_a.Q_flow = TC_55_0.Q_flow; TC_55_0.port_b.Q_flow = -TC_55_0.Q_flow; TC_56_0.Q_flow = TC_56_0.G * TC_56_0.dT; TC_56_0.dT = TC_56_0.port_a.T - TC_56_0.port_b.T; TC_56_0.port_a.Q_flow = TC_56_0.Q_flow; TC_56_0.port_b.Q_flow = -TC_56_0.Q_flow; TC_57_0.Q_flow = TC_57_0.G * TC_57_0.dT; TC_57_0.dT = TC_57_0.port_a.T - TC_57_0.port_b.T; TC_57_0.port_a.Q_flow = TC_57_0.Q_flow; TC_57_0.port_b.Q_flow = -TC_57_0.Q_flow; TC_58_0.Q_flow = TC_58_0.G * TC_58_0.dT; TC_58_0.dT = TC_58_0.port_a.T - TC_58_0.port_b.T; TC_58_0.port_a.Q_flow = TC_58_0.Q_flow; TC_58_0.port_b.Q_flow = -TC_58_0.Q_flow; TC_59_0.Q_flow = TC_59_0.G * TC_59_0.dT; TC_59_0.dT = TC_59_0.port_a.T - TC_59_0.port_b.T; TC_59_0.port_a.Q_flow = TC_59_0.Q_flow; TC_59_0.port_b.Q_flow = -TC_59_0.Q_flow; TC_60_0.Q_flow = TC_60_0.G * TC_60_0.dT; TC_60_0.dT = TC_60_0.port_a.T - TC_60_0.port_b.T; TC_60_0.port_a.Q_flow = TC_60_0.Q_flow; TC_60_0.port_b.Q_flow = -TC_60_0.Q_flow; TC_61_0.Q_flow = TC_61_0.G * TC_61_0.dT; TC_61_0.dT = TC_61_0.port_a.T - TC_61_0.port_b.T; TC_61_0.port_a.Q_flow = TC_61_0.Q_flow; TC_61_0.port_b.Q_flow = -TC_61_0.Q_flow; TC_62_0.Q_flow = TC_62_0.G * TC_62_0.dT; TC_62_0.dT = TC_62_0.port_a.T - TC_62_0.port_b.T; TC_62_0.port_a.Q_flow = TC_62_0.Q_flow; TC_62_0.port_b.Q_flow = -TC_62_0.Q_flow; TC_63_0.Q_flow = TC_63_0.G * TC_63_0.dT; TC_63_0.dT = TC_63_0.port_a.T - TC_63_0.port_b.T; TC_63_0.port_a.Q_flow = TC_63_0.Q_flow; TC_63_0.port_b.Q_flow = -TC_63_0.Q_flow; TC_64_0.Q_flow = TC_64_0.G * TC_64_0.dT; TC_64_0.dT = TC_64_0.port_a.T - TC_64_0.port_b.T; TC_64_0.port_a.Q_flow = TC_64_0.Q_flow; TC_64_0.port_b.Q_flow = -TC_64_0.Q_flow; TC_65_0.Q_flow = TC_65_0.G * TC_65_0.dT; TC_65_0.dT = TC_65_0.port_a.T - TC_65_0.port_b.T; TC_65_0.port_a.Q_flow = TC_65_0.Q_flow; TC_65_0.port_b.Q_flow = -TC_65_0.Q_flow; TC_66_0.Q_flow = TC_66_0.G * TC_66_0.dT; TC_66_0.dT = TC_66_0.port_a.T - TC_66_0.port_b.T; TC_66_0.port_a.Q_flow = TC_66_0.Q_flow; TC_66_0.port_b.Q_flow = -TC_66_0.Q_flow; TC_67_0.Q_flow = TC_67_0.G * TC_67_0.dT; TC_67_0.dT = TC_67_0.port_a.T - TC_67_0.port_b.T; TC_67_0.port_a.Q_flow = TC_67_0.Q_flow; TC_67_0.port_b.Q_flow = -TC_67_0.Q_flow; TC_68_0.Q_flow = TC_68_0.G * TC_68_0.dT; TC_68_0.dT = TC_68_0.port_a.T - TC_68_0.port_b.T; TC_68_0.port_a.Q_flow = TC_68_0.Q_flow; TC_68_0.port_b.Q_flow = -TC_68_0.Q_flow; TC_69_0.Q_flow = TC_69_0.G * TC_69_0.dT; TC_69_0.dT = TC_69_0.port_a.T - TC_69_0.port_b.T; TC_69_0.port_a.Q_flow = TC_69_0.Q_flow; TC_69_0.port_b.Q_flow = -TC_69_0.Q_flow; TC_70_0.Q_flow = TC_70_0.G * TC_70_0.dT; TC_70_0.dT = TC_70_0.port_a.T - TC_70_0.port_b.T; TC_70_0.port_a.Q_flow = TC_70_0.Q_flow; TC_70_0.port_b.Q_flow = -TC_70_0.Q_flow; TC_71_0.Q_flow = TC_71_0.G * TC_71_0.dT; TC_71_0.dT = TC_71_0.port_a.T - TC_71_0.port_b.T; TC_71_0.port_a.Q_flow = TC_71_0.Q_flow; TC_71_0.port_b.Q_flow = -TC_71_0.Q_flow; TC_72_0.Q_flow = TC_72_0.G * TC_72_0.dT; TC_72_0.dT = TC_72_0.port_a.T - TC_72_0.port_b.T; TC_72_0.port_a.Q_flow = TC_72_0.Q_flow; TC_72_0.port_b.Q_flow = -TC_72_0.Q_flow; TC_73_0.Q_flow = TC_73_0.G * TC_73_0.dT; TC_73_0.dT = TC_73_0.port_a.T - TC_73_0.port_b.T; TC_73_0.port_a.Q_flow = TC_73_0.Q_flow; TC_73_0.port_b.Q_flow = -TC_73_0.Q_flow; TC_74_0.Q_flow = TC_74_0.G * TC_74_0.dT; TC_74_0.dT = TC_74_0.port_a.T - TC_74_0.port_b.T; TC_74_0.port_a.Q_flow = TC_74_0.Q_flow; TC_74_0.port_b.Q_flow = -TC_74_0.Q_flow; TC_75_0.Q_flow = TC_75_0.G * TC_75_0.dT; TC_75_0.dT = TC_75_0.port_a.T - TC_75_0.port_b.T; TC_75_0.port_a.Q_flow = TC_75_0.Q_flow; TC_75_0.port_b.Q_flow = -TC_75_0.Q_flow; TC_76_0.Q_flow = TC_76_0.G * TC_76_0.dT; TC_76_0.dT = TC_76_0.port_a.T - TC_76_0.port_b.T; TC_76_0.port_a.Q_flow = TC_76_0.Q_flow; TC_76_0.port_b.Q_flow = -TC_76_0.Q_flow; TC_77_0.Q_flow = TC_77_0.G * TC_77_0.dT; TC_77_0.dT = TC_77_0.port_a.T - TC_77_0.port_b.T; TC_77_0.port_a.Q_flow = TC_77_0.Q_flow; TC_77_0.port_b.Q_flow = -TC_77_0.Q_flow; TC_78_0.Q_flow = TC_78_0.G * TC_78_0.dT; TC_78_0.dT = TC_78_0.port_a.T - TC_78_0.port_b.T; TC_78_0.port_a.Q_flow = TC_78_0.Q_flow; TC_78_0.port_b.Q_flow = -TC_78_0.Q_flow; TC_79_0.Q_flow = TC_79_0.G * TC_79_0.dT; TC_79_0.dT = TC_79_0.port_a.T - TC_79_0.port_b.T; TC_79_0.port_a.Q_flow = TC_79_0.Q_flow; TC_79_0.port_b.Q_flow = -TC_79_0.Q_flow; TC_80_0.Q_flow = TC_80_0.G * TC_80_0.dT; TC_80_0.dT = TC_80_0.port_a.T - TC_80_0.port_b.T; TC_80_0.port_a.Q_flow = TC_80_0.Q_flow; TC_80_0.port_b.Q_flow = -TC_80_0.Q_flow; TC_81_0.Q_flow = TC_81_0.G * TC_81_0.dT; TC_81_0.dT = TC_81_0.port_a.T - TC_81_0.port_b.T; TC_81_0.port_a.Q_flow = TC_81_0.Q_flow; TC_81_0.port_b.Q_flow = -TC_81_0.Q_flow; TC_82_0.Q_flow = TC_82_0.G * TC_82_0.dT; TC_82_0.dT = TC_82_0.port_a.T - TC_82_0.port_b.T; TC_82_0.port_a.Q_flow = TC_82_0.Q_flow; TC_82_0.port_b.Q_flow = -TC_82_0.Q_flow; TC_83_0.Q_flow = TC_83_0.G * TC_83_0.dT; TC_83_0.dT = TC_83_0.port_a.T - TC_83_0.port_b.T; TC_83_0.port_a.Q_flow = TC_83_0.Q_flow; TC_83_0.port_b.Q_flow = -TC_83_0.Q_flow; TC_84_0.Q_flow = TC_84_0.G * TC_84_0.dT; TC_84_0.dT = TC_84_0.port_a.T - TC_84_0.port_b.T; TC_84_0.port_a.Q_flow = TC_84_0.Q_flow; TC_84_0.port_b.Q_flow = -TC_84_0.Q_flow; TC_85_0.Q_flow = TC_85_0.G * TC_85_0.dT; TC_85_0.dT = TC_85_0.port_a.T - TC_85_0.port_b.T; TC_85_0.port_a.Q_flow = TC_85_0.Q_flow; TC_85_0.port_b.Q_flow = -TC_85_0.Q_flow; TC_86_0.Q_flow = TC_86_0.G * TC_86_0.dT; TC_86_0.dT = TC_86_0.port_a.T - TC_86_0.port_b.T; TC_86_0.port_a.Q_flow = TC_86_0.Q_flow; TC_86_0.port_b.Q_flow = -TC_86_0.Q_flow; TC_87_0.Q_flow = TC_87_0.G * TC_87_0.dT; TC_87_0.dT = TC_87_0.port_a.T - TC_87_0.port_b.T; TC_87_0.port_a.Q_flow = TC_87_0.Q_flow; TC_87_0.port_b.Q_flow = -TC_87_0.Q_flow; TC_88_0.Q_flow = TC_88_0.G * TC_88_0.dT; TC_88_0.dT = TC_88_0.port_a.T - TC_88_0.port_b.T; TC_88_0.port_a.Q_flow = TC_88_0.Q_flow; TC_88_0.port_b.Q_flow = -TC_88_0.Q_flow; TC_89_0.Q_flow = TC_89_0.G * TC_89_0.dT; TC_89_0.dT = TC_89_0.port_a.T - TC_89_0.port_b.T; TC_89_0.port_a.Q_flow = TC_89_0.Q_flow; TC_89_0.port_b.Q_flow = -TC_89_0.Q_flow; TC_90_0.Q_flow = TC_90_0.G * TC_90_0.dT; TC_90_0.dT = TC_90_0.port_a.T - TC_90_0.port_b.T; TC_90_0.port_a.Q_flow = TC_90_0.Q_flow; TC_90_0.port_b.Q_flow = -TC_90_0.Q_flow; TC_91_0.Q_flow = TC_91_0.G * TC_91_0.dT; TC_91_0.dT = TC_91_0.port_a.T - TC_91_0.port_b.T; TC_91_0.port_a.Q_flow = TC_91_0.Q_flow; TC_91_0.port_b.Q_flow = -TC_91_0.Q_flow; TC_92_0.Q_flow = TC_92_0.G * TC_92_0.dT; TC_92_0.dT = TC_92_0.port_a.T - TC_92_0.port_b.T; TC_92_0.port_a.Q_flow = TC_92_0.Q_flow; TC_92_0.port_b.Q_flow = -TC_92_0.Q_flow; TC_93_0.Q_flow = TC_93_0.G * TC_93_0.dT; TC_93_0.dT = TC_93_0.port_a.T - TC_93_0.port_b.T; TC_93_0.port_a.Q_flow = TC_93_0.Q_flow; TC_93_0.port_b.Q_flow = -TC_93_0.Q_flow; TC_94_0.Q_flow = TC_94_0.G * TC_94_0.dT; TC_94_0.dT = TC_94_0.port_a.T - TC_94_0.port_b.T; TC_94_0.port_a.Q_flow = TC_94_0.Q_flow; TC_94_0.port_b.Q_flow = -TC_94_0.Q_flow; TC_95_0.Q_flow = TC_95_0.G * TC_95_0.dT; TC_95_0.dT = TC_95_0.port_a.T - TC_95_0.port_b.T; TC_95_0.port_a.Q_flow = TC_95_0.Q_flow; TC_95_0.port_b.Q_flow = -TC_95_0.Q_flow; TC_96_0.Q_flow = TC_96_0.G * TC_96_0.dT; TC_96_0.dT = TC_96_0.port_a.T - TC_96_0.port_b.T; TC_96_0.port_a.Q_flow = TC_96_0.Q_flow; TC_96_0.port_b.Q_flow = -TC_96_0.Q_flow; TC_97_0.Q_flow = TC_97_0.G * TC_97_0.dT; TC_97_0.dT = TC_97_0.port_a.T - TC_97_0.port_b.T; TC_97_0.port_a.Q_flow = TC_97_0.Q_flow; TC_97_0.port_b.Q_flow = -TC_97_0.Q_flow; TC_98_0.Q_flow = TC_98_0.G * TC_98_0.dT; TC_98_0.dT = TC_98_0.port_a.T - TC_98_0.port_b.T; TC_98_0.port_a.Q_flow = TC_98_0.Q_flow; TC_98_0.port_b.Q_flow = -TC_98_0.Q_flow; TC_99_0.Q_flow = TC_99_0.G * TC_99_0.dT; TC_99_0.dT = TC_99_0.port_a.T - TC_99_0.port_b.T; TC_99_0.port_a.Q_flow = TC_99_0.Q_flow; TC_99_0.port_b.Q_flow = -TC_99_0.Q_flow; TC_100_0.Q_flow = TC_100_0.G * TC_100_0.dT; TC_100_0.dT = TC_100_0.port_a.T - TC_100_0.port_b.T; TC_100_0.port_a.Q_flow = TC_100_0.Q_flow; TC_100_0.port_b.Q_flow = -TC_100_0.Q_flow; TC_101_0.Q_flow = TC_101_0.G * TC_101_0.dT; TC_101_0.dT = TC_101_0.port_a.T - TC_101_0.port_b.T; TC_101_0.port_a.Q_flow = TC_101_0.Q_flow; TC_101_0.port_b.Q_flow = -TC_101_0.Q_flow; TC_102_0.Q_flow = TC_102_0.G * TC_102_0.dT; TC_102_0.dT = TC_102_0.port_a.T - TC_102_0.port_b.T; TC_102_0.port_a.Q_flow = TC_102_0.Q_flow; TC_102_0.port_b.Q_flow = -TC_102_0.Q_flow; TC_103_0.Q_flow = TC_103_0.G * TC_103_0.dT; TC_103_0.dT = TC_103_0.port_a.T - TC_103_0.port_b.T; TC_103_0.port_a.Q_flow = TC_103_0.Q_flow; TC_103_0.port_b.Q_flow = -TC_103_0.Q_flow; TC_104_0.Q_flow = TC_104_0.G * TC_104_0.dT; TC_104_0.dT = TC_104_0.port_a.T - TC_104_0.port_b.T; TC_104_0.port_a.Q_flow = TC_104_0.Q_flow; TC_104_0.port_b.Q_flow = -TC_104_0.Q_flow; TC_105_0.Q_flow = TC_105_0.G * TC_105_0.dT; TC_105_0.dT = TC_105_0.port_a.T - TC_105_0.port_b.T; TC_105_0.port_a.Q_flow = TC_105_0.Q_flow; TC_105_0.port_b.Q_flow = -TC_105_0.Q_flow; TC_106_0.Q_flow = TC_106_0.G * TC_106_0.dT; TC_106_0.dT = TC_106_0.port_a.T - TC_106_0.port_b.T; TC_106_0.port_a.Q_flow = TC_106_0.Q_flow; TC_106_0.port_b.Q_flow = -TC_106_0.Q_flow; TC_107_0.Q_flow = TC_107_0.G * TC_107_0.dT; TC_107_0.dT = TC_107_0.port_a.T - TC_107_0.port_b.T; TC_107_0.port_a.Q_flow = TC_107_0.Q_flow; TC_107_0.port_b.Q_flow = -TC_107_0.Q_flow; TC_108_0.Q_flow = TC_108_0.G * TC_108_0.dT; TC_108_0.dT = TC_108_0.port_a.T - TC_108_0.port_b.T; TC_108_0.port_a.Q_flow = TC_108_0.Q_flow; TC_108_0.port_b.Q_flow = -TC_108_0.Q_flow; TC_109_0.Q_flow = TC_109_0.G * TC_109_0.dT; TC_109_0.dT = TC_109_0.port_a.T - TC_109_0.port_b.T; TC_109_0.port_a.Q_flow = TC_109_0.Q_flow; TC_109_0.port_b.Q_flow = -TC_109_0.Q_flow; TC_110_0.Q_flow = TC_110_0.G * TC_110_0.dT; TC_110_0.dT = TC_110_0.port_a.T - TC_110_0.port_b.T; TC_110_0.port_a.Q_flow = TC_110_0.Q_flow; TC_110_0.port_b.Q_flow = -TC_110_0.Q_flow; TC_111_0.Q_flow = TC_111_0.G * TC_111_0.dT; TC_111_0.dT = TC_111_0.port_a.T - TC_111_0.port_b.T; TC_111_0.port_a.Q_flow = TC_111_0.Q_flow; TC_111_0.port_b.Q_flow = -TC_111_0.Q_flow; TC_112_0.Q_flow = TC_112_0.G * TC_112_0.dT; TC_112_0.dT = TC_112_0.port_a.T - TC_112_0.port_b.T; TC_112_0.port_a.Q_flow = TC_112_0.Q_flow; TC_112_0.port_b.Q_flow = -TC_112_0.Q_flow; TC_113_0.Q_flow = TC_113_0.G * TC_113_0.dT; TC_113_0.dT = TC_113_0.port_a.T - TC_113_0.port_b.T; TC_113_0.port_a.Q_flow = TC_113_0.Q_flow; TC_113_0.port_b.Q_flow = -TC_113_0.Q_flow; TC_114_0.Q_flow = TC_114_0.G * TC_114_0.dT; TC_114_0.dT = TC_114_0.port_a.T - TC_114_0.port_b.T; TC_114_0.port_a.Q_flow = TC_114_0.Q_flow; TC_114_0.port_b.Q_flow = -TC_114_0.Q_flow; TC_115_0.Q_flow = TC_115_0.G * TC_115_0.dT; TC_115_0.dT = TC_115_0.port_a.T - TC_115_0.port_b.T; TC_115_0.port_a.Q_flow = TC_115_0.Q_flow; TC_115_0.port_b.Q_flow = -TC_115_0.Q_flow; TC_116_0.Q_flow = TC_116_0.G * TC_116_0.dT; TC_116_0.dT = TC_116_0.port_a.T - TC_116_0.port_b.T; TC_116_0.port_a.Q_flow = TC_116_0.Q_flow; TC_116_0.port_b.Q_flow = -TC_116_0.Q_flow; TC_117_0.Q_flow = TC_117_0.G * TC_117_0.dT; TC_117_0.dT = TC_117_0.port_a.T - TC_117_0.port_b.T; TC_117_0.port_a.Q_flow = TC_117_0.Q_flow; TC_117_0.port_b.Q_flow = -TC_117_0.Q_flow; TC_118_0.Q_flow = TC_118_0.G * TC_118_0.dT; TC_118_0.dT = TC_118_0.port_a.T - TC_118_0.port_b.T; TC_118_0.port_a.Q_flow = TC_118_0.Q_flow; TC_118_0.port_b.Q_flow = -TC_118_0.Q_flow; TC_119_0.Q_flow = TC_119_0.G * TC_119_0.dT; TC_119_0.dT = TC_119_0.port_a.T - TC_119_0.port_b.T; TC_119_0.port_a.Q_flow = TC_119_0.Q_flow; TC_119_0.port_b.Q_flow = -TC_119_0.Q_flow; TC_120_0.Q_flow = TC_120_0.G * TC_120_0.dT; TC_120_0.dT = TC_120_0.port_a.T - TC_120_0.port_b.T; TC_120_0.port_a.Q_flow = TC_120_0.Q_flow; TC_120_0.port_b.Q_flow = -TC_120_0.Q_flow; TC_121_0.Q_flow = TC_121_0.G * TC_121_0.dT; TC_121_0.dT = TC_121_0.port_a.T - TC_121_0.port_b.T; TC_121_0.port_a.Q_flow = TC_121_0.Q_flow; TC_121_0.port_b.Q_flow = -TC_121_0.Q_flow; TC_122_0.Q_flow = TC_122_0.G * TC_122_0.dT; TC_122_0.dT = TC_122_0.port_a.T - TC_122_0.port_b.T; TC_122_0.port_a.Q_flow = TC_122_0.Q_flow; TC_122_0.port_b.Q_flow = -TC_122_0.Q_flow; TC_123_0.Q_flow = TC_123_0.G * TC_123_0.dT; TC_123_0.dT = TC_123_0.port_a.T - TC_123_0.port_b.T; TC_123_0.port_a.Q_flow = TC_123_0.Q_flow; TC_123_0.port_b.Q_flow = -TC_123_0.Q_flow; TC_124_0.Q_flow = TC_124_0.G * TC_124_0.dT; TC_124_0.dT = TC_124_0.port_a.T - TC_124_0.port_b.T; TC_124_0.port_a.Q_flow = TC_124_0.Q_flow; TC_124_0.port_b.Q_flow = -TC_124_0.Q_flow; TC_125_0.Q_flow = TC_125_0.G * TC_125_0.dT; TC_125_0.dT = TC_125_0.port_a.T - TC_125_0.port_b.T; TC_125_0.port_a.Q_flow = TC_125_0.Q_flow; TC_125_0.port_b.Q_flow = -TC_125_0.Q_flow; TC_126_0.Q_flow = TC_126_0.G * TC_126_0.dT; TC_126_0.dT = TC_126_0.port_a.T - TC_126_0.port_b.T; TC_126_0.port_a.Q_flow = TC_126_0.Q_flow; TC_126_0.port_b.Q_flow = -TC_126_0.Q_flow; TC_127_0.Q_flow = TC_127_0.G * TC_127_0.dT; TC_127_0.dT = TC_127_0.port_a.T - TC_127_0.port_b.T; TC_127_0.port_a.Q_flow = TC_127_0.Q_flow; TC_127_0.port_b.Q_flow = -TC_127_0.Q_flow; TC_128_0.Q_flow = TC_128_0.G * TC_128_0.dT; TC_128_0.dT = TC_128_0.port_a.T - TC_128_0.port_b.T; TC_128_0.port_a.Q_flow = TC_128_0.Q_flow; TC_128_0.port_b.Q_flow = -TC_128_0.Q_flow; TC_129_0.Q_flow = TC_129_0.G * TC_129_0.dT; TC_129_0.dT = TC_129_0.port_a.T - TC_129_0.port_b.T; TC_129_0.port_a.Q_flow = TC_129_0.Q_flow; TC_129_0.port_b.Q_flow = -TC_129_0.Q_flow; TC_130_0.Q_flow = TC_130_0.G * TC_130_0.dT; TC_130_0.dT = TC_130_0.port_a.T - TC_130_0.port_b.T; TC_130_0.port_a.Q_flow = TC_130_0.Q_flow; TC_130_0.port_b.Q_flow = -TC_130_0.Q_flow; TC_131_0.Q_flow = TC_131_0.G * TC_131_0.dT; TC_131_0.dT = TC_131_0.port_a.T - TC_131_0.port_b.T; TC_131_0.port_a.Q_flow = TC_131_0.Q_flow; TC_131_0.port_b.Q_flow = -TC_131_0.Q_flow; TC_132_0.Q_flow = TC_132_0.G * TC_132_0.dT; TC_132_0.dT = TC_132_0.port_a.T - TC_132_0.port_b.T; TC_132_0.port_a.Q_flow = TC_132_0.Q_flow; TC_132_0.port_b.Q_flow = -TC_132_0.Q_flow; TC_133_0.Q_flow = TC_133_0.G * TC_133_0.dT; TC_133_0.dT = TC_133_0.port_a.T - TC_133_0.port_b.T; TC_133_0.port_a.Q_flow = TC_133_0.Q_flow; TC_133_0.port_b.Q_flow = -TC_133_0.Q_flow; TC_134_0.Q_flow = TC_134_0.G * TC_134_0.dT; TC_134_0.dT = TC_134_0.port_a.T - TC_134_0.port_b.T; TC_134_0.port_a.Q_flow = TC_134_0.Q_flow; TC_134_0.port_b.Q_flow = -TC_134_0.Q_flow; TC_135_0.Q_flow = TC_135_0.G * TC_135_0.dT; TC_135_0.dT = TC_135_0.port_a.T - TC_135_0.port_b.T; TC_135_0.port_a.Q_flow = TC_135_0.Q_flow; TC_135_0.port_b.Q_flow = -TC_135_0.Q_flow; TC_136_0.Q_flow = TC_136_0.G * TC_136_0.dT; TC_136_0.dT = TC_136_0.port_a.T - TC_136_0.port_b.T; TC_136_0.port_a.Q_flow = TC_136_0.Q_flow; TC_136_0.port_b.Q_flow = -TC_136_0.Q_flow; TC_137_0.Q_flow = TC_137_0.G * TC_137_0.dT; TC_137_0.dT = TC_137_0.port_a.T - TC_137_0.port_b.T; TC_137_0.port_a.Q_flow = TC_137_0.Q_flow; TC_137_0.port_b.Q_flow = -TC_137_0.Q_flow; TC_138_0.Q_flow = TC_138_0.G * TC_138_0.dT; TC_138_0.dT = TC_138_0.port_a.T - TC_138_0.port_b.T; TC_138_0.port_a.Q_flow = TC_138_0.Q_flow; TC_138_0.port_b.Q_flow = -TC_138_0.Q_flow; TC_139_0.Q_flow = TC_139_0.G * TC_139_0.dT; TC_139_0.dT = TC_139_0.port_a.T - TC_139_0.port_b.T; TC_139_0.port_a.Q_flow = TC_139_0.Q_flow; TC_139_0.port_b.Q_flow = -TC_139_0.Q_flow; TC_140_0.Q_flow = TC_140_0.G * TC_140_0.dT; TC_140_0.dT = TC_140_0.port_a.T - TC_140_0.port_b.T; TC_140_0.port_a.Q_flow = TC_140_0.Q_flow; TC_140_0.port_b.Q_flow = -TC_140_0.Q_flow; TC_141_0.Q_flow = TC_141_0.G * TC_141_0.dT; TC_141_0.dT = TC_141_0.port_a.T - TC_141_0.port_b.T; TC_141_0.port_a.Q_flow = TC_141_0.Q_flow; TC_141_0.port_b.Q_flow = -TC_141_0.Q_flow; TC_142_0.Q_flow = TC_142_0.G * TC_142_0.dT; TC_142_0.dT = TC_142_0.port_a.T - TC_142_0.port_b.T; TC_142_0.port_a.Q_flow = TC_142_0.Q_flow; TC_142_0.port_b.Q_flow = -TC_142_0.Q_flow; TC_143_0.Q_flow = TC_143_0.G * TC_143_0.dT; TC_143_0.dT = TC_143_0.port_a.T - TC_143_0.port_b.T; TC_143_0.port_a.Q_flow = TC_143_0.Q_flow; TC_143_0.port_b.Q_flow = -TC_143_0.Q_flow; TC_144_0.Q_flow = TC_144_0.G * TC_144_0.dT; TC_144_0.dT = TC_144_0.port_a.T - TC_144_0.port_b.T; TC_144_0.port_a.Q_flow = TC_144_0.Q_flow; TC_144_0.port_b.Q_flow = -TC_144_0.Q_flow; TC_145_0.Q_flow = TC_145_0.G * TC_145_0.dT; TC_145_0.dT = TC_145_0.port_a.T - TC_145_0.port_b.T; TC_145_0.port_a.Q_flow = TC_145_0.Q_flow; TC_145_0.port_b.Q_flow = -TC_145_0.Q_flow; TC_146_0.Q_flow = TC_146_0.G * TC_146_0.dT; TC_146_0.dT = TC_146_0.port_a.T - TC_146_0.port_b.T; TC_146_0.port_a.Q_flow = TC_146_0.Q_flow; TC_146_0.port_b.Q_flow = -TC_146_0.Q_flow; TC_147_0.Q_flow = TC_147_0.G * TC_147_0.dT; TC_147_0.dT = TC_147_0.port_a.T - TC_147_0.port_b.T; TC_147_0.port_a.Q_flow = TC_147_0.Q_flow; TC_147_0.port_b.Q_flow = -TC_147_0.Q_flow; TC_148_0.Q_flow = TC_148_0.G * TC_148_0.dT; TC_148_0.dT = TC_148_0.port_a.T - TC_148_0.port_b.T; TC_148_0.port_a.Q_flow = TC_148_0.Q_flow; TC_148_0.port_b.Q_flow = -TC_148_0.Q_flow; TC_149_0.Q_flow = TC_149_0.G * TC_149_0.dT; TC_149_0.dT = TC_149_0.port_a.T - TC_149_0.port_b.T; TC_149_0.port_a.Q_flow = TC_149_0.Q_flow; TC_149_0.port_b.Q_flow = -TC_149_0.Q_flow; TC_150_0.Q_flow = TC_150_0.G * TC_150_0.dT; TC_150_0.dT = TC_150_0.port_a.T - TC_150_0.port_b.T; TC_150_0.port_a.Q_flow = TC_150_0.Q_flow; TC_150_0.port_b.Q_flow = -TC_150_0.Q_flow; TC_151_0.Q_flow = TC_151_0.G * TC_151_0.dT; TC_151_0.dT = TC_151_0.port_a.T - TC_151_0.port_b.T; TC_151_0.port_a.Q_flow = TC_151_0.Q_flow; TC_151_0.port_b.Q_flow = -TC_151_0.Q_flow; TC_152_0.Q_flow = TC_152_0.G * TC_152_0.dT; TC_152_0.dT = TC_152_0.port_a.T - TC_152_0.port_b.T; TC_152_0.port_a.Q_flow = TC_152_0.Q_flow; TC_152_0.port_b.Q_flow = -TC_152_0.Q_flow; TC_153_0.Q_flow = TC_153_0.G * TC_153_0.dT; TC_153_0.dT = TC_153_0.port_a.T - TC_153_0.port_b.T; TC_153_0.port_a.Q_flow = TC_153_0.Q_flow; TC_153_0.port_b.Q_flow = -TC_153_0.Q_flow; TC_154_0.Q_flow = TC_154_0.G * TC_154_0.dT; TC_154_0.dT = TC_154_0.port_a.T - TC_154_0.port_b.T; TC_154_0.port_a.Q_flow = TC_154_0.Q_flow; TC_154_0.port_b.Q_flow = -TC_154_0.Q_flow; TC_155_0.Q_flow = TC_155_0.G * TC_155_0.dT; TC_155_0.dT = TC_155_0.port_a.T - TC_155_0.port_b.T; TC_155_0.port_a.Q_flow = TC_155_0.Q_flow; TC_155_0.port_b.Q_flow = -TC_155_0.Q_flow; TC_156_0.Q_flow = TC_156_0.G * TC_156_0.dT; TC_156_0.dT = TC_156_0.port_a.T - TC_156_0.port_b.T; TC_156_0.port_a.Q_flow = TC_156_0.Q_flow; TC_156_0.port_b.Q_flow = -TC_156_0.Q_flow; TC_157_0.Q_flow = TC_157_0.G * TC_157_0.dT; TC_157_0.dT = TC_157_0.port_a.T - TC_157_0.port_b.T; TC_157_0.port_a.Q_flow = TC_157_0.Q_flow; TC_157_0.port_b.Q_flow = -TC_157_0.Q_flow; TC_158_0.Q_flow = TC_158_0.G * TC_158_0.dT; TC_158_0.dT = TC_158_0.port_a.T - TC_158_0.port_b.T; TC_158_0.port_a.Q_flow = TC_158_0.Q_flow; TC_158_0.port_b.Q_flow = -TC_158_0.Q_flow; TC_159_0.Q_flow = TC_159_0.G * TC_159_0.dT; TC_159_0.dT = TC_159_0.port_a.T - TC_159_0.port_b.T; TC_159_0.port_a.Q_flow = TC_159_0.Q_flow; TC_159_0.port_b.Q_flow = -TC_159_0.Q_flow; TC_160_0.Q_flow = TC_160_0.G * TC_160_0.dT; TC_160_0.dT = TC_160_0.port_a.T - TC_160_0.port_b.T; TC_160_0.port_a.Q_flow = TC_160_0.Q_flow; TC_160_0.port_b.Q_flow = -TC_160_0.Q_flow; TC_161_0.Q_flow = TC_161_0.G * TC_161_0.dT; TC_161_0.dT = TC_161_0.port_a.T - TC_161_0.port_b.T; TC_161_0.port_a.Q_flow = TC_161_0.Q_flow; TC_161_0.port_b.Q_flow = -TC_161_0.Q_flow; TC_162_0.Q_flow = TC_162_0.G * TC_162_0.dT; TC_162_0.dT = TC_162_0.port_a.T - TC_162_0.port_b.T; TC_162_0.port_a.Q_flow = TC_162_0.Q_flow; TC_162_0.port_b.Q_flow = -TC_162_0.Q_flow; TC_163_0.Q_flow = TC_163_0.G * TC_163_0.dT; TC_163_0.dT = TC_163_0.port_a.T - TC_163_0.port_b.T; TC_163_0.port_a.Q_flow = TC_163_0.Q_flow; TC_163_0.port_b.Q_flow = -TC_163_0.Q_flow; TC_164_0.Q_flow = TC_164_0.G * TC_164_0.dT; TC_164_0.dT = TC_164_0.port_a.T - TC_164_0.port_b.T; TC_164_0.port_a.Q_flow = TC_164_0.Q_flow; TC_164_0.port_b.Q_flow = -TC_164_0.Q_flow; TC_165_0.Q_flow = TC_165_0.G * TC_165_0.dT; TC_165_0.dT = TC_165_0.port_a.T - TC_165_0.port_b.T; TC_165_0.port_a.Q_flow = TC_165_0.Q_flow; TC_165_0.port_b.Q_flow = -TC_165_0.Q_flow; TC_166_0.Q_flow = TC_166_0.G * TC_166_0.dT; TC_166_0.dT = TC_166_0.port_a.T - TC_166_0.port_b.T; TC_166_0.port_a.Q_flow = TC_166_0.Q_flow; TC_166_0.port_b.Q_flow = -TC_166_0.Q_flow; TC_167_0.Q_flow = TC_167_0.G * TC_167_0.dT; TC_167_0.dT = TC_167_0.port_a.T - TC_167_0.port_b.T; TC_167_0.port_a.Q_flow = TC_167_0.Q_flow; TC_167_0.port_b.Q_flow = -TC_167_0.Q_flow; TC_168_0.Q_flow = TC_168_0.G * TC_168_0.dT; TC_168_0.dT = TC_168_0.port_a.T - TC_168_0.port_b.T; TC_168_0.port_a.Q_flow = TC_168_0.Q_flow; TC_168_0.port_b.Q_flow = -TC_168_0.Q_flow; TC_169_0.Q_flow = TC_169_0.G * TC_169_0.dT; TC_169_0.dT = TC_169_0.port_a.T - TC_169_0.port_b.T; TC_169_0.port_a.Q_flow = TC_169_0.Q_flow; TC_169_0.port_b.Q_flow = -TC_169_0.Q_flow; TC_170_0.Q_flow = TC_170_0.G * TC_170_0.dT; TC_170_0.dT = TC_170_0.port_a.T - TC_170_0.port_b.T; TC_170_0.port_a.Q_flow = TC_170_0.Q_flow; TC_170_0.port_b.Q_flow = -TC_170_0.Q_flow; TC_171_0.Q_flow = TC_171_0.G * TC_171_0.dT; TC_171_0.dT = TC_171_0.port_a.T - TC_171_0.port_b.T; TC_171_0.port_a.Q_flow = TC_171_0.Q_flow; TC_171_0.port_b.Q_flow = -TC_171_0.Q_flow; TC_172_0.Q_flow = TC_172_0.G * TC_172_0.dT; TC_172_0.dT = TC_172_0.port_a.T - TC_172_0.port_b.T; TC_172_0.port_a.Q_flow = TC_172_0.Q_flow; TC_172_0.port_b.Q_flow = -TC_172_0.Q_flow; TC_173_0.Q_flow = TC_173_0.G * TC_173_0.dT; TC_173_0.dT = TC_173_0.port_a.T - TC_173_0.port_b.T; TC_173_0.port_a.Q_flow = TC_173_0.Q_flow; TC_173_0.port_b.Q_flow = -TC_173_0.Q_flow; TC_174_0.Q_flow = TC_174_0.G * TC_174_0.dT; TC_174_0.dT = TC_174_0.port_a.T - TC_174_0.port_b.T; TC_174_0.port_a.Q_flow = TC_174_0.Q_flow; TC_174_0.port_b.Q_flow = -TC_174_0.Q_flow; TC_175_0.Q_flow = TC_175_0.G * TC_175_0.dT; TC_175_0.dT = TC_175_0.port_a.T - TC_175_0.port_b.T; TC_175_0.port_a.Q_flow = TC_175_0.Q_flow; TC_175_0.port_b.Q_flow = -TC_175_0.Q_flow; TC_176_0.Q_flow = TC_176_0.G * TC_176_0.dT; TC_176_0.dT = TC_176_0.port_a.T - TC_176_0.port_b.T; TC_176_0.port_a.Q_flow = TC_176_0.Q_flow; TC_176_0.port_b.Q_flow = -TC_176_0.Q_flow; TC_177_0.Q_flow = TC_177_0.G * TC_177_0.dT; TC_177_0.dT = TC_177_0.port_a.T - TC_177_0.port_b.T; TC_177_0.port_a.Q_flow = TC_177_0.Q_flow; TC_177_0.port_b.Q_flow = -TC_177_0.Q_flow; TC_178_0.Q_flow = TC_178_0.G * TC_178_0.dT; TC_178_0.dT = TC_178_0.port_a.T - TC_178_0.port_b.T; TC_178_0.port_a.Q_flow = TC_178_0.Q_flow; TC_178_0.port_b.Q_flow = -TC_178_0.Q_flow; TC_179_0.Q_flow = TC_179_0.G * TC_179_0.dT; TC_179_0.dT = TC_179_0.port_a.T - TC_179_0.port_b.T; TC_179_0.port_a.Q_flow = TC_179_0.Q_flow; TC_179_0.port_b.Q_flow = -TC_179_0.Q_flow; TC_180_0.Q_flow = TC_180_0.G * TC_180_0.dT; TC_180_0.dT = TC_180_0.port_a.T - TC_180_0.port_b.T; TC_180_0.port_a.Q_flow = TC_180_0.Q_flow; TC_180_0.port_b.Q_flow = -TC_180_0.Q_flow; TC_181_0.Q_flow = TC_181_0.G * TC_181_0.dT; TC_181_0.dT = TC_181_0.port_a.T - TC_181_0.port_b.T; TC_181_0.port_a.Q_flow = TC_181_0.Q_flow; TC_181_0.port_b.Q_flow = -TC_181_0.Q_flow; TC_182_0.Q_flow = TC_182_0.G * TC_182_0.dT; TC_182_0.dT = TC_182_0.port_a.T - TC_182_0.port_b.T; TC_182_0.port_a.Q_flow = TC_182_0.Q_flow; TC_182_0.port_b.Q_flow = -TC_182_0.Q_flow; TC_183_0.Q_flow = TC_183_0.G * TC_183_0.dT; TC_183_0.dT = TC_183_0.port_a.T - TC_183_0.port_b.T; TC_183_0.port_a.Q_flow = TC_183_0.Q_flow; TC_183_0.port_b.Q_flow = -TC_183_0.Q_flow; TC_184_0.Q_flow = TC_184_0.G * TC_184_0.dT; TC_184_0.dT = TC_184_0.port_a.T - TC_184_0.port_b.T; TC_184_0.port_a.Q_flow = TC_184_0.Q_flow; TC_184_0.port_b.Q_flow = -TC_184_0.Q_flow; TC_185_0.Q_flow = TC_185_0.G * TC_185_0.dT; TC_185_0.dT = TC_185_0.port_a.T - TC_185_0.port_b.T; TC_185_0.port_a.Q_flow = TC_185_0.Q_flow; TC_185_0.port_b.Q_flow = -TC_185_0.Q_flow; TC_186_0.Q_flow = TC_186_0.G * TC_186_0.dT; TC_186_0.dT = TC_186_0.port_a.T - TC_186_0.port_b.T; TC_186_0.port_a.Q_flow = TC_186_0.Q_flow; TC_186_0.port_b.Q_flow = -TC_186_0.Q_flow; TC_187_0.Q_flow = TC_187_0.G * TC_187_0.dT; TC_187_0.dT = TC_187_0.port_a.T - TC_187_0.port_b.T; TC_187_0.port_a.Q_flow = TC_187_0.Q_flow; TC_187_0.port_b.Q_flow = -TC_187_0.Q_flow; TC_188_0.Q_flow = TC_188_0.G * TC_188_0.dT; TC_188_0.dT = TC_188_0.port_a.T - TC_188_0.port_b.T; TC_188_0.port_a.Q_flow = TC_188_0.Q_flow; TC_188_0.port_b.Q_flow = -TC_188_0.Q_flow; TC_189_0.Q_flow = TC_189_0.G * TC_189_0.dT; TC_189_0.dT = TC_189_0.port_a.T - TC_189_0.port_b.T; TC_189_0.port_a.Q_flow = TC_189_0.Q_flow; TC_189_0.port_b.Q_flow = -TC_189_0.Q_flow; TC_190_0.Q_flow = TC_190_0.G * TC_190_0.dT; TC_190_0.dT = TC_190_0.port_a.T - TC_190_0.port_b.T; TC_190_0.port_a.Q_flow = TC_190_0.Q_flow; TC_190_0.port_b.Q_flow = -TC_190_0.Q_flow; TC_191_0.Q_flow = TC_191_0.G * TC_191_0.dT; TC_191_0.dT = TC_191_0.port_a.T - TC_191_0.port_b.T; TC_191_0.port_a.Q_flow = TC_191_0.Q_flow; TC_191_0.port_b.Q_flow = -TC_191_0.Q_flow; TC_192_0.Q_flow = TC_192_0.G * TC_192_0.dT; TC_192_0.dT = TC_192_0.port_a.T - TC_192_0.port_b.T; TC_192_0.port_a.Q_flow = TC_192_0.Q_flow; TC_192_0.port_b.Q_flow = -TC_192_0.Q_flow; TC_193_0.Q_flow = TC_193_0.G * TC_193_0.dT; TC_193_0.dT = TC_193_0.port_a.T - TC_193_0.port_b.T; TC_193_0.port_a.Q_flow = TC_193_0.Q_flow; TC_193_0.port_b.Q_flow = -TC_193_0.Q_flow; TC_194_0.Q_flow = TC_194_0.G * TC_194_0.dT; TC_194_0.dT = TC_194_0.port_a.T - TC_194_0.port_b.T; TC_194_0.port_a.Q_flow = TC_194_0.Q_flow; TC_194_0.port_b.Q_flow = -TC_194_0.Q_flow; TC_195_0.Q_flow = TC_195_0.G * TC_195_0.dT; TC_195_0.dT = TC_195_0.port_a.T - TC_195_0.port_b.T; TC_195_0.port_a.Q_flow = TC_195_0.Q_flow; TC_195_0.port_b.Q_flow = -TC_195_0.Q_flow; TC_196_0.Q_flow = TC_196_0.G * TC_196_0.dT; TC_196_0.dT = TC_196_0.port_a.T - TC_196_0.port_b.T; TC_196_0.port_a.Q_flow = TC_196_0.Q_flow; TC_196_0.port_b.Q_flow = -TC_196_0.Q_flow; TC_197_0.Q_flow = TC_197_0.G * TC_197_0.dT; TC_197_0.dT = TC_197_0.port_a.T - TC_197_0.port_b.T; TC_197_0.port_a.Q_flow = TC_197_0.Q_flow; TC_197_0.port_b.Q_flow = -TC_197_0.Q_flow; TC_198_0.Q_flow = TC_198_0.G * TC_198_0.dT; TC_198_0.dT = TC_198_0.port_a.T - TC_198_0.port_b.T; TC_198_0.port_a.Q_flow = TC_198_0.Q_flow; TC_198_0.port_b.Q_flow = -TC_198_0.Q_flow; TC_199_0.Q_flow = TC_199_0.G * TC_199_0.dT; TC_199_0.dT = TC_199_0.port_a.T - TC_199_0.port_b.T; TC_199_0.port_a.Q_flow = TC_199_0.Q_flow; TC_199_0.port_b.Q_flow = -TC_199_0.Q_flow; TC_200_0.Q_flow = TC_200_0.G * TC_200_0.dT; TC_200_0.dT = TC_200_0.port_a.T - TC_200_0.port_b.T; TC_200_0.port_a.Q_flow = TC_200_0.Q_flow; TC_200_0.port_b.Q_flow = -TC_200_0.Q_flow; TC_201_0.Q_flow = TC_201_0.G * TC_201_0.dT; TC_201_0.dT = TC_201_0.port_a.T - TC_201_0.port_b.T; TC_201_0.port_a.Q_flow = TC_201_0.Q_flow; TC_201_0.port_b.Q_flow = -TC_201_0.Q_flow; TC_202_0.Q_flow = TC_202_0.G * TC_202_0.dT; TC_202_0.dT = TC_202_0.port_a.T - TC_202_0.port_b.T; TC_202_0.port_a.Q_flow = TC_202_0.Q_flow; TC_202_0.port_b.Q_flow = -TC_202_0.Q_flow; TC_203_0.Q_flow = TC_203_0.G * TC_203_0.dT; TC_203_0.dT = TC_203_0.port_a.T - TC_203_0.port_b.T; TC_203_0.port_a.Q_flow = TC_203_0.Q_flow; TC_203_0.port_b.Q_flow = -TC_203_0.Q_flow; TC_204_0.Q_flow = TC_204_0.G * TC_204_0.dT; TC_204_0.dT = TC_204_0.port_a.T - TC_204_0.port_b.T; TC_204_0.port_a.Q_flow = TC_204_0.Q_flow; TC_204_0.port_b.Q_flow = -TC_204_0.Q_flow; TC_205_0.Q_flow = TC_205_0.G * TC_205_0.dT; TC_205_0.dT = TC_205_0.port_a.T - TC_205_0.port_b.T; TC_205_0.port_a.Q_flow = TC_205_0.Q_flow; TC_205_0.port_b.Q_flow = -TC_205_0.Q_flow; TC_206_0.Q_flow = TC_206_0.G * TC_206_0.dT; TC_206_0.dT = TC_206_0.port_a.T - TC_206_0.port_b.T; TC_206_0.port_a.Q_flow = TC_206_0.Q_flow; TC_206_0.port_b.Q_flow = -TC_206_0.Q_flow; TC_207_0.Q_flow = TC_207_0.G * TC_207_0.dT; TC_207_0.dT = TC_207_0.port_a.T - TC_207_0.port_b.T; TC_207_0.port_a.Q_flow = TC_207_0.Q_flow; TC_207_0.port_b.Q_flow = -TC_207_0.Q_flow; TC_208_0.Q_flow = TC_208_0.G * TC_208_0.dT; TC_208_0.dT = TC_208_0.port_a.T - TC_208_0.port_b.T; TC_208_0.port_a.Q_flow = TC_208_0.Q_flow; TC_208_0.port_b.Q_flow = -TC_208_0.Q_flow; TC_209_0.Q_flow = TC_209_0.G * TC_209_0.dT; TC_209_0.dT = TC_209_0.port_a.T - TC_209_0.port_b.T; TC_209_0.port_a.Q_flow = TC_209_0.Q_flow; TC_209_0.port_b.Q_flow = -TC_209_0.Q_flow; TC_210_0.Q_flow = TC_210_0.G * TC_210_0.dT; TC_210_0.dT = TC_210_0.port_a.T - TC_210_0.port_b.T; TC_210_0.port_a.Q_flow = TC_210_0.Q_flow; TC_210_0.port_b.Q_flow = -TC_210_0.Q_flow; TC_211_0.Q_flow = TC_211_0.G * TC_211_0.dT; TC_211_0.dT = TC_211_0.port_a.T - TC_211_0.port_b.T; TC_211_0.port_a.Q_flow = TC_211_0.Q_flow; TC_211_0.port_b.Q_flow = -TC_211_0.Q_flow; TC_212_0.Q_flow = TC_212_0.G * TC_212_0.dT; TC_212_0.dT = TC_212_0.port_a.T - TC_212_0.port_b.T; TC_212_0.port_a.Q_flow = TC_212_0.Q_flow; TC_212_0.port_b.Q_flow = -TC_212_0.Q_flow; TC_213_0.Q_flow = TC_213_0.G * TC_213_0.dT; TC_213_0.dT = TC_213_0.port_a.T - TC_213_0.port_b.T; TC_213_0.port_a.Q_flow = TC_213_0.Q_flow; TC_213_0.port_b.Q_flow = -TC_213_0.Q_flow; TC_214_0.Q_flow = TC_214_0.G * TC_214_0.dT; TC_214_0.dT = TC_214_0.port_a.T - TC_214_0.port_b.T; TC_214_0.port_a.Q_flow = TC_214_0.Q_flow; TC_214_0.port_b.Q_flow = -TC_214_0.Q_flow; TC_215_0.Q_flow = TC_215_0.G * TC_215_0.dT; TC_215_0.dT = TC_215_0.port_a.T - TC_215_0.port_b.T; TC_215_0.port_a.Q_flow = TC_215_0.Q_flow; TC_215_0.port_b.Q_flow = -TC_215_0.Q_flow; TC_216_0.Q_flow = TC_216_0.G * TC_216_0.dT; TC_216_0.dT = TC_216_0.port_a.T - TC_216_0.port_b.T; TC_216_0.port_a.Q_flow = TC_216_0.Q_flow; TC_216_0.port_b.Q_flow = -TC_216_0.Q_flow; TC_217_0.Q_flow = TC_217_0.G * TC_217_0.dT; TC_217_0.dT = TC_217_0.port_a.T - TC_217_0.port_b.T; TC_217_0.port_a.Q_flow = TC_217_0.Q_flow; TC_217_0.port_b.Q_flow = -TC_217_0.Q_flow; TC_218_0.Q_flow = TC_218_0.G * TC_218_0.dT; TC_218_0.dT = TC_218_0.port_a.T - TC_218_0.port_b.T; TC_218_0.port_a.Q_flow = TC_218_0.Q_flow; TC_218_0.port_b.Q_flow = -TC_218_0.Q_flow; TC_219_0.Q_flow = TC_219_0.G * TC_219_0.dT; TC_219_0.dT = TC_219_0.port_a.T - TC_219_0.port_b.T; TC_219_0.port_a.Q_flow = TC_219_0.Q_flow; TC_219_0.port_b.Q_flow = -TC_219_0.Q_flow; TC_220_0.Q_flow = TC_220_0.G * TC_220_0.dT; TC_220_0.dT = TC_220_0.port_a.T - TC_220_0.port_b.T; TC_220_0.port_a.Q_flow = TC_220_0.Q_flow; TC_220_0.port_b.Q_flow = -TC_220_0.Q_flow; TC_221_0.Q_flow = TC_221_0.G * TC_221_0.dT; TC_221_0.dT = TC_221_0.port_a.T - TC_221_0.port_b.T; TC_221_0.port_a.Q_flow = TC_221_0.Q_flow; TC_221_0.port_b.Q_flow = -TC_221_0.Q_flow; TC_222_0.Q_flow = TC_222_0.G * TC_222_0.dT; TC_222_0.dT = TC_222_0.port_a.T - TC_222_0.port_b.T; TC_222_0.port_a.Q_flow = TC_222_0.Q_flow; TC_222_0.port_b.Q_flow = -TC_222_0.Q_flow; TC_223_0.Q_flow = TC_223_0.G * TC_223_0.dT; TC_223_0.dT = TC_223_0.port_a.T - TC_223_0.port_b.T; TC_223_0.port_a.Q_flow = TC_223_0.Q_flow; TC_223_0.port_b.Q_flow = -TC_223_0.Q_flow; TC_224_0.Q_flow = TC_224_0.G * TC_224_0.dT; TC_224_0.dT = TC_224_0.port_a.T - TC_224_0.port_b.T; TC_224_0.port_a.Q_flow = TC_224_0.Q_flow; TC_224_0.port_b.Q_flow = -TC_224_0.Q_flow; TC_225_0.Q_flow = TC_225_0.G * TC_225_0.dT; TC_225_0.dT = TC_225_0.port_a.T - TC_225_0.port_b.T; TC_225_0.port_a.Q_flow = TC_225_0.Q_flow; TC_225_0.port_b.Q_flow = -TC_225_0.Q_flow; TC_226_0.Q_flow = TC_226_0.G * TC_226_0.dT; TC_226_0.dT = TC_226_0.port_a.T - TC_226_0.port_b.T; TC_226_0.port_a.Q_flow = TC_226_0.Q_flow; TC_226_0.port_b.Q_flow = -TC_226_0.Q_flow; TC_227_0.Q_flow = TC_227_0.G * TC_227_0.dT; TC_227_0.dT = TC_227_0.port_a.T - TC_227_0.port_b.T; TC_227_0.port_a.Q_flow = TC_227_0.Q_flow; TC_227_0.port_b.Q_flow = -TC_227_0.Q_flow; TC_228_0.Q_flow = TC_228_0.G * TC_228_0.dT; TC_228_0.dT = TC_228_0.port_a.T - TC_228_0.port_b.T; TC_228_0.port_a.Q_flow = TC_228_0.Q_flow; TC_228_0.port_b.Q_flow = -TC_228_0.Q_flow; TC_229_0.Q_flow = TC_229_0.G * TC_229_0.dT; TC_229_0.dT = TC_229_0.port_a.T - TC_229_0.port_b.T; TC_229_0.port_a.Q_flow = TC_229_0.Q_flow; TC_229_0.port_b.Q_flow = -TC_229_0.Q_flow; TC_230_0.Q_flow = TC_230_0.G * TC_230_0.dT; TC_230_0.dT = TC_230_0.port_a.T - TC_230_0.port_b.T; TC_230_0.port_a.Q_flow = TC_230_0.Q_flow; TC_230_0.port_b.Q_flow = -TC_230_0.Q_flow; TC_231_0.Q_flow = TC_231_0.G * TC_231_0.dT; TC_231_0.dT = TC_231_0.port_a.T - TC_231_0.port_b.T; TC_231_0.port_a.Q_flow = TC_231_0.Q_flow; TC_231_0.port_b.Q_flow = -TC_231_0.Q_flow; TC_232_0.Q_flow = TC_232_0.G * TC_232_0.dT; TC_232_0.dT = TC_232_0.port_a.T - TC_232_0.port_b.T; TC_232_0.port_a.Q_flow = TC_232_0.Q_flow; TC_232_0.port_b.Q_flow = -TC_232_0.Q_flow; TC_233_0.Q_flow = TC_233_0.G * TC_233_0.dT; TC_233_0.dT = TC_233_0.port_a.T - TC_233_0.port_b.T; TC_233_0.port_a.Q_flow = TC_233_0.Q_flow; TC_233_0.port_b.Q_flow = -TC_233_0.Q_flow; TC_234_0.Q_flow = TC_234_0.G * TC_234_0.dT; TC_234_0.dT = TC_234_0.port_a.T - TC_234_0.port_b.T; TC_234_0.port_a.Q_flow = TC_234_0.Q_flow; TC_234_0.port_b.Q_flow = -TC_234_0.Q_flow; TC_235_0.Q_flow = TC_235_0.G * TC_235_0.dT; TC_235_0.dT = TC_235_0.port_a.T - TC_235_0.port_b.T; TC_235_0.port_a.Q_flow = TC_235_0.Q_flow; TC_235_0.port_b.Q_flow = -TC_235_0.Q_flow; TC_236_0.Q_flow = TC_236_0.G * TC_236_0.dT; TC_236_0.dT = TC_236_0.port_a.T - TC_236_0.port_b.T; TC_236_0.port_a.Q_flow = TC_236_0.Q_flow; TC_236_0.port_b.Q_flow = -TC_236_0.Q_flow; TC_237_0.Q_flow = TC_237_0.G * TC_237_0.dT; TC_237_0.dT = TC_237_0.port_a.T - TC_237_0.port_b.T; TC_237_0.port_a.Q_flow = TC_237_0.Q_flow; TC_237_0.port_b.Q_flow = -TC_237_0.Q_flow; TC_238_0.Q_flow = TC_238_0.G * TC_238_0.dT; TC_238_0.dT = TC_238_0.port_a.T - TC_238_0.port_b.T; TC_238_0.port_a.Q_flow = TC_238_0.Q_flow; TC_238_0.port_b.Q_flow = -TC_238_0.Q_flow; TC_239_0.Q_flow = TC_239_0.G * TC_239_0.dT; TC_239_0.dT = TC_239_0.port_a.T - TC_239_0.port_b.T; TC_239_0.port_a.Q_flow = TC_239_0.Q_flow; TC_239_0.port_b.Q_flow = -TC_239_0.Q_flow; TC_240_0.Q_flow = TC_240_0.G * TC_240_0.dT; TC_240_0.dT = TC_240_0.port_a.T - TC_240_0.port_b.T; TC_240_0.port_a.Q_flow = TC_240_0.Q_flow; TC_240_0.port_b.Q_flow = -TC_240_0.Q_flow; TC_241_0.Q_flow = TC_241_0.G * TC_241_0.dT; TC_241_0.dT = TC_241_0.port_a.T - TC_241_0.port_b.T; TC_241_0.port_a.Q_flow = TC_241_0.Q_flow; TC_241_0.port_b.Q_flow = -TC_241_0.Q_flow; TC_242_0.Q_flow = TC_242_0.G * TC_242_0.dT; TC_242_0.dT = TC_242_0.port_a.T - TC_242_0.port_b.T; TC_242_0.port_a.Q_flow = TC_242_0.Q_flow; TC_242_0.port_b.Q_flow = -TC_242_0.Q_flow; TC_243_0.Q_flow = TC_243_0.G * TC_243_0.dT; TC_243_0.dT = TC_243_0.port_a.T - TC_243_0.port_b.T; TC_243_0.port_a.Q_flow = TC_243_0.Q_flow; TC_243_0.port_b.Q_flow = -TC_243_0.Q_flow; TC_244_0.Q_flow = TC_244_0.G * TC_244_0.dT; TC_244_0.dT = TC_244_0.port_a.T - TC_244_0.port_b.T; TC_244_0.port_a.Q_flow = TC_244_0.Q_flow; TC_244_0.port_b.Q_flow = -TC_244_0.Q_flow; TC_245_0.Q_flow = TC_245_0.G * TC_245_0.dT; TC_245_0.dT = TC_245_0.port_a.T - TC_245_0.port_b.T; TC_245_0.port_a.Q_flow = TC_245_0.Q_flow; TC_245_0.port_b.Q_flow = -TC_245_0.Q_flow; TC_246_0.Q_flow = TC_246_0.G * TC_246_0.dT; TC_246_0.dT = TC_246_0.port_a.T - TC_246_0.port_b.T; TC_246_0.port_a.Q_flow = TC_246_0.Q_flow; TC_246_0.port_b.Q_flow = -TC_246_0.Q_flow; TC_247_0.Q_flow = TC_247_0.G * TC_247_0.dT; TC_247_0.dT = TC_247_0.port_a.T - TC_247_0.port_b.T; TC_247_0.port_a.Q_flow = TC_247_0.Q_flow; TC_247_0.port_b.Q_flow = -TC_247_0.Q_flow; TC_248_0.Q_flow = TC_248_0.G * TC_248_0.dT; TC_248_0.dT = TC_248_0.port_a.T - TC_248_0.port_b.T; TC_248_0.port_a.Q_flow = TC_248_0.Q_flow; TC_248_0.port_b.Q_flow = -TC_248_0.Q_flow; TC_249_0.Q_flow = TC_249_0.G * TC_249_0.dT; TC_249_0.dT = TC_249_0.port_a.T - TC_249_0.port_b.T; TC_249_0.port_a.Q_flow = TC_249_0.Q_flow; TC_249_0.port_b.Q_flow = -TC_249_0.Q_flow; TC_250_0.Q_flow = TC_250_0.G * TC_250_0.dT; TC_250_0.dT = TC_250_0.port_a.T - TC_250_0.port_b.T; TC_250_0.port_a.Q_flow = TC_250_0.Q_flow; TC_250_0.port_b.Q_flow = -TC_250_0.Q_flow; TC_251_0.Q_flow = TC_251_0.G * TC_251_0.dT; TC_251_0.dT = TC_251_0.port_a.T - TC_251_0.port_b.T; TC_251_0.port_a.Q_flow = TC_251_0.Q_flow; TC_251_0.port_b.Q_flow = -TC_251_0.Q_flow; TC_252_0.Q_flow = TC_252_0.G * TC_252_0.dT; TC_252_0.dT = TC_252_0.port_a.T - TC_252_0.port_b.T; TC_252_0.port_a.Q_flow = TC_252_0.Q_flow; TC_252_0.port_b.Q_flow = -TC_252_0.Q_flow; TC_253_0.Q_flow = TC_253_0.G * TC_253_0.dT; TC_253_0.dT = TC_253_0.port_a.T - TC_253_0.port_b.T; TC_253_0.port_a.Q_flow = TC_253_0.Q_flow; TC_253_0.port_b.Q_flow = -TC_253_0.Q_flow; TC_254_0.Q_flow = TC_254_0.G * TC_254_0.dT; TC_254_0.dT = TC_254_0.port_a.T - TC_254_0.port_b.T; TC_254_0.port_a.Q_flow = TC_254_0.Q_flow; TC_254_0.port_b.Q_flow = -TC_254_0.Q_flow; TC_255_0.Q_flow = TC_255_0.G * TC_255_0.dT; TC_255_0.dT = TC_255_0.port_a.T - TC_255_0.port_b.T; TC_255_0.port_a.Q_flow = TC_255_0.Q_flow; TC_255_0.port_b.Q_flow = -TC_255_0.Q_flow; TC_256_0.Q_flow = TC_256_0.G * TC_256_0.dT; TC_256_0.dT = TC_256_0.port_a.T - TC_256_0.port_b.T; TC_256_0.port_a.Q_flow = TC_256_0.Q_flow; TC_256_0.port_b.Q_flow = -TC_256_0.Q_flow; TC_257_0.Q_flow = TC_257_0.G * TC_257_0.dT; TC_257_0.dT = TC_257_0.port_a.T - TC_257_0.port_b.T; TC_257_0.port_a.Q_flow = TC_257_0.Q_flow; TC_257_0.port_b.Q_flow = -TC_257_0.Q_flow; TC_258_0.Q_flow = TC_258_0.G * TC_258_0.dT; TC_258_0.dT = TC_258_0.port_a.T - TC_258_0.port_b.T; TC_258_0.port_a.Q_flow = TC_258_0.Q_flow; TC_258_0.port_b.Q_flow = -TC_258_0.Q_flow; TC_259_0.Q_flow = TC_259_0.G * TC_259_0.dT; TC_259_0.dT = TC_259_0.port_a.T - TC_259_0.port_b.T; TC_259_0.port_a.Q_flow = TC_259_0.Q_flow; TC_259_0.port_b.Q_flow = -TC_259_0.Q_flow; TC_260_0.Q_flow = TC_260_0.G * TC_260_0.dT; TC_260_0.dT = TC_260_0.port_a.T - TC_260_0.port_b.T; TC_260_0.port_a.Q_flow = TC_260_0.Q_flow; TC_260_0.port_b.Q_flow = -TC_260_0.Q_flow; TC_261_0.Q_flow = TC_261_0.G * TC_261_0.dT; TC_261_0.dT = TC_261_0.port_a.T - TC_261_0.port_b.T; TC_261_0.port_a.Q_flow = TC_261_0.Q_flow; TC_261_0.port_b.Q_flow = -TC_261_0.Q_flow; TC_262_0.Q_flow = TC_262_0.G * TC_262_0.dT; TC_262_0.dT = TC_262_0.port_a.T - TC_262_0.port_b.T; TC_262_0.port_a.Q_flow = TC_262_0.Q_flow; TC_262_0.port_b.Q_flow = -TC_262_0.Q_flow; TC_263_0.Q_flow = TC_263_0.G * TC_263_0.dT; TC_263_0.dT = TC_263_0.port_a.T - TC_263_0.port_b.T; TC_263_0.port_a.Q_flow = TC_263_0.Q_flow; TC_263_0.port_b.Q_flow = -TC_263_0.Q_flow; TC_264_0.Q_flow = TC_264_0.G * TC_264_0.dT; TC_264_0.dT = TC_264_0.port_a.T - TC_264_0.port_b.T; TC_264_0.port_a.Q_flow = TC_264_0.Q_flow; TC_264_0.port_b.Q_flow = -TC_264_0.Q_flow; TC_265_0.Q_flow = TC_265_0.G * TC_265_0.dT; TC_265_0.dT = TC_265_0.port_a.T - TC_265_0.port_b.T; TC_265_0.port_a.Q_flow = TC_265_0.Q_flow; TC_265_0.port_b.Q_flow = -TC_265_0.Q_flow; TC_266_0.Q_flow = TC_266_0.G * TC_266_0.dT; TC_266_0.dT = TC_266_0.port_a.T - TC_266_0.port_b.T; TC_266_0.port_a.Q_flow = TC_266_0.Q_flow; TC_266_0.port_b.Q_flow = -TC_266_0.Q_flow; TC_267_0.Q_flow = TC_267_0.G * TC_267_0.dT; TC_267_0.dT = TC_267_0.port_a.T - TC_267_0.port_b.T; TC_267_0.port_a.Q_flow = TC_267_0.Q_flow; TC_267_0.port_b.Q_flow = -TC_267_0.Q_flow; TC_268_0.Q_flow = TC_268_0.G * TC_268_0.dT; TC_268_0.dT = TC_268_0.port_a.T - TC_268_0.port_b.T; TC_268_0.port_a.Q_flow = TC_268_0.Q_flow; TC_268_0.port_b.Q_flow = -TC_268_0.Q_flow; TC_269_0.Q_flow = TC_269_0.G * TC_269_0.dT; TC_269_0.dT = TC_269_0.port_a.T - TC_269_0.port_b.T; TC_269_0.port_a.Q_flow = TC_269_0.Q_flow; TC_269_0.port_b.Q_flow = -TC_269_0.Q_flow; TC_270_0.Q_flow = TC_270_0.G * TC_270_0.dT; TC_270_0.dT = TC_270_0.port_a.T - TC_270_0.port_b.T; TC_270_0.port_a.Q_flow = TC_270_0.Q_flow; TC_270_0.port_b.Q_flow = -TC_270_0.Q_flow; TC_271_0.Q_flow = TC_271_0.G * TC_271_0.dT; TC_271_0.dT = TC_271_0.port_a.T - TC_271_0.port_b.T; TC_271_0.port_a.Q_flow = TC_271_0.Q_flow; TC_271_0.port_b.Q_flow = -TC_271_0.Q_flow; TC_272_0.Q_flow = TC_272_0.G * TC_272_0.dT; TC_272_0.dT = TC_272_0.port_a.T - TC_272_0.port_b.T; TC_272_0.port_a.Q_flow = TC_272_0.Q_flow; TC_272_0.port_b.Q_flow = -TC_272_0.Q_flow; TC_273_0.Q_flow = TC_273_0.G * TC_273_0.dT; TC_273_0.dT = TC_273_0.port_a.T - TC_273_0.port_b.T; TC_273_0.port_a.Q_flow = TC_273_0.Q_flow; TC_273_0.port_b.Q_flow = -TC_273_0.Q_flow; TC_274_0.Q_flow = TC_274_0.G * TC_274_0.dT; TC_274_0.dT = TC_274_0.port_a.T - TC_274_0.port_b.T; TC_274_0.port_a.Q_flow = TC_274_0.Q_flow; TC_274_0.port_b.Q_flow = -TC_274_0.Q_flow; TC_275_0.Q_flow = TC_275_0.G * TC_275_0.dT; TC_275_0.dT = TC_275_0.port_a.T - TC_275_0.port_b.T; TC_275_0.port_a.Q_flow = TC_275_0.Q_flow; TC_275_0.port_b.Q_flow = -TC_275_0.Q_flow; TC_276_0.Q_flow = TC_276_0.G * TC_276_0.dT; TC_276_0.dT = TC_276_0.port_a.T - TC_276_0.port_b.T; TC_276_0.port_a.Q_flow = TC_276_0.Q_flow; TC_276_0.port_b.Q_flow = -TC_276_0.Q_flow; TC_277_0.Q_flow = TC_277_0.G * TC_277_0.dT; TC_277_0.dT = TC_277_0.port_a.T - TC_277_0.port_b.T; TC_277_0.port_a.Q_flow = TC_277_0.Q_flow; TC_277_0.port_b.Q_flow = -TC_277_0.Q_flow; TC_278_0.Q_flow = TC_278_0.G * TC_278_0.dT; TC_278_0.dT = TC_278_0.port_a.T - TC_278_0.port_b.T; TC_278_0.port_a.Q_flow = TC_278_0.Q_flow; TC_278_0.port_b.Q_flow = -TC_278_0.Q_flow; TC_279_0.Q_flow = TC_279_0.G * TC_279_0.dT; TC_279_0.dT = TC_279_0.port_a.T - TC_279_0.port_b.T; TC_279_0.port_a.Q_flow = TC_279_0.Q_flow; TC_279_0.port_b.Q_flow = -TC_279_0.Q_flow; TC_280_0.Q_flow = TC_280_0.G * TC_280_0.dT; TC_280_0.dT = TC_280_0.port_a.T - TC_280_0.port_b.T; TC_280_0.port_a.Q_flow = TC_280_0.Q_flow; TC_280_0.port_b.Q_flow = -TC_280_0.Q_flow; TC_281_0.Q_flow = TC_281_0.G * TC_281_0.dT; TC_281_0.dT = TC_281_0.port_a.T - TC_281_0.port_b.T; TC_281_0.port_a.Q_flow = TC_281_0.Q_flow; TC_281_0.port_b.Q_flow = -TC_281_0.Q_flow; TC_282_0.Q_flow = TC_282_0.G * TC_282_0.dT; TC_282_0.dT = TC_282_0.port_a.T - TC_282_0.port_b.T; TC_282_0.port_a.Q_flow = TC_282_0.Q_flow; TC_282_0.port_b.Q_flow = -TC_282_0.Q_flow; TC_283_0.Q_flow = TC_283_0.G * TC_283_0.dT; TC_283_0.dT = TC_283_0.port_a.T - TC_283_0.port_b.T; TC_283_0.port_a.Q_flow = TC_283_0.Q_flow; TC_283_0.port_b.Q_flow = -TC_283_0.Q_flow; TC_284_0.Q_flow = TC_284_0.G * TC_284_0.dT; TC_284_0.dT = TC_284_0.port_a.T - TC_284_0.port_b.T; TC_284_0.port_a.Q_flow = TC_284_0.Q_flow; TC_284_0.port_b.Q_flow = -TC_284_0.Q_flow; TC_285_0.Q_flow = TC_285_0.G * TC_285_0.dT; TC_285_0.dT = TC_285_0.port_a.T - TC_285_0.port_b.T; TC_285_0.port_a.Q_flow = TC_285_0.Q_flow; TC_285_0.port_b.Q_flow = -TC_285_0.Q_flow; TC_286_0.Q_flow = TC_286_0.G * TC_286_0.dT; TC_286_0.dT = TC_286_0.port_a.T - TC_286_0.port_b.T; TC_286_0.port_a.Q_flow = TC_286_0.Q_flow; TC_286_0.port_b.Q_flow = -TC_286_0.Q_flow; TC_287_0.Q_flow = TC_287_0.G * TC_287_0.dT; TC_287_0.dT = TC_287_0.port_a.T - TC_287_0.port_b.T; TC_287_0.port_a.Q_flow = TC_287_0.Q_flow; TC_287_0.port_b.Q_flow = -TC_287_0.Q_flow; TC_288_0.Q_flow = TC_288_0.G * TC_288_0.dT; TC_288_0.dT = TC_288_0.port_a.T - TC_288_0.port_b.T; TC_288_0.port_a.Q_flow = TC_288_0.Q_flow; TC_288_0.port_b.Q_flow = -TC_288_0.Q_flow; TC_289_0.Q_flow = TC_289_0.G * TC_289_0.dT; TC_289_0.dT = TC_289_0.port_a.T - TC_289_0.port_b.T; TC_289_0.port_a.Q_flow = TC_289_0.Q_flow; TC_289_0.port_b.Q_flow = -TC_289_0.Q_flow; TC_290_0.Q_flow = TC_290_0.G * TC_290_0.dT; TC_290_0.dT = TC_290_0.port_a.T - TC_290_0.port_b.T; TC_290_0.port_a.Q_flow = TC_290_0.Q_flow; TC_290_0.port_b.Q_flow = -TC_290_0.Q_flow; TC_291_0.Q_flow = TC_291_0.G * TC_291_0.dT; TC_291_0.dT = TC_291_0.port_a.T - TC_291_0.port_b.T; TC_291_0.port_a.Q_flow = TC_291_0.Q_flow; TC_291_0.port_b.Q_flow = -TC_291_0.Q_flow; TC_292_0.Q_flow = TC_292_0.G * TC_292_0.dT; TC_292_0.dT = TC_292_0.port_a.T - TC_292_0.port_b.T; TC_292_0.port_a.Q_flow = TC_292_0.Q_flow; TC_292_0.port_b.Q_flow = -TC_292_0.Q_flow; TC_293_0.Q_flow = TC_293_0.G * TC_293_0.dT; TC_293_0.dT = TC_293_0.port_a.T - TC_293_0.port_b.T; TC_293_0.port_a.Q_flow = TC_293_0.Q_flow; TC_293_0.port_b.Q_flow = -TC_293_0.Q_flow; TC_294_0.Q_flow = TC_294_0.G * TC_294_0.dT; TC_294_0.dT = TC_294_0.port_a.T - TC_294_0.port_b.T; TC_294_0.port_a.Q_flow = TC_294_0.Q_flow; TC_294_0.port_b.Q_flow = -TC_294_0.Q_flow; TC_295_0.Q_flow = TC_295_0.G * TC_295_0.dT; TC_295_0.dT = TC_295_0.port_a.T - TC_295_0.port_b.T; TC_295_0.port_a.Q_flow = TC_295_0.Q_flow; TC_295_0.port_b.Q_flow = -TC_295_0.Q_flow; TC_296_0.Q_flow = TC_296_0.G * TC_296_0.dT; TC_296_0.dT = TC_296_0.port_a.T - TC_296_0.port_b.T; TC_296_0.port_a.Q_flow = TC_296_0.Q_flow; TC_296_0.port_b.Q_flow = -TC_296_0.Q_flow; TC_297_0.Q_flow = TC_297_0.G * TC_297_0.dT; TC_297_0.dT = TC_297_0.port_a.T - TC_297_0.port_b.T; TC_297_0.port_a.Q_flow = TC_297_0.Q_flow; TC_297_0.port_b.Q_flow = -TC_297_0.Q_flow; TC_298_0.Q_flow = TC_298_0.G * TC_298_0.dT; TC_298_0.dT = TC_298_0.port_a.T - TC_298_0.port_b.T; TC_298_0.port_a.Q_flow = TC_298_0.Q_flow; TC_298_0.port_b.Q_flow = -TC_298_0.Q_flow; TC_299_0.Q_flow = TC_299_0.G * TC_299_0.dT; TC_299_0.dT = TC_299_0.port_a.T - TC_299_0.port_b.T; TC_299_0.port_a.Q_flow = TC_299_0.Q_flow; TC_299_0.port_b.Q_flow = -TC_299_0.Q_flow; TC_300_0.Q_flow = TC_300_0.G * TC_300_0.dT; TC_300_0.dT = TC_300_0.port_a.T - TC_300_0.port_b.T; TC_300_0.port_a.Q_flow = TC_300_0.Q_flow; TC_300_0.port_b.Q_flow = -TC_300_0.Q_flow; TC_301_0.Q_flow = TC_301_0.G * TC_301_0.dT; TC_301_0.dT = TC_301_0.port_a.T - TC_301_0.port_b.T; TC_301_0.port_a.Q_flow = TC_301_0.Q_flow; TC_301_0.port_b.Q_flow = -TC_301_0.Q_flow; TC_302_0.Q_flow = TC_302_0.G * TC_302_0.dT; TC_302_0.dT = TC_302_0.port_a.T - TC_302_0.port_b.T; TC_302_0.port_a.Q_flow = TC_302_0.Q_flow; TC_302_0.port_b.Q_flow = -TC_302_0.Q_flow; TC_303_0.Q_flow = TC_303_0.G * TC_303_0.dT; TC_303_0.dT = TC_303_0.port_a.T - TC_303_0.port_b.T; TC_303_0.port_a.Q_flow = TC_303_0.Q_flow; TC_303_0.port_b.Q_flow = -TC_303_0.Q_flow; TC_304_0.Q_flow = TC_304_0.G * TC_304_0.dT; TC_304_0.dT = TC_304_0.port_a.T - TC_304_0.port_b.T; TC_304_0.port_a.Q_flow = TC_304_0.Q_flow; TC_304_0.port_b.Q_flow = -TC_304_0.Q_flow; TC_305_0.Q_flow = TC_305_0.G * TC_305_0.dT; TC_305_0.dT = TC_305_0.port_a.T - TC_305_0.port_b.T; TC_305_0.port_a.Q_flow = TC_305_0.Q_flow; TC_305_0.port_b.Q_flow = -TC_305_0.Q_flow; TC_306_0.Q_flow = TC_306_0.G * TC_306_0.dT; TC_306_0.dT = TC_306_0.port_a.T - TC_306_0.port_b.T; TC_306_0.port_a.Q_flow = TC_306_0.Q_flow; TC_306_0.port_b.Q_flow = -TC_306_0.Q_flow; TC_307_0.Q_flow = TC_307_0.G * TC_307_0.dT; TC_307_0.dT = TC_307_0.port_a.T - TC_307_0.port_b.T; TC_307_0.port_a.Q_flow = TC_307_0.Q_flow; TC_307_0.port_b.Q_flow = -TC_307_0.Q_flow; TC_308_0.Q_flow = TC_308_0.G * TC_308_0.dT; TC_308_0.dT = TC_308_0.port_a.T - TC_308_0.port_b.T; TC_308_0.port_a.Q_flow = TC_308_0.Q_flow; TC_308_0.port_b.Q_flow = -TC_308_0.Q_flow; TC_309_0.Q_flow = TC_309_0.G * TC_309_0.dT; TC_309_0.dT = TC_309_0.port_a.T - TC_309_0.port_b.T; TC_309_0.port_a.Q_flow = TC_309_0.Q_flow; TC_309_0.port_b.Q_flow = -TC_309_0.Q_flow; TC_310_0.Q_flow = TC_310_0.G * TC_310_0.dT; TC_310_0.dT = TC_310_0.port_a.T - TC_310_0.port_b.T; TC_310_0.port_a.Q_flow = TC_310_0.Q_flow; TC_310_0.port_b.Q_flow = -TC_310_0.Q_flow; TC_311_0.Q_flow = TC_311_0.G * TC_311_0.dT; TC_311_0.dT = TC_311_0.port_a.T - TC_311_0.port_b.T; TC_311_0.port_a.Q_flow = TC_311_0.Q_flow; TC_311_0.port_b.Q_flow = -TC_311_0.Q_flow; TC_312_0.Q_flow = TC_312_0.G * TC_312_0.dT; TC_312_0.dT = TC_312_0.port_a.T - TC_312_0.port_b.T; TC_312_0.port_a.Q_flow = TC_312_0.Q_flow; TC_312_0.port_b.Q_flow = -TC_312_0.Q_flow; TC_313_0.Q_flow = TC_313_0.G * TC_313_0.dT; TC_313_0.dT = TC_313_0.port_a.T - TC_313_0.port_b.T; TC_313_0.port_a.Q_flow = TC_313_0.Q_flow; TC_313_0.port_b.Q_flow = -TC_313_0.Q_flow; TC_314_0.Q_flow = TC_314_0.G * TC_314_0.dT; TC_314_0.dT = TC_314_0.port_a.T - TC_314_0.port_b.T; TC_314_0.port_a.Q_flow = TC_314_0.Q_flow; TC_314_0.port_b.Q_flow = -TC_314_0.Q_flow; TC_315_0.Q_flow = TC_315_0.G * TC_315_0.dT; TC_315_0.dT = TC_315_0.port_a.T - TC_315_0.port_b.T; TC_315_0.port_a.Q_flow = TC_315_0.Q_flow; TC_315_0.port_b.Q_flow = -TC_315_0.Q_flow; TC_316_0.Q_flow = TC_316_0.G * TC_316_0.dT; TC_316_0.dT = TC_316_0.port_a.T - TC_316_0.port_b.T; TC_316_0.port_a.Q_flow = TC_316_0.Q_flow; TC_316_0.port_b.Q_flow = -TC_316_0.Q_flow; TC_317_0.Q_flow = TC_317_0.G * TC_317_0.dT; TC_317_0.dT = TC_317_0.port_a.T - TC_317_0.port_b.T; TC_317_0.port_a.Q_flow = TC_317_0.Q_flow; TC_317_0.port_b.Q_flow = -TC_317_0.Q_flow; TC_318_0.Q_flow = TC_318_0.G * TC_318_0.dT; TC_318_0.dT = TC_318_0.port_a.T - TC_318_0.port_b.T; TC_318_0.port_a.Q_flow = TC_318_0.Q_flow; TC_318_0.port_b.Q_flow = -TC_318_0.Q_flow; TC_319_0.Q_flow = TC_319_0.G * TC_319_0.dT; TC_319_0.dT = TC_319_0.port_a.T - TC_319_0.port_b.T; TC_319_0.port_a.Q_flow = TC_319_0.Q_flow; TC_319_0.port_b.Q_flow = -TC_319_0.Q_flow; TC_320_0.Q_flow = TC_320_0.G * TC_320_0.dT; TC_320_0.dT = TC_320_0.port_a.T - TC_320_0.port_b.T; TC_320_0.port_a.Q_flow = TC_320_0.Q_flow; TC_320_0.port_b.Q_flow = -TC_320_0.Q_flow; TC_321_0.Q_flow = TC_321_0.G * TC_321_0.dT; TC_321_0.dT = TC_321_0.port_a.T - TC_321_0.port_b.T; TC_321_0.port_a.Q_flow = TC_321_0.Q_flow; TC_321_0.port_b.Q_flow = -TC_321_0.Q_flow; TC_322_0.Q_flow = TC_322_0.G * TC_322_0.dT; TC_322_0.dT = TC_322_0.port_a.T - TC_322_0.port_b.T; TC_322_0.port_a.Q_flow = TC_322_0.Q_flow; TC_322_0.port_b.Q_flow = -TC_322_0.Q_flow; TC_323_0.Q_flow = TC_323_0.G * TC_323_0.dT; TC_323_0.dT = TC_323_0.port_a.T - TC_323_0.port_b.T; TC_323_0.port_a.Q_flow = TC_323_0.Q_flow; TC_323_0.port_b.Q_flow = -TC_323_0.Q_flow; TC_324_0.Q_flow = TC_324_0.G * TC_324_0.dT; TC_324_0.dT = TC_324_0.port_a.T - TC_324_0.port_b.T; TC_324_0.port_a.Q_flow = TC_324_0.Q_flow; TC_324_0.port_b.Q_flow = -TC_324_0.Q_flow; TC_325_0.Q_flow = TC_325_0.G * TC_325_0.dT; TC_325_0.dT = TC_325_0.port_a.T - TC_325_0.port_b.T; TC_325_0.port_a.Q_flow = TC_325_0.Q_flow; TC_325_0.port_b.Q_flow = -TC_325_0.Q_flow; TC_326_0.Q_flow = TC_326_0.G * TC_326_0.dT; TC_326_0.dT = TC_326_0.port_a.T - TC_326_0.port_b.T; TC_326_0.port_a.Q_flow = TC_326_0.Q_flow; TC_326_0.port_b.Q_flow = -TC_326_0.Q_flow; TC_327_0.Q_flow = TC_327_0.G * TC_327_0.dT; TC_327_0.dT = TC_327_0.port_a.T - TC_327_0.port_b.T; TC_327_0.port_a.Q_flow = TC_327_0.Q_flow; TC_327_0.port_b.Q_flow = -TC_327_0.Q_flow; TC_328_0.Q_flow = TC_328_0.G * TC_328_0.dT; TC_328_0.dT = TC_328_0.port_a.T - TC_328_0.port_b.T; TC_328_0.port_a.Q_flow = TC_328_0.Q_flow; TC_328_0.port_b.Q_flow = -TC_328_0.Q_flow; TC_329_0.Q_flow = TC_329_0.G * TC_329_0.dT; TC_329_0.dT = TC_329_0.port_a.T - TC_329_0.port_b.T; TC_329_0.port_a.Q_flow = TC_329_0.Q_flow; TC_329_0.port_b.Q_flow = -TC_329_0.Q_flow; TC_330_0.Q_flow = TC_330_0.G * TC_330_0.dT; TC_330_0.dT = TC_330_0.port_a.T - TC_330_0.port_b.T; TC_330_0.port_a.Q_flow = TC_330_0.Q_flow; TC_330_0.port_b.Q_flow = -TC_330_0.Q_flow; TC_331_0.Q_flow = TC_331_0.G * TC_331_0.dT; TC_331_0.dT = TC_331_0.port_a.T - TC_331_0.port_b.T; TC_331_0.port_a.Q_flow = TC_331_0.Q_flow; TC_331_0.port_b.Q_flow = -TC_331_0.Q_flow; TC_332_0.Q_flow = TC_332_0.G * TC_332_0.dT; TC_332_0.dT = TC_332_0.port_a.T - TC_332_0.port_b.T; TC_332_0.port_a.Q_flow = TC_332_0.Q_flow; TC_332_0.port_b.Q_flow = -TC_332_0.Q_flow; TC_333_0.Q_flow = TC_333_0.G * TC_333_0.dT; TC_333_0.dT = TC_333_0.port_a.T - TC_333_0.port_b.T; TC_333_0.port_a.Q_flow = TC_333_0.Q_flow; TC_333_0.port_b.Q_flow = -TC_333_0.Q_flow; TC_334_0.Q_flow = TC_334_0.G * TC_334_0.dT; TC_334_0.dT = TC_334_0.port_a.T - TC_334_0.port_b.T; TC_334_0.port_a.Q_flow = TC_334_0.Q_flow; TC_334_0.port_b.Q_flow = -TC_334_0.Q_flow; TC_335_0.Q_flow = TC_335_0.G * TC_335_0.dT; TC_335_0.dT = TC_335_0.port_a.T - TC_335_0.port_b.T; TC_335_0.port_a.Q_flow = TC_335_0.Q_flow; TC_335_0.port_b.Q_flow = -TC_335_0.Q_flow; TC_336_0.Q_flow = TC_336_0.G * TC_336_0.dT; TC_336_0.dT = TC_336_0.port_a.T - TC_336_0.port_b.T; TC_336_0.port_a.Q_flow = TC_336_0.Q_flow; TC_336_0.port_b.Q_flow = -TC_336_0.Q_flow; TC_337_0.Q_flow = TC_337_0.G * TC_337_0.dT; TC_337_0.dT = TC_337_0.port_a.T - TC_337_0.port_b.T; TC_337_0.port_a.Q_flow = TC_337_0.Q_flow; TC_337_0.port_b.Q_flow = -TC_337_0.Q_flow; TC_338_0.Q_flow = TC_338_0.G * TC_338_0.dT; TC_338_0.dT = TC_338_0.port_a.T - TC_338_0.port_b.T; TC_338_0.port_a.Q_flow = TC_338_0.Q_flow; TC_338_0.port_b.Q_flow = -TC_338_0.Q_flow; TC_339_0.Q_flow = TC_339_0.G * TC_339_0.dT; TC_339_0.dT = TC_339_0.port_a.T - TC_339_0.port_b.T; TC_339_0.port_a.Q_flow = TC_339_0.Q_flow; TC_339_0.port_b.Q_flow = -TC_339_0.Q_flow; TC_340_0.Q_flow = TC_340_0.G * TC_340_0.dT; TC_340_0.dT = TC_340_0.port_a.T - TC_340_0.port_b.T; TC_340_0.port_a.Q_flow = TC_340_0.Q_flow; TC_340_0.port_b.Q_flow = -TC_340_0.Q_flow; TC_341_0.Q_flow = TC_341_0.G * TC_341_0.dT; TC_341_0.dT = TC_341_0.port_a.T - TC_341_0.port_b.T; TC_341_0.port_a.Q_flow = TC_341_0.Q_flow; TC_341_0.port_b.Q_flow = -TC_341_0.Q_flow; TC_342_0.Q_flow = TC_342_0.G * TC_342_0.dT; TC_342_0.dT = TC_342_0.port_a.T - TC_342_0.port_b.T; TC_342_0.port_a.Q_flow = TC_342_0.Q_flow; TC_342_0.port_b.Q_flow = -TC_342_0.Q_flow; TC_343_0.Q_flow = TC_343_0.G * TC_343_0.dT; TC_343_0.dT = TC_343_0.port_a.T - TC_343_0.port_b.T; TC_343_0.port_a.Q_flow = TC_343_0.Q_flow; TC_343_0.port_b.Q_flow = -TC_343_0.Q_flow; TC_344_0.Q_flow = TC_344_0.G * TC_344_0.dT; TC_344_0.dT = TC_344_0.port_a.T - TC_344_0.port_b.T; TC_344_0.port_a.Q_flow = TC_344_0.Q_flow; TC_344_0.port_b.Q_flow = -TC_344_0.Q_flow; TC_345_0.Q_flow = TC_345_0.G * TC_345_0.dT; TC_345_0.dT = TC_345_0.port_a.T - TC_345_0.port_b.T; TC_345_0.port_a.Q_flow = TC_345_0.Q_flow; TC_345_0.port_b.Q_flow = -TC_345_0.Q_flow; TC_346_0.Q_flow = TC_346_0.G * TC_346_0.dT; TC_346_0.dT = TC_346_0.port_a.T - TC_346_0.port_b.T; TC_346_0.port_a.Q_flow = TC_346_0.Q_flow; TC_346_0.port_b.Q_flow = -TC_346_0.Q_flow; TC_347_0.Q_flow = TC_347_0.G * TC_347_0.dT; TC_347_0.dT = TC_347_0.port_a.T - TC_347_0.port_b.T; TC_347_0.port_a.Q_flow = TC_347_0.Q_flow; TC_347_0.port_b.Q_flow = -TC_347_0.Q_flow; TC_348_0.Q_flow = TC_348_0.G * TC_348_0.dT; TC_348_0.dT = TC_348_0.port_a.T - TC_348_0.port_b.T; TC_348_0.port_a.Q_flow = TC_348_0.Q_flow; TC_348_0.port_b.Q_flow = -TC_348_0.Q_flow; TC_349_0.Q_flow = TC_349_0.G * TC_349_0.dT; TC_349_0.dT = TC_349_0.port_a.T - TC_349_0.port_b.T; TC_349_0.port_a.Q_flow = TC_349_0.Q_flow; TC_349_0.port_b.Q_flow = -TC_349_0.Q_flow; TC_350_0.Q_flow = TC_350_0.G * TC_350_0.dT; TC_350_0.dT = TC_350_0.port_a.T - TC_350_0.port_b.T; TC_350_0.port_a.Q_flow = TC_350_0.Q_flow; TC_350_0.port_b.Q_flow = -TC_350_0.Q_flow; TC_351_0.Q_flow = TC_351_0.G * TC_351_0.dT; TC_351_0.dT = TC_351_0.port_a.T - TC_351_0.port_b.T; TC_351_0.port_a.Q_flow = TC_351_0.Q_flow; TC_351_0.port_b.Q_flow = -TC_351_0.Q_flow; TC_352_0.Q_flow = TC_352_0.G * TC_352_0.dT; TC_352_0.dT = TC_352_0.port_a.T - TC_352_0.port_b.T; TC_352_0.port_a.Q_flow = TC_352_0.Q_flow; TC_352_0.port_b.Q_flow = -TC_352_0.Q_flow; TC_353_0.Q_flow = TC_353_0.G * TC_353_0.dT; TC_353_0.dT = TC_353_0.port_a.T - TC_353_0.port_b.T; TC_353_0.port_a.Q_flow = TC_353_0.Q_flow; TC_353_0.port_b.Q_flow = -TC_353_0.Q_flow; TC_354_0.Q_flow = TC_354_0.G * TC_354_0.dT; TC_354_0.dT = TC_354_0.port_a.T - TC_354_0.port_b.T; TC_354_0.port_a.Q_flow = TC_354_0.Q_flow; TC_354_0.port_b.Q_flow = -TC_354_0.Q_flow; TC_355_0.Q_flow = TC_355_0.G * TC_355_0.dT; TC_355_0.dT = TC_355_0.port_a.T - TC_355_0.port_b.T; TC_355_0.port_a.Q_flow = TC_355_0.Q_flow; TC_355_0.port_b.Q_flow = -TC_355_0.Q_flow; TC_356_0.Q_flow = TC_356_0.G * TC_356_0.dT; TC_356_0.dT = TC_356_0.port_a.T - TC_356_0.port_b.T; TC_356_0.port_a.Q_flow = TC_356_0.Q_flow; TC_356_0.port_b.Q_flow = -TC_356_0.Q_flow; TC_357_0.Q_flow = TC_357_0.G * TC_357_0.dT; TC_357_0.dT = TC_357_0.port_a.T - TC_357_0.port_b.T; TC_357_0.port_a.Q_flow = TC_357_0.Q_flow; TC_357_0.port_b.Q_flow = -TC_357_0.Q_flow; TC_358_0.Q_flow = TC_358_0.G * TC_358_0.dT; TC_358_0.dT = TC_358_0.port_a.T - TC_358_0.port_b.T; TC_358_0.port_a.Q_flow = TC_358_0.Q_flow; TC_358_0.port_b.Q_flow = -TC_358_0.Q_flow; TC_359_0.Q_flow = TC_359_0.G * TC_359_0.dT; TC_359_0.dT = TC_359_0.port_a.T - TC_359_0.port_b.T; TC_359_0.port_a.Q_flow = TC_359_0.Q_flow; TC_359_0.port_b.Q_flow = -TC_359_0.Q_flow; TC_360_0.Q_flow = TC_360_0.G * TC_360_0.dT; TC_360_0.dT = TC_360_0.port_a.T - TC_360_0.port_b.T; TC_360_0.port_a.Q_flow = TC_360_0.Q_flow; TC_360_0.port_b.Q_flow = -TC_360_0.Q_flow; TC_361_0.Q_flow = TC_361_0.G * TC_361_0.dT; TC_361_0.dT = TC_361_0.port_a.T - TC_361_0.port_b.T; TC_361_0.port_a.Q_flow = TC_361_0.Q_flow; TC_361_0.port_b.Q_flow = -TC_361_0.Q_flow; TC_362_0.Q_flow = TC_362_0.G * TC_362_0.dT; TC_362_0.dT = TC_362_0.port_a.T - TC_362_0.port_b.T; TC_362_0.port_a.Q_flow = TC_362_0.Q_flow; TC_362_0.port_b.Q_flow = -TC_362_0.Q_flow; TC_363_0.Q_flow = TC_363_0.G * TC_363_0.dT; TC_363_0.dT = TC_363_0.port_a.T - TC_363_0.port_b.T; TC_363_0.port_a.Q_flow = TC_363_0.Q_flow; TC_363_0.port_b.Q_flow = -TC_363_0.Q_flow; TC_364_0.Q_flow = TC_364_0.G * TC_364_0.dT; TC_364_0.dT = TC_364_0.port_a.T - TC_364_0.port_b.T; TC_364_0.port_a.Q_flow = TC_364_0.Q_flow; TC_364_0.port_b.Q_flow = -TC_364_0.Q_flow; TC_365_0.Q_flow = TC_365_0.G * TC_365_0.dT; TC_365_0.dT = TC_365_0.port_a.T - TC_365_0.port_b.T; TC_365_0.port_a.Q_flow = TC_365_0.Q_flow; TC_365_0.port_b.Q_flow = -TC_365_0.Q_flow; TC_366_0.Q_flow = TC_366_0.G * TC_366_0.dT; TC_366_0.dT = TC_366_0.port_a.T - TC_366_0.port_b.T; TC_366_0.port_a.Q_flow = TC_366_0.Q_flow; TC_366_0.port_b.Q_flow = -TC_366_0.Q_flow; TC_367_0.Q_flow = TC_367_0.G * TC_367_0.dT; TC_367_0.dT = TC_367_0.port_a.T - TC_367_0.port_b.T; TC_367_0.port_a.Q_flow = TC_367_0.Q_flow; TC_367_0.port_b.Q_flow = -TC_367_0.Q_flow; TC_368_0.Q_flow = TC_368_0.G * TC_368_0.dT; TC_368_0.dT = TC_368_0.port_a.T - TC_368_0.port_b.T; TC_368_0.port_a.Q_flow = TC_368_0.Q_flow; TC_368_0.port_b.Q_flow = -TC_368_0.Q_flow; TC_369_0.Q_flow = TC_369_0.G * TC_369_0.dT; TC_369_0.dT = TC_369_0.port_a.T - TC_369_0.port_b.T; TC_369_0.port_a.Q_flow = TC_369_0.Q_flow; TC_369_0.port_b.Q_flow = -TC_369_0.Q_flow; TC_370_0.Q_flow = TC_370_0.G * TC_370_0.dT; TC_370_0.dT = TC_370_0.port_a.T - TC_370_0.port_b.T; TC_370_0.port_a.Q_flow = TC_370_0.Q_flow; TC_370_0.port_b.Q_flow = -TC_370_0.Q_flow; TC_371_0.Q_flow = TC_371_0.G * TC_371_0.dT; TC_371_0.dT = TC_371_0.port_a.T - TC_371_0.port_b.T; TC_371_0.port_a.Q_flow = TC_371_0.Q_flow; TC_371_0.port_b.Q_flow = -TC_371_0.Q_flow; TC_372_0.Q_flow = TC_372_0.G * TC_372_0.dT; TC_372_0.dT = TC_372_0.port_a.T - TC_372_0.port_b.T; TC_372_0.port_a.Q_flow = TC_372_0.Q_flow; TC_372_0.port_b.Q_flow = -TC_372_0.Q_flow; TC_373_0.Q_flow = TC_373_0.G * TC_373_0.dT; TC_373_0.dT = TC_373_0.port_a.T - TC_373_0.port_b.T; TC_373_0.port_a.Q_flow = TC_373_0.Q_flow; TC_373_0.port_b.Q_flow = -TC_373_0.Q_flow; TC_374_0.Q_flow = TC_374_0.G * TC_374_0.dT; TC_374_0.dT = TC_374_0.port_a.T - TC_374_0.port_b.T; TC_374_0.port_a.Q_flow = TC_374_0.Q_flow; TC_374_0.port_b.Q_flow = -TC_374_0.Q_flow; TC_375_0.Q_flow = TC_375_0.G * TC_375_0.dT; TC_375_0.dT = TC_375_0.port_a.T - TC_375_0.port_b.T; TC_375_0.port_a.Q_flow = TC_375_0.Q_flow; TC_375_0.port_b.Q_flow = -TC_375_0.Q_flow; TC_376_0.Q_flow = TC_376_0.G * TC_376_0.dT; TC_376_0.dT = TC_376_0.port_a.T - TC_376_0.port_b.T; TC_376_0.port_a.Q_flow = TC_376_0.Q_flow; TC_376_0.port_b.Q_flow = -TC_376_0.Q_flow; TC_377_0.Q_flow = TC_377_0.G * TC_377_0.dT; TC_377_0.dT = TC_377_0.port_a.T - TC_377_0.port_b.T; TC_377_0.port_a.Q_flow = TC_377_0.Q_flow; TC_377_0.port_b.Q_flow = -TC_377_0.Q_flow; TC_378_0.Q_flow = TC_378_0.G * TC_378_0.dT; TC_378_0.dT = TC_378_0.port_a.T - TC_378_0.port_b.T; TC_378_0.port_a.Q_flow = TC_378_0.Q_flow; TC_378_0.port_b.Q_flow = -TC_378_0.Q_flow; TC_379_0.Q_flow = TC_379_0.G * TC_379_0.dT; TC_379_0.dT = TC_379_0.port_a.T - TC_379_0.port_b.T; TC_379_0.port_a.Q_flow = TC_379_0.Q_flow; TC_379_0.port_b.Q_flow = -TC_379_0.Q_flow; TC_380_0.Q_flow = TC_380_0.G * TC_380_0.dT; TC_380_0.dT = TC_380_0.port_a.T - TC_380_0.port_b.T; TC_380_0.port_a.Q_flow = TC_380_0.Q_flow; TC_380_0.port_b.Q_flow = -TC_380_0.Q_flow; TC_381_0.Q_flow = TC_381_0.G * TC_381_0.dT; TC_381_0.dT = TC_381_0.port_a.T - TC_381_0.port_b.T; TC_381_0.port_a.Q_flow = TC_381_0.Q_flow; TC_381_0.port_b.Q_flow = -TC_381_0.Q_flow; TC_382_0.Q_flow = TC_382_0.G * TC_382_0.dT; TC_382_0.dT = TC_382_0.port_a.T - TC_382_0.port_b.T; TC_382_0.port_a.Q_flow = TC_382_0.Q_flow; TC_382_0.port_b.Q_flow = -TC_382_0.Q_flow; TC_383_0.Q_flow = TC_383_0.G * TC_383_0.dT; TC_383_0.dT = TC_383_0.port_a.T - TC_383_0.port_b.T; TC_383_0.port_a.Q_flow = TC_383_0.Q_flow; TC_383_0.port_b.Q_flow = -TC_383_0.Q_flow; TC_384_0.Q_flow = TC_384_0.G * TC_384_0.dT; TC_384_0.dT = TC_384_0.port_a.T - TC_384_0.port_b.T; TC_384_0.port_a.Q_flow = TC_384_0.Q_flow; TC_384_0.port_b.Q_flow = -TC_384_0.Q_flow; TC_385_0.Q_flow = TC_385_0.G * TC_385_0.dT; TC_385_0.dT = TC_385_0.port_a.T - TC_385_0.port_b.T; TC_385_0.port_a.Q_flow = TC_385_0.Q_flow; TC_385_0.port_b.Q_flow = -TC_385_0.Q_flow; TC_386_0.Q_flow = TC_386_0.G * TC_386_0.dT; TC_386_0.dT = TC_386_0.port_a.T - TC_386_0.port_b.T; TC_386_0.port_a.Q_flow = TC_386_0.Q_flow; TC_386_0.port_b.Q_flow = -TC_386_0.Q_flow; TC_387_0.Q_flow = TC_387_0.G * TC_387_0.dT; TC_387_0.dT = TC_387_0.port_a.T - TC_387_0.port_b.T; TC_387_0.port_a.Q_flow = TC_387_0.Q_flow; TC_387_0.port_b.Q_flow = -TC_387_0.Q_flow; TC_388_0.Q_flow = TC_388_0.G * TC_388_0.dT; TC_388_0.dT = TC_388_0.port_a.T - TC_388_0.port_b.T; TC_388_0.port_a.Q_flow = TC_388_0.Q_flow; TC_388_0.port_b.Q_flow = -TC_388_0.Q_flow; TC_389_0.Q_flow = TC_389_0.G * TC_389_0.dT; TC_389_0.dT = TC_389_0.port_a.T - TC_389_0.port_b.T; TC_389_0.port_a.Q_flow = TC_389_0.Q_flow; TC_389_0.port_b.Q_flow = -TC_389_0.Q_flow; TC_390_0.Q_flow = TC_390_0.G * TC_390_0.dT; TC_390_0.dT = TC_390_0.port_a.T - TC_390_0.port_b.T; TC_390_0.port_a.Q_flow = TC_390_0.Q_flow; TC_390_0.port_b.Q_flow = -TC_390_0.Q_flow; TC_391_0.Q_flow = TC_391_0.G * TC_391_0.dT; TC_391_0.dT = TC_391_0.port_a.T - TC_391_0.port_b.T; TC_391_0.port_a.Q_flow = TC_391_0.Q_flow; TC_391_0.port_b.Q_flow = -TC_391_0.Q_flow; TC_392_0.Q_flow = TC_392_0.G * TC_392_0.dT; TC_392_0.dT = TC_392_0.port_a.T - TC_392_0.port_b.T; TC_392_0.port_a.Q_flow = TC_392_0.Q_flow; TC_392_0.port_b.Q_flow = -TC_392_0.Q_flow; TC_393_0.Q_flow = TC_393_0.G * TC_393_0.dT; TC_393_0.dT = TC_393_0.port_a.T - TC_393_0.port_b.T; TC_393_0.port_a.Q_flow = TC_393_0.Q_flow; TC_393_0.port_b.Q_flow = -TC_393_0.Q_flow; TC_394_0.Q_flow = TC_394_0.G * TC_394_0.dT; TC_394_0.dT = TC_394_0.port_a.T - TC_394_0.port_b.T; TC_394_0.port_a.Q_flow = TC_394_0.Q_flow; TC_394_0.port_b.Q_flow = -TC_394_0.Q_flow; TC_395_0.Q_flow = TC_395_0.G * TC_395_0.dT; TC_395_0.dT = TC_395_0.port_a.T - TC_395_0.port_b.T; TC_395_0.port_a.Q_flow = TC_395_0.Q_flow; TC_395_0.port_b.Q_flow = -TC_395_0.Q_flow; TC_396_0.Q_flow = TC_396_0.G * TC_396_0.dT; TC_396_0.dT = TC_396_0.port_a.T - TC_396_0.port_b.T; TC_396_0.port_a.Q_flow = TC_396_0.Q_flow; TC_396_0.port_b.Q_flow = -TC_396_0.Q_flow; TC_397_0.Q_flow = TC_397_0.G * TC_397_0.dT; TC_397_0.dT = TC_397_0.port_a.T - TC_397_0.port_b.T; TC_397_0.port_a.Q_flow = TC_397_0.Q_flow; TC_397_0.port_b.Q_flow = -TC_397_0.Q_flow; TC_398_0.Q_flow = TC_398_0.G * TC_398_0.dT; TC_398_0.dT = TC_398_0.port_a.T - TC_398_0.port_b.T; TC_398_0.port_a.Q_flow = TC_398_0.Q_flow; TC_398_0.port_b.Q_flow = -TC_398_0.Q_flow; TC_399_0.Q_flow = TC_399_0.G * TC_399_0.dT; TC_399_0.dT = TC_399_0.port_a.T - TC_399_0.port_b.T; TC_399_0.port_a.Q_flow = TC_399_0.Q_flow; TC_399_0.port_b.Q_flow = -TC_399_0.Q_flow; TC_400_0.Q_flow = TC_400_0.G * TC_400_0.dT; TC_400_0.dT = TC_400_0.port_a.T - TC_400_0.port_b.T; TC_400_0.port_a.Q_flow = TC_400_0.Q_flow; TC_400_0.port_b.Q_flow = -TC_400_0.Q_flow; TC_401_0.Q_flow = TC_401_0.G * TC_401_0.dT; TC_401_0.dT = TC_401_0.port_a.T - TC_401_0.port_b.T; TC_401_0.port_a.Q_flow = TC_401_0.Q_flow; TC_401_0.port_b.Q_flow = -TC_401_0.Q_flow; TC_402_0.Q_flow = TC_402_0.G * TC_402_0.dT; TC_402_0.dT = TC_402_0.port_a.T - TC_402_0.port_b.T; TC_402_0.port_a.Q_flow = TC_402_0.Q_flow; TC_402_0.port_b.Q_flow = -TC_402_0.Q_flow; TC_403_0.Q_flow = TC_403_0.G * TC_403_0.dT; TC_403_0.dT = TC_403_0.port_a.T - TC_403_0.port_b.T; TC_403_0.port_a.Q_flow = TC_403_0.Q_flow; TC_403_0.port_b.Q_flow = -TC_403_0.Q_flow; TC_404_0.Q_flow = TC_404_0.G * TC_404_0.dT; TC_404_0.dT = TC_404_0.port_a.T - TC_404_0.port_b.T; TC_404_0.port_a.Q_flow = TC_404_0.Q_flow; TC_404_0.port_b.Q_flow = -TC_404_0.Q_flow; TC_405_0.Q_flow = TC_405_0.G * TC_405_0.dT; TC_405_0.dT = TC_405_0.port_a.T - TC_405_0.port_b.T; TC_405_0.port_a.Q_flow = TC_405_0.Q_flow; TC_405_0.port_b.Q_flow = -TC_405_0.Q_flow; TC_406_0.Q_flow = TC_406_0.G * TC_406_0.dT; TC_406_0.dT = TC_406_0.port_a.T - TC_406_0.port_b.T; TC_406_0.port_a.Q_flow = TC_406_0.Q_flow; TC_406_0.port_b.Q_flow = -TC_406_0.Q_flow; TC_407_0.Q_flow = TC_407_0.G * TC_407_0.dT; TC_407_0.dT = TC_407_0.port_a.T - TC_407_0.port_b.T; TC_407_0.port_a.Q_flow = TC_407_0.Q_flow; TC_407_0.port_b.Q_flow = -TC_407_0.Q_flow; TC_408_0.Q_flow = TC_408_0.G * TC_408_0.dT; TC_408_0.dT = TC_408_0.port_a.T - TC_408_0.port_b.T; TC_408_0.port_a.Q_flow = TC_408_0.Q_flow; TC_408_0.port_b.Q_flow = -TC_408_0.Q_flow; TC_409_0.Q_flow = TC_409_0.G * TC_409_0.dT; TC_409_0.dT = TC_409_0.port_a.T - TC_409_0.port_b.T; TC_409_0.port_a.Q_flow = TC_409_0.Q_flow; TC_409_0.port_b.Q_flow = -TC_409_0.Q_flow; TC_410_0.Q_flow = TC_410_0.G * TC_410_0.dT; TC_410_0.dT = TC_410_0.port_a.T - TC_410_0.port_b.T; TC_410_0.port_a.Q_flow = TC_410_0.Q_flow; TC_410_0.port_b.Q_flow = -TC_410_0.Q_flow; TC_411_0.Q_flow = TC_411_0.G * TC_411_0.dT; TC_411_0.dT = TC_411_0.port_a.T - TC_411_0.port_b.T; TC_411_0.port_a.Q_flow = TC_411_0.Q_flow; TC_411_0.port_b.Q_flow = -TC_411_0.Q_flow; TC_412_0.Q_flow = TC_412_0.G * TC_412_0.dT; TC_412_0.dT = TC_412_0.port_a.T - TC_412_0.port_b.T; TC_412_0.port_a.Q_flow = TC_412_0.Q_flow; TC_412_0.port_b.Q_flow = -TC_412_0.Q_flow; TC_413_0.Q_flow = TC_413_0.G * TC_413_0.dT; TC_413_0.dT = TC_413_0.port_a.T - TC_413_0.port_b.T; TC_413_0.port_a.Q_flow = TC_413_0.Q_flow; TC_413_0.port_b.Q_flow = -TC_413_0.Q_flow; TC_414_0.Q_flow = TC_414_0.G * TC_414_0.dT; TC_414_0.dT = TC_414_0.port_a.T - TC_414_0.port_b.T; TC_414_0.port_a.Q_flow = TC_414_0.Q_flow; TC_414_0.port_b.Q_flow = -TC_414_0.Q_flow; TC_415_0.Q_flow = TC_415_0.G * TC_415_0.dT; TC_415_0.dT = TC_415_0.port_a.T - TC_415_0.port_b.T; TC_415_0.port_a.Q_flow = TC_415_0.Q_flow; TC_415_0.port_b.Q_flow = -TC_415_0.Q_flow; TC_416_0.Q_flow = TC_416_0.G * TC_416_0.dT; TC_416_0.dT = TC_416_0.port_a.T - TC_416_0.port_b.T; TC_416_0.port_a.Q_flow = TC_416_0.Q_flow; TC_416_0.port_b.Q_flow = -TC_416_0.Q_flow; TC_417_0.Q_flow = TC_417_0.G * TC_417_0.dT; TC_417_0.dT = TC_417_0.port_a.T - TC_417_0.port_b.T; TC_417_0.port_a.Q_flow = TC_417_0.Q_flow; TC_417_0.port_b.Q_flow = -TC_417_0.Q_flow; TC_418_0.Q_flow = TC_418_0.G * TC_418_0.dT; TC_418_0.dT = TC_418_0.port_a.T - TC_418_0.port_b.T; TC_418_0.port_a.Q_flow = TC_418_0.Q_flow; TC_418_0.port_b.Q_flow = -TC_418_0.Q_flow; TC_419_0.Q_flow = TC_419_0.G * TC_419_0.dT; TC_419_0.dT = TC_419_0.port_a.T - TC_419_0.port_b.T; TC_419_0.port_a.Q_flow = TC_419_0.Q_flow; TC_419_0.port_b.Q_flow = -TC_419_0.Q_flow; TC_420_0.Q_flow = TC_420_0.G * TC_420_0.dT; TC_420_0.dT = TC_420_0.port_a.T - TC_420_0.port_b.T; TC_420_0.port_a.Q_flow = TC_420_0.Q_flow; TC_420_0.port_b.Q_flow = -TC_420_0.Q_flow; TC_421_0.Q_flow = TC_421_0.G * TC_421_0.dT; TC_421_0.dT = TC_421_0.port_a.T - TC_421_0.port_b.T; TC_421_0.port_a.Q_flow = TC_421_0.Q_flow; TC_421_0.port_b.Q_flow = -TC_421_0.Q_flow; TC_422_0.Q_flow = TC_422_0.G * TC_422_0.dT; TC_422_0.dT = TC_422_0.port_a.T - TC_422_0.port_b.T; TC_422_0.port_a.Q_flow = TC_422_0.Q_flow; TC_422_0.port_b.Q_flow = -TC_422_0.Q_flow; TC_423_0.Q_flow = TC_423_0.G * TC_423_0.dT; TC_423_0.dT = TC_423_0.port_a.T - TC_423_0.port_b.T; TC_423_0.port_a.Q_flow = TC_423_0.Q_flow; TC_423_0.port_b.Q_flow = -TC_423_0.Q_flow; TC_424_0.Q_flow = TC_424_0.G * TC_424_0.dT; TC_424_0.dT = TC_424_0.port_a.T - TC_424_0.port_b.T; TC_424_0.port_a.Q_flow = TC_424_0.Q_flow; TC_424_0.port_b.Q_flow = -TC_424_0.Q_flow; TC_425_0.Q_flow = TC_425_0.G * TC_425_0.dT; TC_425_0.dT = TC_425_0.port_a.T - TC_425_0.port_b.T; TC_425_0.port_a.Q_flow = TC_425_0.Q_flow; TC_425_0.port_b.Q_flow = -TC_425_0.Q_flow; TC_426_0.Q_flow = TC_426_0.G * TC_426_0.dT; TC_426_0.dT = TC_426_0.port_a.T - TC_426_0.port_b.T; TC_426_0.port_a.Q_flow = TC_426_0.Q_flow; TC_426_0.port_b.Q_flow = -TC_426_0.Q_flow; TC_427_0.Q_flow = TC_427_0.G * TC_427_0.dT; TC_427_0.dT = TC_427_0.port_a.T - TC_427_0.port_b.T; TC_427_0.port_a.Q_flow = TC_427_0.Q_flow; TC_427_0.port_b.Q_flow = -TC_427_0.Q_flow; TC_428_0.Q_flow = TC_428_0.G * TC_428_0.dT; TC_428_0.dT = TC_428_0.port_a.T - TC_428_0.port_b.T; TC_428_0.port_a.Q_flow = TC_428_0.Q_flow; TC_428_0.port_b.Q_flow = -TC_428_0.Q_flow; TC_429_0.Q_flow = TC_429_0.G * TC_429_0.dT; TC_429_0.dT = TC_429_0.port_a.T - TC_429_0.port_b.T; TC_429_0.port_a.Q_flow = TC_429_0.Q_flow; TC_429_0.port_b.Q_flow = -TC_429_0.Q_flow; TC_430_0.Q_flow = TC_430_0.G * TC_430_0.dT; TC_430_0.dT = TC_430_0.port_a.T - TC_430_0.port_b.T; TC_430_0.port_a.Q_flow = TC_430_0.Q_flow; TC_430_0.port_b.Q_flow = -TC_430_0.Q_flow; TC_431_0.Q_flow = TC_431_0.G * TC_431_0.dT; TC_431_0.dT = TC_431_0.port_a.T - TC_431_0.port_b.T; TC_431_0.port_a.Q_flow = TC_431_0.Q_flow; TC_431_0.port_b.Q_flow = -TC_431_0.Q_flow; TC_432_0.Q_flow = TC_432_0.G * TC_432_0.dT; TC_432_0.dT = TC_432_0.port_a.T - TC_432_0.port_b.T; TC_432_0.port_a.Q_flow = TC_432_0.Q_flow; TC_432_0.port_b.Q_flow = -TC_432_0.Q_flow; TC_433_0.Q_flow = TC_433_0.G * TC_433_0.dT; TC_433_0.dT = TC_433_0.port_a.T - TC_433_0.port_b.T; TC_433_0.port_a.Q_flow = TC_433_0.Q_flow; TC_433_0.port_b.Q_flow = -TC_433_0.Q_flow; TC_434_0.Q_flow = TC_434_0.G * TC_434_0.dT; TC_434_0.dT = TC_434_0.port_a.T - TC_434_0.port_b.T; TC_434_0.port_a.Q_flow = TC_434_0.Q_flow; TC_434_0.port_b.Q_flow = -TC_434_0.Q_flow; TC_435_0.Q_flow = TC_435_0.G * TC_435_0.dT; TC_435_0.dT = TC_435_0.port_a.T - TC_435_0.port_b.T; TC_435_0.port_a.Q_flow = TC_435_0.Q_flow; TC_435_0.port_b.Q_flow = -TC_435_0.Q_flow; TC_436_0.Q_flow = TC_436_0.G * TC_436_0.dT; TC_436_0.dT = TC_436_0.port_a.T - TC_436_0.port_b.T; TC_436_0.port_a.Q_flow = TC_436_0.Q_flow; TC_436_0.port_b.Q_flow = -TC_436_0.Q_flow; TC_437_0.Q_flow = TC_437_0.G * TC_437_0.dT; TC_437_0.dT = TC_437_0.port_a.T - TC_437_0.port_b.T; TC_437_0.port_a.Q_flow = TC_437_0.Q_flow; TC_437_0.port_b.Q_flow = -TC_437_0.Q_flow; TC_438_0.Q_flow = TC_438_0.G * TC_438_0.dT; TC_438_0.dT = TC_438_0.port_a.T - TC_438_0.port_b.T; TC_438_0.port_a.Q_flow = TC_438_0.Q_flow; TC_438_0.port_b.Q_flow = -TC_438_0.Q_flow; TC_439_0.Q_flow = TC_439_0.G * TC_439_0.dT; TC_439_0.dT = TC_439_0.port_a.T - TC_439_0.port_b.T; TC_439_0.port_a.Q_flow = TC_439_0.Q_flow; TC_439_0.port_b.Q_flow = -TC_439_0.Q_flow; TC_440_0.Q_flow = TC_440_0.G * TC_440_0.dT; TC_440_0.dT = TC_440_0.port_a.T - TC_440_0.port_b.T; TC_440_0.port_a.Q_flow = TC_440_0.Q_flow; TC_440_0.port_b.Q_flow = -TC_440_0.Q_flow; TC_441_0.Q_flow = TC_441_0.G * TC_441_0.dT; TC_441_0.dT = TC_441_0.port_a.T - TC_441_0.port_b.T; TC_441_0.port_a.Q_flow = TC_441_0.Q_flow; TC_441_0.port_b.Q_flow = -TC_441_0.Q_flow; TC_442_0.Q_flow = TC_442_0.G * TC_442_0.dT; TC_442_0.dT = TC_442_0.port_a.T - TC_442_0.port_b.T; TC_442_0.port_a.Q_flow = TC_442_0.Q_flow; TC_442_0.port_b.Q_flow = -TC_442_0.Q_flow; TC_443_0.Q_flow = TC_443_0.G * TC_443_0.dT; TC_443_0.dT = TC_443_0.port_a.T - TC_443_0.port_b.T; TC_443_0.port_a.Q_flow = TC_443_0.Q_flow; TC_443_0.port_b.Q_flow = -TC_443_0.Q_flow; TC_444_0.Q_flow = TC_444_0.G * TC_444_0.dT; TC_444_0.dT = TC_444_0.port_a.T - TC_444_0.port_b.T; TC_444_0.port_a.Q_flow = TC_444_0.Q_flow; TC_444_0.port_b.Q_flow = -TC_444_0.Q_flow; TC_445_0.Q_flow = TC_445_0.G * TC_445_0.dT; TC_445_0.dT = TC_445_0.port_a.T - TC_445_0.port_b.T; TC_445_0.port_a.Q_flow = TC_445_0.Q_flow; TC_445_0.port_b.Q_flow = -TC_445_0.Q_flow; TC_446_0.Q_flow = TC_446_0.G * TC_446_0.dT; TC_446_0.dT = TC_446_0.port_a.T - TC_446_0.port_b.T; TC_446_0.port_a.Q_flow = TC_446_0.Q_flow; TC_446_0.port_b.Q_flow = -TC_446_0.Q_flow; TC_447_0.Q_flow = TC_447_0.G * TC_447_0.dT; TC_447_0.dT = TC_447_0.port_a.T - TC_447_0.port_b.T; TC_447_0.port_a.Q_flow = TC_447_0.Q_flow; TC_447_0.port_b.Q_flow = -TC_447_0.Q_flow; TC_448_0.Q_flow = TC_448_0.G * TC_448_0.dT; TC_448_0.dT = TC_448_0.port_a.T - TC_448_0.port_b.T; TC_448_0.port_a.Q_flow = TC_448_0.Q_flow; TC_448_0.port_b.Q_flow = -TC_448_0.Q_flow; TC_449_0.Q_flow = TC_449_0.G * TC_449_0.dT; TC_449_0.dT = TC_449_0.port_a.T - TC_449_0.port_b.T; TC_449_0.port_a.Q_flow = TC_449_0.Q_flow; TC_449_0.port_b.Q_flow = -TC_449_0.Q_flow; TC_450_0.Q_flow = TC_450_0.G * TC_450_0.dT; TC_450_0.dT = TC_450_0.port_a.T - TC_450_0.port_b.T; TC_450_0.port_a.Q_flow = TC_450_0.Q_flow; TC_450_0.port_b.Q_flow = -TC_450_0.Q_flow; TC_451_0.Q_flow = TC_451_0.G * TC_451_0.dT; TC_451_0.dT = TC_451_0.port_a.T - TC_451_0.port_b.T; TC_451_0.port_a.Q_flow = TC_451_0.Q_flow; TC_451_0.port_b.Q_flow = -TC_451_0.Q_flow; TC_452_0.Q_flow = TC_452_0.G * TC_452_0.dT; TC_452_0.dT = TC_452_0.port_a.T - TC_452_0.port_b.T; TC_452_0.port_a.Q_flow = TC_452_0.Q_flow; TC_452_0.port_b.Q_flow = -TC_452_0.Q_flow; TC_453_0.Q_flow = TC_453_0.G * TC_453_0.dT; TC_453_0.dT = TC_453_0.port_a.T - TC_453_0.port_b.T; TC_453_0.port_a.Q_flow = TC_453_0.Q_flow; TC_453_0.port_b.Q_flow = -TC_453_0.Q_flow; TC_454_0.Q_flow = TC_454_0.G * TC_454_0.dT; TC_454_0.dT = TC_454_0.port_a.T - TC_454_0.port_b.T; TC_454_0.port_a.Q_flow = TC_454_0.Q_flow; TC_454_0.port_b.Q_flow = -TC_454_0.Q_flow; TC_455_0.Q_flow = TC_455_0.G * TC_455_0.dT; TC_455_0.dT = TC_455_0.port_a.T - TC_455_0.port_b.T; TC_455_0.port_a.Q_flow = TC_455_0.Q_flow; TC_455_0.port_b.Q_flow = -TC_455_0.Q_flow; TC_456_0.Q_flow = TC_456_0.G * TC_456_0.dT; TC_456_0.dT = TC_456_0.port_a.T - TC_456_0.port_b.T; TC_456_0.port_a.Q_flow = TC_456_0.Q_flow; TC_456_0.port_b.Q_flow = -TC_456_0.Q_flow; TC_457_0.Q_flow = TC_457_0.G * TC_457_0.dT; TC_457_0.dT = TC_457_0.port_a.T - TC_457_0.port_b.T; TC_457_0.port_a.Q_flow = TC_457_0.Q_flow; TC_457_0.port_b.Q_flow = -TC_457_0.Q_flow; TC_458_0.Q_flow = TC_458_0.G * TC_458_0.dT; TC_458_0.dT = TC_458_0.port_a.T - TC_458_0.port_b.T; TC_458_0.port_a.Q_flow = TC_458_0.Q_flow; TC_458_0.port_b.Q_flow = -TC_458_0.Q_flow; TC_459_0.Q_flow = TC_459_0.G * TC_459_0.dT; TC_459_0.dT = TC_459_0.port_a.T - TC_459_0.port_b.T; TC_459_0.port_a.Q_flow = TC_459_0.Q_flow; TC_459_0.port_b.Q_flow = -TC_459_0.Q_flow; TC_460_0.Q_flow = TC_460_0.G * TC_460_0.dT; TC_460_0.dT = TC_460_0.port_a.T - TC_460_0.port_b.T; TC_460_0.port_a.Q_flow = TC_460_0.Q_flow; TC_460_0.port_b.Q_flow = -TC_460_0.Q_flow; TC_461_0.Q_flow = TC_461_0.G * TC_461_0.dT; TC_461_0.dT = TC_461_0.port_a.T - TC_461_0.port_b.T; TC_461_0.port_a.Q_flow = TC_461_0.Q_flow; TC_461_0.port_b.Q_flow = -TC_461_0.Q_flow; TC_462_0.Q_flow = TC_462_0.G * TC_462_0.dT; TC_462_0.dT = TC_462_0.port_a.T - TC_462_0.port_b.T; TC_462_0.port_a.Q_flow = TC_462_0.Q_flow; TC_462_0.port_b.Q_flow = -TC_462_0.Q_flow; TC_463_0.Q_flow = TC_463_0.G * TC_463_0.dT; TC_463_0.dT = TC_463_0.port_a.T - TC_463_0.port_b.T; TC_463_0.port_a.Q_flow = TC_463_0.Q_flow; TC_463_0.port_b.Q_flow = -TC_463_0.Q_flow; TC_464_0.Q_flow = TC_464_0.G * TC_464_0.dT; TC_464_0.dT = TC_464_0.port_a.T - TC_464_0.port_b.T; TC_464_0.port_a.Q_flow = TC_464_0.Q_flow; TC_464_0.port_b.Q_flow = -TC_464_0.Q_flow; TC_465_0.Q_flow = TC_465_0.G * TC_465_0.dT; TC_465_0.dT = TC_465_0.port_a.T - TC_465_0.port_b.T; TC_465_0.port_a.Q_flow = TC_465_0.Q_flow; TC_465_0.port_b.Q_flow = -TC_465_0.Q_flow; TC_466_0.Q_flow = TC_466_0.G * TC_466_0.dT; TC_466_0.dT = TC_466_0.port_a.T - TC_466_0.port_b.T; TC_466_0.port_a.Q_flow = TC_466_0.Q_flow; TC_466_0.port_b.Q_flow = -TC_466_0.Q_flow; TC_467_0.Q_flow = TC_467_0.G * TC_467_0.dT; TC_467_0.dT = TC_467_0.port_a.T - TC_467_0.port_b.T; TC_467_0.port_a.Q_flow = TC_467_0.Q_flow; TC_467_0.port_b.Q_flow = -TC_467_0.Q_flow; TC_468_0.Q_flow = TC_468_0.G * TC_468_0.dT; TC_468_0.dT = TC_468_0.port_a.T - TC_468_0.port_b.T; TC_468_0.port_a.Q_flow = TC_468_0.Q_flow; TC_468_0.port_b.Q_flow = -TC_468_0.Q_flow; TC_469_0.Q_flow = TC_469_0.G * TC_469_0.dT; TC_469_0.dT = TC_469_0.port_a.T - TC_469_0.port_b.T; TC_469_0.port_a.Q_flow = TC_469_0.Q_flow; TC_469_0.port_b.Q_flow = -TC_469_0.Q_flow; TC_470_0.Q_flow = TC_470_0.G * TC_470_0.dT; TC_470_0.dT = TC_470_0.port_a.T - TC_470_0.port_b.T; TC_470_0.port_a.Q_flow = TC_470_0.Q_flow; TC_470_0.port_b.Q_flow = -TC_470_0.Q_flow; TC_471_0.Q_flow = TC_471_0.G * TC_471_0.dT; TC_471_0.dT = TC_471_0.port_a.T - TC_471_0.port_b.T; TC_471_0.port_a.Q_flow = TC_471_0.Q_flow; TC_471_0.port_b.Q_flow = -TC_471_0.Q_flow; TC_472_0.Q_flow = TC_472_0.G * TC_472_0.dT; TC_472_0.dT = TC_472_0.port_a.T - TC_472_0.port_b.T; TC_472_0.port_a.Q_flow = TC_472_0.Q_flow; TC_472_0.port_b.Q_flow = -TC_472_0.Q_flow; TC_473_0.Q_flow = TC_473_0.G * TC_473_0.dT; TC_473_0.dT = TC_473_0.port_a.T - TC_473_0.port_b.T; TC_473_0.port_a.Q_flow = TC_473_0.Q_flow; TC_473_0.port_b.Q_flow = -TC_473_0.Q_flow; TC_474_0.Q_flow = TC_474_0.G * TC_474_0.dT; TC_474_0.dT = TC_474_0.port_a.T - TC_474_0.port_b.T; TC_474_0.port_a.Q_flow = TC_474_0.Q_flow; TC_474_0.port_b.Q_flow = -TC_474_0.Q_flow; TC_475_0.Q_flow = TC_475_0.G * TC_475_0.dT; TC_475_0.dT = TC_475_0.port_a.T - TC_475_0.port_b.T; TC_475_0.port_a.Q_flow = TC_475_0.Q_flow; TC_475_0.port_b.Q_flow = -TC_475_0.Q_flow; TC_476_0.Q_flow = TC_476_0.G * TC_476_0.dT; TC_476_0.dT = TC_476_0.port_a.T - TC_476_0.port_b.T; TC_476_0.port_a.Q_flow = TC_476_0.Q_flow; TC_476_0.port_b.Q_flow = -TC_476_0.Q_flow; TC_477_0.Q_flow = TC_477_0.G * TC_477_0.dT; TC_477_0.dT = TC_477_0.port_a.T - TC_477_0.port_b.T; TC_477_0.port_a.Q_flow = TC_477_0.Q_flow; TC_477_0.port_b.Q_flow = -TC_477_0.Q_flow; TC_478_0.Q_flow = TC_478_0.G * TC_478_0.dT; TC_478_0.dT = TC_478_0.port_a.T - TC_478_0.port_b.T; TC_478_0.port_a.Q_flow = TC_478_0.Q_flow; TC_478_0.port_b.Q_flow = -TC_478_0.Q_flow; TC_479_0.Q_flow = TC_479_0.G * TC_479_0.dT; TC_479_0.dT = TC_479_0.port_a.T - TC_479_0.port_b.T; TC_479_0.port_a.Q_flow = TC_479_0.Q_flow; TC_479_0.port_b.Q_flow = -TC_479_0.Q_flow; TC_480_0.Q_flow = TC_480_0.G * TC_480_0.dT; TC_480_0.dT = TC_480_0.port_a.T - TC_480_0.port_b.T; TC_480_0.port_a.Q_flow = TC_480_0.Q_flow; TC_480_0.port_b.Q_flow = -TC_480_0.Q_flow; TC_481_0.Q_flow = TC_481_0.G * TC_481_0.dT; TC_481_0.dT = TC_481_0.port_a.T - TC_481_0.port_b.T; TC_481_0.port_a.Q_flow = TC_481_0.Q_flow; TC_481_0.port_b.Q_flow = -TC_481_0.Q_flow; TC_482_0.Q_flow = TC_482_0.G * TC_482_0.dT; TC_482_0.dT = TC_482_0.port_a.T - TC_482_0.port_b.T; TC_482_0.port_a.Q_flow = TC_482_0.Q_flow; TC_482_0.port_b.Q_flow = -TC_482_0.Q_flow; TC_483_0.Q_flow = TC_483_0.G * TC_483_0.dT; TC_483_0.dT = TC_483_0.port_a.T - TC_483_0.port_b.T; TC_483_0.port_a.Q_flow = TC_483_0.Q_flow; TC_483_0.port_b.Q_flow = -TC_483_0.Q_flow; TC_484_0.Q_flow = TC_484_0.G * TC_484_0.dT; TC_484_0.dT = TC_484_0.port_a.T - TC_484_0.port_b.T; TC_484_0.port_a.Q_flow = TC_484_0.Q_flow; TC_484_0.port_b.Q_flow = -TC_484_0.Q_flow; TC_485_0.Q_flow = TC_485_0.G * TC_485_0.dT; TC_485_0.dT = TC_485_0.port_a.T - TC_485_0.port_b.T; TC_485_0.port_a.Q_flow = TC_485_0.Q_flow; TC_485_0.port_b.Q_flow = -TC_485_0.Q_flow; TC_486_0.Q_flow = TC_486_0.G * TC_486_0.dT; TC_486_0.dT = TC_486_0.port_a.T - TC_486_0.port_b.T; TC_486_0.port_a.Q_flow = TC_486_0.Q_flow; TC_486_0.port_b.Q_flow = -TC_486_0.Q_flow; TC_487_0.Q_flow = TC_487_0.G * TC_487_0.dT; TC_487_0.dT = TC_487_0.port_a.T - TC_487_0.port_b.T; TC_487_0.port_a.Q_flow = TC_487_0.Q_flow; TC_487_0.port_b.Q_flow = -TC_487_0.Q_flow; TC_488_0.Q_flow = TC_488_0.G * TC_488_0.dT; TC_488_0.dT = TC_488_0.port_a.T - TC_488_0.port_b.T; TC_488_0.port_a.Q_flow = TC_488_0.Q_flow; TC_488_0.port_b.Q_flow = -TC_488_0.Q_flow; TC_489_0.Q_flow = TC_489_0.G * TC_489_0.dT; TC_489_0.dT = TC_489_0.port_a.T - TC_489_0.port_b.T; TC_489_0.port_a.Q_flow = TC_489_0.Q_flow; TC_489_0.port_b.Q_flow = -TC_489_0.Q_flow; TC_490_0.Q_flow = TC_490_0.G * TC_490_0.dT; TC_490_0.dT = TC_490_0.port_a.T - TC_490_0.port_b.T; TC_490_0.port_a.Q_flow = TC_490_0.Q_flow; TC_490_0.port_b.Q_flow = -TC_490_0.Q_flow; TC_491_0.Q_flow = TC_491_0.G * TC_491_0.dT; TC_491_0.dT = TC_491_0.port_a.T - TC_491_0.port_b.T; TC_491_0.port_a.Q_flow = TC_491_0.Q_flow; TC_491_0.port_b.Q_flow = -TC_491_0.Q_flow; TC_492_0.Q_flow = TC_492_0.G * TC_492_0.dT; TC_492_0.dT = TC_492_0.port_a.T - TC_492_0.port_b.T; TC_492_0.port_a.Q_flow = TC_492_0.Q_flow; TC_492_0.port_b.Q_flow = -TC_492_0.Q_flow; TC_493_0.Q_flow = TC_493_0.G * TC_493_0.dT; TC_493_0.dT = TC_493_0.port_a.T - TC_493_0.port_b.T; TC_493_0.port_a.Q_flow = TC_493_0.Q_flow; TC_493_0.port_b.Q_flow = -TC_493_0.Q_flow; TC_494_0.Q_flow = TC_494_0.G * TC_494_0.dT; TC_494_0.dT = TC_494_0.port_a.T - TC_494_0.port_b.T; TC_494_0.port_a.Q_flow = TC_494_0.Q_flow; TC_494_0.port_b.Q_flow = -TC_494_0.Q_flow; TC_495_0.Q_flow = TC_495_0.G * TC_495_0.dT; TC_495_0.dT = TC_495_0.port_a.T - TC_495_0.port_b.T; TC_495_0.port_a.Q_flow = TC_495_0.Q_flow; TC_495_0.port_b.Q_flow = -TC_495_0.Q_flow; TC_496_0.Q_flow = TC_496_0.G * TC_496_0.dT; TC_496_0.dT = TC_496_0.port_a.T - TC_496_0.port_b.T; TC_496_0.port_a.Q_flow = TC_496_0.Q_flow; TC_496_0.port_b.Q_flow = -TC_496_0.Q_flow; TC_497_0.Q_flow = TC_497_0.G * TC_497_0.dT; TC_497_0.dT = TC_497_0.port_a.T - TC_497_0.port_b.T; TC_497_0.port_a.Q_flow = TC_497_0.Q_flow; TC_497_0.port_b.Q_flow = -TC_497_0.Q_flow; TC_498_0.Q_flow = TC_498_0.G * TC_498_0.dT; TC_498_0.dT = TC_498_0.port_a.T - TC_498_0.port_b.T; TC_498_0.port_a.Q_flow = TC_498_0.Q_flow; TC_498_0.port_b.Q_flow = -TC_498_0.Q_flow; TC_499_0.Q_flow = TC_499_0.G * TC_499_0.dT; TC_499_0.dT = TC_499_0.port_a.T - TC_499_0.port_b.T; TC_499_0.port_a.Q_flow = TC_499_0.Q_flow; TC_499_0.port_b.Q_flow = -TC_499_0.Q_flow; TC_500_0.Q_flow = TC_500_0.G * TC_500_0.dT; TC_500_0.dT = TC_500_0.port_a.T - TC_500_0.port_b.T; TC_500_0.port_a.Q_flow = TC_500_0.Q_flow; TC_500_0.port_b.Q_flow = -TC_500_0.Q_flow; TC_501_0.Q_flow = TC_501_0.G * TC_501_0.dT; TC_501_0.dT = TC_501_0.port_a.T - TC_501_0.port_b.T; TC_501_0.port_a.Q_flow = TC_501_0.Q_flow; TC_501_0.port_b.Q_flow = -TC_501_0.Q_flow; TC_502_0.Q_flow = TC_502_0.G * TC_502_0.dT; TC_502_0.dT = TC_502_0.port_a.T - TC_502_0.port_b.T; TC_502_0.port_a.Q_flow = TC_502_0.Q_flow; TC_502_0.port_b.Q_flow = -TC_502_0.Q_flow; TC_503_0.Q_flow = TC_503_0.G * TC_503_0.dT; TC_503_0.dT = TC_503_0.port_a.T - TC_503_0.port_b.T; TC_503_0.port_a.Q_flow = TC_503_0.Q_flow; TC_503_0.port_b.Q_flow = -TC_503_0.Q_flow; TC_504_0.Q_flow = TC_504_0.G * TC_504_0.dT; TC_504_0.dT = TC_504_0.port_a.T - TC_504_0.port_b.T; TC_504_0.port_a.Q_flow = TC_504_0.Q_flow; TC_504_0.port_b.Q_flow = -TC_504_0.Q_flow; TC_505_0.Q_flow = TC_505_0.G * TC_505_0.dT; TC_505_0.dT = TC_505_0.port_a.T - TC_505_0.port_b.T; TC_505_0.port_a.Q_flow = TC_505_0.Q_flow; TC_505_0.port_b.Q_flow = -TC_505_0.Q_flow; TC_506_0.Q_flow = TC_506_0.G * TC_506_0.dT; TC_506_0.dT = TC_506_0.port_a.T - TC_506_0.port_b.T; TC_506_0.port_a.Q_flow = TC_506_0.Q_flow; TC_506_0.port_b.Q_flow = -TC_506_0.Q_flow; TC_507_0.Q_flow = TC_507_0.G * TC_507_0.dT; TC_507_0.dT = TC_507_0.port_a.T - TC_507_0.port_b.T; TC_507_0.port_a.Q_flow = TC_507_0.Q_flow; TC_507_0.port_b.Q_flow = -TC_507_0.Q_flow; TC_508_0.Q_flow = TC_508_0.G * TC_508_0.dT; TC_508_0.dT = TC_508_0.port_a.T - TC_508_0.port_b.T; TC_508_0.port_a.Q_flow = TC_508_0.Q_flow; TC_508_0.port_b.Q_flow = -TC_508_0.Q_flow; TC_509_0.Q_flow = TC_509_0.G * TC_509_0.dT; TC_509_0.dT = TC_509_0.port_a.T - TC_509_0.port_b.T; TC_509_0.port_a.Q_flow = TC_509_0.Q_flow; TC_509_0.port_b.Q_flow = -TC_509_0.Q_flow; TC_510_0.Q_flow = TC_510_0.G * TC_510_0.dT; TC_510_0.dT = TC_510_0.port_a.T - TC_510_0.port_b.T; TC_510_0.port_a.Q_flow = TC_510_0.Q_flow; TC_510_0.port_b.Q_flow = -TC_510_0.Q_flow; TC_511_0.Q_flow = TC_511_0.G * TC_511_0.dT; TC_511_0.dT = TC_511_0.port_a.T - TC_511_0.port_b.T; TC_511_0.port_a.Q_flow = TC_511_0.Q_flow; TC_511_0.port_b.Q_flow = -TC_511_0.Q_flow; TC_512_0.Q_flow = TC_512_0.G * TC_512_0.dT; TC_512_0.dT = TC_512_0.port_a.T - TC_512_0.port_b.T; TC_512_0.port_a.Q_flow = TC_512_0.Q_flow; TC_512_0.port_b.Q_flow = -TC_512_0.Q_flow; TC_513_0.Q_flow = TC_513_0.G * TC_513_0.dT; TC_513_0.dT = TC_513_0.port_a.T - TC_513_0.port_b.T; TC_513_0.port_a.Q_flow = TC_513_0.Q_flow; TC_513_0.port_b.Q_flow = -TC_513_0.Q_flow; TC_514_0.Q_flow = TC_514_0.G * TC_514_0.dT; TC_514_0.dT = TC_514_0.port_a.T - TC_514_0.port_b.T; TC_514_0.port_a.Q_flow = TC_514_0.Q_flow; TC_514_0.port_b.Q_flow = -TC_514_0.Q_flow; TC_515_0.Q_flow = TC_515_0.G * TC_515_0.dT; TC_515_0.dT = TC_515_0.port_a.T - TC_515_0.port_b.T; TC_515_0.port_a.Q_flow = TC_515_0.Q_flow; TC_515_0.port_b.Q_flow = -TC_515_0.Q_flow; TC_516_0.Q_flow = TC_516_0.G * TC_516_0.dT; TC_516_0.dT = TC_516_0.port_a.T - TC_516_0.port_b.T; TC_516_0.port_a.Q_flow = TC_516_0.Q_flow; TC_516_0.port_b.Q_flow = -TC_516_0.Q_flow; TC_517_0.Q_flow = TC_517_0.G * TC_517_0.dT; TC_517_0.dT = TC_517_0.port_a.T - TC_517_0.port_b.T; TC_517_0.port_a.Q_flow = TC_517_0.Q_flow; TC_517_0.port_b.Q_flow = -TC_517_0.Q_flow; TC_518_0.Q_flow = TC_518_0.G * TC_518_0.dT; TC_518_0.dT = TC_518_0.port_a.T - TC_518_0.port_b.T; TC_518_0.port_a.Q_flow = TC_518_0.Q_flow; TC_518_0.port_b.Q_flow = -TC_518_0.Q_flow; TC_519_0.Q_flow = TC_519_0.G * TC_519_0.dT; TC_519_0.dT = TC_519_0.port_a.T - TC_519_0.port_b.T; TC_519_0.port_a.Q_flow = TC_519_0.Q_flow; TC_519_0.port_b.Q_flow = -TC_519_0.Q_flow; TC_520_0.Q_flow = TC_520_0.G * TC_520_0.dT; TC_520_0.dT = TC_520_0.port_a.T - TC_520_0.port_b.T; TC_520_0.port_a.Q_flow = TC_520_0.Q_flow; TC_520_0.port_b.Q_flow = -TC_520_0.Q_flow; TC_521_0.Q_flow = TC_521_0.G * TC_521_0.dT; TC_521_0.dT = TC_521_0.port_a.T - TC_521_0.port_b.T; TC_521_0.port_a.Q_flow = TC_521_0.Q_flow; TC_521_0.port_b.Q_flow = -TC_521_0.Q_flow; TC_522_0.Q_flow = TC_522_0.G * TC_522_0.dT; TC_522_0.dT = TC_522_0.port_a.T - TC_522_0.port_b.T; TC_522_0.port_a.Q_flow = TC_522_0.Q_flow; TC_522_0.port_b.Q_flow = -TC_522_0.Q_flow; TC_523_0.Q_flow = TC_523_0.G * TC_523_0.dT; TC_523_0.dT = TC_523_0.port_a.T - TC_523_0.port_b.T; TC_523_0.port_a.Q_flow = TC_523_0.Q_flow; TC_523_0.port_b.Q_flow = -TC_523_0.Q_flow; TC_524_0.Q_flow = TC_524_0.G * TC_524_0.dT; TC_524_0.dT = TC_524_0.port_a.T - TC_524_0.port_b.T; TC_524_0.port_a.Q_flow = TC_524_0.Q_flow; TC_524_0.port_b.Q_flow = -TC_524_0.Q_flow; TC_525_0.Q_flow = TC_525_0.G * TC_525_0.dT; TC_525_0.dT = TC_525_0.port_a.T - TC_525_0.port_b.T; TC_525_0.port_a.Q_flow = TC_525_0.Q_flow; TC_525_0.port_b.Q_flow = -TC_525_0.Q_flow; TC_526_0.Q_flow = TC_526_0.G * TC_526_0.dT; TC_526_0.dT = TC_526_0.port_a.T - TC_526_0.port_b.T; TC_526_0.port_a.Q_flow = TC_526_0.Q_flow; TC_526_0.port_b.Q_flow = -TC_526_0.Q_flow; TC_527_0.Q_flow = TC_527_0.G * TC_527_0.dT; TC_527_0.dT = TC_527_0.port_a.T - TC_527_0.port_b.T; TC_527_0.port_a.Q_flow = TC_527_0.Q_flow; TC_527_0.port_b.Q_flow = -TC_527_0.Q_flow; TC_528_0.Q_flow = TC_528_0.G * TC_528_0.dT; TC_528_0.dT = TC_528_0.port_a.T - TC_528_0.port_b.T; TC_528_0.port_a.Q_flow = TC_528_0.Q_flow; TC_528_0.port_b.Q_flow = -TC_528_0.Q_flow; TC_529_0.Q_flow = TC_529_0.G * TC_529_0.dT; TC_529_0.dT = TC_529_0.port_a.T - TC_529_0.port_b.T; TC_529_0.port_a.Q_flow = TC_529_0.Q_flow; TC_529_0.port_b.Q_flow = -TC_529_0.Q_flow; TC_530_0.Q_flow = TC_530_0.G * TC_530_0.dT; TC_530_0.dT = TC_530_0.port_a.T - TC_530_0.port_b.T; TC_530_0.port_a.Q_flow = TC_530_0.Q_flow; TC_530_0.port_b.Q_flow = -TC_530_0.Q_flow; TC_531_0.Q_flow = TC_531_0.G * TC_531_0.dT; TC_531_0.dT = TC_531_0.port_a.T - TC_531_0.port_b.T; TC_531_0.port_a.Q_flow = TC_531_0.Q_flow; TC_531_0.port_b.Q_flow = -TC_531_0.Q_flow; TC_532_0.Q_flow = TC_532_0.G * TC_532_0.dT; TC_532_0.dT = TC_532_0.port_a.T - TC_532_0.port_b.T; TC_532_0.port_a.Q_flow = TC_532_0.Q_flow; TC_532_0.port_b.Q_flow = -TC_532_0.Q_flow; TC_533_0.Q_flow = TC_533_0.G * TC_533_0.dT; TC_533_0.dT = TC_533_0.port_a.T - TC_533_0.port_b.T; TC_533_0.port_a.Q_flow = TC_533_0.Q_flow; TC_533_0.port_b.Q_flow = -TC_533_0.Q_flow; TC_534_0.Q_flow = TC_534_0.G * TC_534_0.dT; TC_534_0.dT = TC_534_0.port_a.T - TC_534_0.port_b.T; TC_534_0.port_a.Q_flow = TC_534_0.Q_flow; TC_534_0.port_b.Q_flow = -TC_534_0.Q_flow; TC_535_0.Q_flow = TC_535_0.G * TC_535_0.dT; TC_535_0.dT = TC_535_0.port_a.T - TC_535_0.port_b.T; TC_535_0.port_a.Q_flow = TC_535_0.Q_flow; TC_535_0.port_b.Q_flow = -TC_535_0.Q_flow; TC_536_0.Q_flow = TC_536_0.G * TC_536_0.dT; TC_536_0.dT = TC_536_0.port_a.T - TC_536_0.port_b.T; TC_536_0.port_a.Q_flow = TC_536_0.Q_flow; TC_536_0.port_b.Q_flow = -TC_536_0.Q_flow; TC_537_0.Q_flow = TC_537_0.G * TC_537_0.dT; TC_537_0.dT = TC_537_0.port_a.T - TC_537_0.port_b.T; TC_537_0.port_a.Q_flow = TC_537_0.Q_flow; TC_537_0.port_b.Q_flow = -TC_537_0.Q_flow; TC_538_0.Q_flow = TC_538_0.G * TC_538_0.dT; TC_538_0.dT = TC_538_0.port_a.T - TC_538_0.port_b.T; TC_538_0.port_a.Q_flow = TC_538_0.Q_flow; TC_538_0.port_b.Q_flow = -TC_538_0.Q_flow; TC_539_0.Q_flow = TC_539_0.G * TC_539_0.dT; TC_539_0.dT = TC_539_0.port_a.T - TC_539_0.port_b.T; TC_539_0.port_a.Q_flow = TC_539_0.Q_flow; TC_539_0.port_b.Q_flow = -TC_539_0.Q_flow; TC_540_0.Q_flow = TC_540_0.G * TC_540_0.dT; TC_540_0.dT = TC_540_0.port_a.T - TC_540_0.port_b.T; TC_540_0.port_a.Q_flow = TC_540_0.Q_flow; TC_540_0.port_b.Q_flow = -TC_540_0.Q_flow; TC_541_0.Q_flow = TC_541_0.G * TC_541_0.dT; TC_541_0.dT = TC_541_0.port_a.T - TC_541_0.port_b.T; TC_541_0.port_a.Q_flow = TC_541_0.Q_flow; TC_541_0.port_b.Q_flow = -TC_541_0.Q_flow; TC_542_0.Q_flow = TC_542_0.G * TC_542_0.dT; TC_542_0.dT = TC_542_0.port_a.T - TC_542_0.port_b.T; TC_542_0.port_a.Q_flow = TC_542_0.Q_flow; TC_542_0.port_b.Q_flow = -TC_542_0.Q_flow; TC_543_0.Q_flow = TC_543_0.G * TC_543_0.dT; TC_543_0.dT = TC_543_0.port_a.T - TC_543_0.port_b.T; TC_543_0.port_a.Q_flow = TC_543_0.Q_flow; TC_543_0.port_b.Q_flow = -TC_543_0.Q_flow; TC_544_0.Q_flow = TC_544_0.G * TC_544_0.dT; TC_544_0.dT = TC_544_0.port_a.T - TC_544_0.port_b.T; TC_544_0.port_a.Q_flow = TC_544_0.Q_flow; TC_544_0.port_b.Q_flow = -TC_544_0.Q_flow; TC_545_0.Q_flow = TC_545_0.G * TC_545_0.dT; TC_545_0.dT = TC_545_0.port_a.T - TC_545_0.port_b.T; TC_545_0.port_a.Q_flow = TC_545_0.Q_flow; TC_545_0.port_b.Q_flow = -TC_545_0.Q_flow; TC_546_0.Q_flow = TC_546_0.G * TC_546_0.dT; TC_546_0.dT = TC_546_0.port_a.T - TC_546_0.port_b.T; TC_546_0.port_a.Q_flow = TC_546_0.Q_flow; TC_546_0.port_b.Q_flow = -TC_546_0.Q_flow; TC_547_0.Q_flow = TC_547_0.G * TC_547_0.dT; TC_547_0.dT = TC_547_0.port_a.T - TC_547_0.port_b.T; TC_547_0.port_a.Q_flow = TC_547_0.Q_flow; TC_547_0.port_b.Q_flow = -TC_547_0.Q_flow; TC_548_0.Q_flow = TC_548_0.G * TC_548_0.dT; TC_548_0.dT = TC_548_0.port_a.T - TC_548_0.port_b.T; TC_548_0.port_a.Q_flow = TC_548_0.Q_flow; TC_548_0.port_b.Q_flow = -TC_548_0.Q_flow; TC_549_0.Q_flow = TC_549_0.G * TC_549_0.dT; TC_549_0.dT = TC_549_0.port_a.T - TC_549_0.port_b.T; TC_549_0.port_a.Q_flow = TC_549_0.Q_flow; TC_549_0.port_b.Q_flow = -TC_549_0.Q_flow; TC_550_0.Q_flow = TC_550_0.G * TC_550_0.dT; TC_550_0.dT = TC_550_0.port_a.T - TC_550_0.port_b.T; TC_550_0.port_a.Q_flow = TC_550_0.Q_flow; TC_550_0.port_b.Q_flow = -TC_550_0.Q_flow; TC_551_0.Q_flow = TC_551_0.G * TC_551_0.dT; TC_551_0.dT = TC_551_0.port_a.T - TC_551_0.port_b.T; TC_551_0.port_a.Q_flow = TC_551_0.Q_flow; TC_551_0.port_b.Q_flow = -TC_551_0.Q_flow; TC_552_0.Q_flow = TC_552_0.G * TC_552_0.dT; TC_552_0.dT = TC_552_0.port_a.T - TC_552_0.port_b.T; TC_552_0.port_a.Q_flow = TC_552_0.Q_flow; TC_552_0.port_b.Q_flow = -TC_552_0.Q_flow; TC_553_0.Q_flow = TC_553_0.G * TC_553_0.dT; TC_553_0.dT = TC_553_0.port_a.T - TC_553_0.port_b.T; TC_553_0.port_a.Q_flow = TC_553_0.Q_flow; TC_553_0.port_b.Q_flow = -TC_553_0.Q_flow; TC_554_0.Q_flow = TC_554_0.G * TC_554_0.dT; TC_554_0.dT = TC_554_0.port_a.T - TC_554_0.port_b.T; TC_554_0.port_a.Q_flow = TC_554_0.Q_flow; TC_554_0.port_b.Q_flow = -TC_554_0.Q_flow; TC_555_0.Q_flow = TC_555_0.G * TC_555_0.dT; TC_555_0.dT = TC_555_0.port_a.T - TC_555_0.port_b.T; TC_555_0.port_a.Q_flow = TC_555_0.Q_flow; TC_555_0.port_b.Q_flow = -TC_555_0.Q_flow; TC_556_0.Q_flow = TC_556_0.G * TC_556_0.dT; TC_556_0.dT = TC_556_0.port_a.T - TC_556_0.port_b.T; TC_556_0.port_a.Q_flow = TC_556_0.Q_flow; TC_556_0.port_b.Q_flow = -TC_556_0.Q_flow; TC_557_0.Q_flow = TC_557_0.G * TC_557_0.dT; TC_557_0.dT = TC_557_0.port_a.T - TC_557_0.port_b.T; TC_557_0.port_a.Q_flow = TC_557_0.Q_flow; TC_557_0.port_b.Q_flow = -TC_557_0.Q_flow; TC_558_0.Q_flow = TC_558_0.G * TC_558_0.dT; TC_558_0.dT = TC_558_0.port_a.T - TC_558_0.port_b.T; TC_558_0.port_a.Q_flow = TC_558_0.Q_flow; TC_558_0.port_b.Q_flow = -TC_558_0.Q_flow; TC_559_0.Q_flow = TC_559_0.G * TC_559_0.dT; TC_559_0.dT = TC_559_0.port_a.T - TC_559_0.port_b.T; TC_559_0.port_a.Q_flow = TC_559_0.Q_flow; TC_559_0.port_b.Q_flow = -TC_559_0.Q_flow; TC_560_0.Q_flow = TC_560_0.G * TC_560_0.dT; TC_560_0.dT = TC_560_0.port_a.T - TC_560_0.port_b.T; TC_560_0.port_a.Q_flow = TC_560_0.Q_flow; TC_560_0.port_b.Q_flow = -TC_560_0.Q_flow; TC_561_0.Q_flow = TC_561_0.G * TC_561_0.dT; TC_561_0.dT = TC_561_0.port_a.T - TC_561_0.port_b.T; TC_561_0.port_a.Q_flow = TC_561_0.Q_flow; TC_561_0.port_b.Q_flow = -TC_561_0.Q_flow; TC_562_0.Q_flow = TC_562_0.G * TC_562_0.dT; TC_562_0.dT = TC_562_0.port_a.T - TC_562_0.port_b.T; TC_562_0.port_a.Q_flow = TC_562_0.Q_flow; TC_562_0.port_b.Q_flow = -TC_562_0.Q_flow; TC_563_0.Q_flow = TC_563_0.G * TC_563_0.dT; TC_563_0.dT = TC_563_0.port_a.T - TC_563_0.port_b.T; TC_563_0.port_a.Q_flow = TC_563_0.Q_flow; TC_563_0.port_b.Q_flow = -TC_563_0.Q_flow; TC_564_0.Q_flow = TC_564_0.G * TC_564_0.dT; TC_564_0.dT = TC_564_0.port_a.T - TC_564_0.port_b.T; TC_564_0.port_a.Q_flow = TC_564_0.Q_flow; TC_564_0.port_b.Q_flow = -TC_564_0.Q_flow; TC_565_0.Q_flow = TC_565_0.G * TC_565_0.dT; TC_565_0.dT = TC_565_0.port_a.T - TC_565_0.port_b.T; TC_565_0.port_a.Q_flow = TC_565_0.Q_flow; TC_565_0.port_b.Q_flow = -TC_565_0.Q_flow; TC_566_0.Q_flow = TC_566_0.G * TC_566_0.dT; TC_566_0.dT = TC_566_0.port_a.T - TC_566_0.port_b.T; TC_566_0.port_a.Q_flow = TC_566_0.Q_flow; TC_566_0.port_b.Q_flow = -TC_566_0.Q_flow; TC_567_0.Q_flow = TC_567_0.G * TC_567_0.dT; TC_567_0.dT = TC_567_0.port_a.T - TC_567_0.port_b.T; TC_567_0.port_a.Q_flow = TC_567_0.Q_flow; TC_567_0.port_b.Q_flow = -TC_567_0.Q_flow; TC_568_0.Q_flow = TC_568_0.G * TC_568_0.dT; TC_568_0.dT = TC_568_0.port_a.T - TC_568_0.port_b.T; TC_568_0.port_a.Q_flow = TC_568_0.Q_flow; TC_568_0.port_b.Q_flow = -TC_568_0.Q_flow; TC_569_0.Q_flow = TC_569_0.G * TC_569_0.dT; TC_569_0.dT = TC_569_0.port_a.T - TC_569_0.port_b.T; TC_569_0.port_a.Q_flow = TC_569_0.Q_flow; TC_569_0.port_b.Q_flow = -TC_569_0.Q_flow; TC_570_0.Q_flow = TC_570_0.G * TC_570_0.dT; TC_570_0.dT = TC_570_0.port_a.T - TC_570_0.port_b.T; TC_570_0.port_a.Q_flow = TC_570_0.Q_flow; TC_570_0.port_b.Q_flow = -TC_570_0.Q_flow; TC_571_0.Q_flow = TC_571_0.G * TC_571_0.dT; TC_571_0.dT = TC_571_0.port_a.T - TC_571_0.port_b.T; TC_571_0.port_a.Q_flow = TC_571_0.Q_flow; TC_571_0.port_b.Q_flow = -TC_571_0.Q_flow; TC_572_0.Q_flow = TC_572_0.G * TC_572_0.dT; TC_572_0.dT = TC_572_0.port_a.T - TC_572_0.port_b.T; TC_572_0.port_a.Q_flow = TC_572_0.Q_flow; TC_572_0.port_b.Q_flow = -TC_572_0.Q_flow; TC_573_0.Q_flow = TC_573_0.G * TC_573_0.dT; TC_573_0.dT = TC_573_0.port_a.T - TC_573_0.port_b.T; TC_573_0.port_a.Q_flow = TC_573_0.Q_flow; TC_573_0.port_b.Q_flow = -TC_573_0.Q_flow; TC_574_0.Q_flow = TC_574_0.G * TC_574_0.dT; TC_574_0.dT = TC_574_0.port_a.T - TC_574_0.port_b.T; TC_574_0.port_a.Q_flow = TC_574_0.Q_flow; TC_574_0.port_b.Q_flow = -TC_574_0.Q_flow; TC_575_0.Q_flow = TC_575_0.G * TC_575_0.dT; TC_575_0.dT = TC_575_0.port_a.T - TC_575_0.port_b.T; TC_575_0.port_a.Q_flow = TC_575_0.Q_flow; TC_575_0.port_b.Q_flow = -TC_575_0.Q_flow; TC_576_0.Q_flow = TC_576_0.G * TC_576_0.dT; TC_576_0.dT = TC_576_0.port_a.T - TC_576_0.port_b.T; TC_576_0.port_a.Q_flow = TC_576_0.Q_flow; TC_576_0.port_b.Q_flow = -TC_576_0.Q_flow; TC_577_0.Q_flow = TC_577_0.G * TC_577_0.dT; TC_577_0.dT = TC_577_0.port_a.T - TC_577_0.port_b.T; TC_577_0.port_a.Q_flow = TC_577_0.Q_flow; TC_577_0.port_b.Q_flow = -TC_577_0.Q_flow; TC_578_0.Q_flow = TC_578_0.G * TC_578_0.dT; TC_578_0.dT = TC_578_0.port_a.T - TC_578_0.port_b.T; TC_578_0.port_a.Q_flow = TC_578_0.Q_flow; TC_578_0.port_b.Q_flow = -TC_578_0.Q_flow; TC_579_0.Q_flow = TC_579_0.G * TC_579_0.dT; TC_579_0.dT = TC_579_0.port_a.T - TC_579_0.port_b.T; TC_579_0.port_a.Q_flow = TC_579_0.Q_flow; TC_579_0.port_b.Q_flow = -TC_579_0.Q_flow; TC_580_0.Q_flow = TC_580_0.G * TC_580_0.dT; TC_580_0.dT = TC_580_0.port_a.T - TC_580_0.port_b.T; TC_580_0.port_a.Q_flow = TC_580_0.Q_flow; TC_580_0.port_b.Q_flow = -TC_580_0.Q_flow; TC_581_0.Q_flow = TC_581_0.G * TC_581_0.dT; TC_581_0.dT = TC_581_0.port_a.T - TC_581_0.port_b.T; TC_581_0.port_a.Q_flow = TC_581_0.Q_flow; TC_581_0.port_b.Q_flow = -TC_581_0.Q_flow; TC_582_0.Q_flow = TC_582_0.G * TC_582_0.dT; TC_582_0.dT = TC_582_0.port_a.T - TC_582_0.port_b.T; TC_582_0.port_a.Q_flow = TC_582_0.Q_flow; TC_582_0.port_b.Q_flow = -TC_582_0.Q_flow; TC_583_0.Q_flow = TC_583_0.G * TC_583_0.dT; TC_583_0.dT = TC_583_0.port_a.T - TC_583_0.port_b.T; TC_583_0.port_a.Q_flow = TC_583_0.Q_flow; TC_583_0.port_b.Q_flow = -TC_583_0.Q_flow; TC_584_0.Q_flow = TC_584_0.G * TC_584_0.dT; TC_584_0.dT = TC_584_0.port_a.T - TC_584_0.port_b.T; TC_584_0.port_a.Q_flow = TC_584_0.Q_flow; TC_584_0.port_b.Q_flow = -TC_584_0.Q_flow; TC_585_0.Q_flow = TC_585_0.G * TC_585_0.dT; TC_585_0.dT = TC_585_0.port_a.T - TC_585_0.port_b.T; TC_585_0.port_a.Q_flow = TC_585_0.Q_flow; TC_585_0.port_b.Q_flow = -TC_585_0.Q_flow; TC_586_0.Q_flow = TC_586_0.G * TC_586_0.dT; TC_586_0.dT = TC_586_0.port_a.T - TC_586_0.port_b.T; TC_586_0.port_a.Q_flow = TC_586_0.Q_flow; TC_586_0.port_b.Q_flow = -TC_586_0.Q_flow; TC_587_0.Q_flow = TC_587_0.G * TC_587_0.dT; TC_587_0.dT = TC_587_0.port_a.T - TC_587_0.port_b.T; TC_587_0.port_a.Q_flow = TC_587_0.Q_flow; TC_587_0.port_b.Q_flow = -TC_587_0.Q_flow; TC_588_0.Q_flow = TC_588_0.G * TC_588_0.dT; TC_588_0.dT = TC_588_0.port_a.T - TC_588_0.port_b.T; TC_588_0.port_a.Q_flow = TC_588_0.Q_flow; TC_588_0.port_b.Q_flow = -TC_588_0.Q_flow; TC_589_0.Q_flow = TC_589_0.G * TC_589_0.dT; TC_589_0.dT = TC_589_0.port_a.T - TC_589_0.port_b.T; TC_589_0.port_a.Q_flow = TC_589_0.Q_flow; TC_589_0.port_b.Q_flow = -TC_589_0.Q_flow; TC_590_0.Q_flow = TC_590_0.G * TC_590_0.dT; TC_590_0.dT = TC_590_0.port_a.T - TC_590_0.port_b.T; TC_590_0.port_a.Q_flow = TC_590_0.Q_flow; TC_590_0.port_b.Q_flow = -TC_590_0.Q_flow; TC_591_0.Q_flow = TC_591_0.G * TC_591_0.dT; TC_591_0.dT = TC_591_0.port_a.T - TC_591_0.port_b.T; TC_591_0.port_a.Q_flow = TC_591_0.Q_flow; TC_591_0.port_b.Q_flow = -TC_591_0.Q_flow; TC_592_0.Q_flow = TC_592_0.G * TC_592_0.dT; TC_592_0.dT = TC_592_0.port_a.T - TC_592_0.port_b.T; TC_592_0.port_a.Q_flow = TC_592_0.Q_flow; TC_592_0.port_b.Q_flow = -TC_592_0.Q_flow; TC_593_0.Q_flow = TC_593_0.G * TC_593_0.dT; TC_593_0.dT = TC_593_0.port_a.T - TC_593_0.port_b.T; TC_593_0.port_a.Q_flow = TC_593_0.Q_flow; TC_593_0.port_b.Q_flow = -TC_593_0.Q_flow; TC_594_0.Q_flow = TC_594_0.G * TC_594_0.dT; TC_594_0.dT = TC_594_0.port_a.T - TC_594_0.port_b.T; TC_594_0.port_a.Q_flow = TC_594_0.Q_flow; TC_594_0.port_b.Q_flow = -TC_594_0.Q_flow; TC_595_0.Q_flow = TC_595_0.G * TC_595_0.dT; TC_595_0.dT = TC_595_0.port_a.T - TC_595_0.port_b.T; TC_595_0.port_a.Q_flow = TC_595_0.Q_flow; TC_595_0.port_b.Q_flow = -TC_595_0.Q_flow; TC_596_0.Q_flow = TC_596_0.G * TC_596_0.dT; TC_596_0.dT = TC_596_0.port_a.T - TC_596_0.port_b.T; TC_596_0.port_a.Q_flow = TC_596_0.Q_flow; TC_596_0.port_b.Q_flow = -TC_596_0.Q_flow; TC_597_0.Q_flow = TC_597_0.G * TC_597_0.dT; TC_597_0.dT = TC_597_0.port_a.T - TC_597_0.port_b.T; TC_597_0.port_a.Q_flow = TC_597_0.Q_flow; TC_597_0.port_b.Q_flow = -TC_597_0.Q_flow; TC_598_0.Q_flow = TC_598_0.G * TC_598_0.dT; TC_598_0.dT = TC_598_0.port_a.T - TC_598_0.port_b.T; TC_598_0.port_a.Q_flow = TC_598_0.Q_flow; TC_598_0.port_b.Q_flow = -TC_598_0.Q_flow; TC_599_0.Q_flow = TC_599_0.G * TC_599_0.dT; TC_599_0.dT = TC_599_0.port_a.T - TC_599_0.port_b.T; TC_599_0.port_a.Q_flow = TC_599_0.Q_flow; TC_599_0.port_b.Q_flow = -TC_599_0.Q_flow; TC_600_0.Q_flow = TC_600_0.G * TC_600_0.dT; TC_600_0.dT = TC_600_0.port_a.T - TC_600_0.port_b.T; TC_600_0.port_a.Q_flow = TC_600_0.Q_flow; TC_600_0.port_b.Q_flow = -TC_600_0.Q_flow; TC_601_0.Q_flow = TC_601_0.G * TC_601_0.dT; TC_601_0.dT = TC_601_0.port_a.T - TC_601_0.port_b.T; TC_601_0.port_a.Q_flow = TC_601_0.Q_flow; TC_601_0.port_b.Q_flow = -TC_601_0.Q_flow; TC_602_0.Q_flow = TC_602_0.G * TC_602_0.dT; TC_602_0.dT = TC_602_0.port_a.T - TC_602_0.port_b.T; TC_602_0.port_a.Q_flow = TC_602_0.Q_flow; TC_602_0.port_b.Q_flow = -TC_602_0.Q_flow; TC_603_0.Q_flow = TC_603_0.G * TC_603_0.dT; TC_603_0.dT = TC_603_0.port_a.T - TC_603_0.port_b.T; TC_603_0.port_a.Q_flow = TC_603_0.Q_flow; TC_603_0.port_b.Q_flow = -TC_603_0.Q_flow; TC_604_0.Q_flow = TC_604_0.G * TC_604_0.dT; TC_604_0.dT = TC_604_0.port_a.T - TC_604_0.port_b.T; TC_604_0.port_a.Q_flow = TC_604_0.Q_flow; TC_604_0.port_b.Q_flow = -TC_604_0.Q_flow; TC_605_0.Q_flow = TC_605_0.G * TC_605_0.dT; TC_605_0.dT = TC_605_0.port_a.T - TC_605_0.port_b.T; TC_605_0.port_a.Q_flow = TC_605_0.Q_flow; TC_605_0.port_b.Q_flow = -TC_605_0.Q_flow; TC_606_0.Q_flow = TC_606_0.G * TC_606_0.dT; TC_606_0.dT = TC_606_0.port_a.T - TC_606_0.port_b.T; TC_606_0.port_a.Q_flow = TC_606_0.Q_flow; TC_606_0.port_b.Q_flow = -TC_606_0.Q_flow; TC_607_0.Q_flow = TC_607_0.G * TC_607_0.dT; TC_607_0.dT = TC_607_0.port_a.T - TC_607_0.port_b.T; TC_607_0.port_a.Q_flow = TC_607_0.Q_flow; TC_607_0.port_b.Q_flow = -TC_607_0.Q_flow; TC_608_0.Q_flow = TC_608_0.G * TC_608_0.dT; TC_608_0.dT = TC_608_0.port_a.T - TC_608_0.port_b.T; TC_608_0.port_a.Q_flow = TC_608_0.Q_flow; TC_608_0.port_b.Q_flow = -TC_608_0.Q_flow; TC_609_0.Q_flow = TC_609_0.G * TC_609_0.dT; TC_609_0.dT = TC_609_0.port_a.T - TC_609_0.port_b.T; TC_609_0.port_a.Q_flow = TC_609_0.Q_flow; TC_609_0.port_b.Q_flow = -TC_609_0.Q_flow; TC_610_0.Q_flow = TC_610_0.G * TC_610_0.dT; TC_610_0.dT = TC_610_0.port_a.T - TC_610_0.port_b.T; TC_610_0.port_a.Q_flow = TC_610_0.Q_flow; TC_610_0.port_b.Q_flow = -TC_610_0.Q_flow; TC_611_0.Q_flow = TC_611_0.G * TC_611_0.dT; TC_611_0.dT = TC_611_0.port_a.T - TC_611_0.port_b.T; TC_611_0.port_a.Q_flow = TC_611_0.Q_flow; TC_611_0.port_b.Q_flow = -TC_611_0.Q_flow; TC_612_0.Q_flow = TC_612_0.G * TC_612_0.dT; TC_612_0.dT = TC_612_0.port_a.T - TC_612_0.port_b.T; TC_612_0.port_a.Q_flow = TC_612_0.Q_flow; TC_612_0.port_b.Q_flow = -TC_612_0.Q_flow; TC_613_0.Q_flow = TC_613_0.G * TC_613_0.dT; TC_613_0.dT = TC_613_0.port_a.T - TC_613_0.port_b.T; TC_613_0.port_a.Q_flow = TC_613_0.Q_flow; TC_613_0.port_b.Q_flow = -TC_613_0.Q_flow; TC_614_0.Q_flow = TC_614_0.G * TC_614_0.dT; TC_614_0.dT = TC_614_0.port_a.T - TC_614_0.port_b.T; TC_614_0.port_a.Q_flow = TC_614_0.Q_flow; TC_614_0.port_b.Q_flow = -TC_614_0.Q_flow; TC_615_0.Q_flow = TC_615_0.G * TC_615_0.dT; TC_615_0.dT = TC_615_0.port_a.T - TC_615_0.port_b.T; TC_615_0.port_a.Q_flow = TC_615_0.Q_flow; TC_615_0.port_b.Q_flow = -TC_615_0.Q_flow; TC_616_0.Q_flow = TC_616_0.G * TC_616_0.dT; TC_616_0.dT = TC_616_0.port_a.T - TC_616_0.port_b.T; TC_616_0.port_a.Q_flow = TC_616_0.Q_flow; TC_616_0.port_b.Q_flow = -TC_616_0.Q_flow; TC_617_0.Q_flow = TC_617_0.G * TC_617_0.dT; TC_617_0.dT = TC_617_0.port_a.T - TC_617_0.port_b.T; TC_617_0.port_a.Q_flow = TC_617_0.Q_flow; TC_617_0.port_b.Q_flow = -TC_617_0.Q_flow; TC_618_0.Q_flow = TC_618_0.G * TC_618_0.dT; TC_618_0.dT = TC_618_0.port_a.T - TC_618_0.port_b.T; TC_618_0.port_a.Q_flow = TC_618_0.Q_flow; TC_618_0.port_b.Q_flow = -TC_618_0.Q_flow; TC_619_0.Q_flow = TC_619_0.G * TC_619_0.dT; TC_619_0.dT = TC_619_0.port_a.T - TC_619_0.port_b.T; TC_619_0.port_a.Q_flow = TC_619_0.Q_flow; TC_619_0.port_b.Q_flow = -TC_619_0.Q_flow; TC_620_0.Q_flow = TC_620_0.G * TC_620_0.dT; TC_620_0.dT = TC_620_0.port_a.T - TC_620_0.port_b.T; TC_620_0.port_a.Q_flow = TC_620_0.Q_flow; TC_620_0.port_b.Q_flow = -TC_620_0.Q_flow; TC_621_0.Q_flow = TC_621_0.G * TC_621_0.dT; TC_621_0.dT = TC_621_0.port_a.T - TC_621_0.port_b.T; TC_621_0.port_a.Q_flow = TC_621_0.Q_flow; TC_621_0.port_b.Q_flow = -TC_621_0.Q_flow; TC_622_0.Q_flow = TC_622_0.G * TC_622_0.dT; TC_622_0.dT = TC_622_0.port_a.T - TC_622_0.port_b.T; TC_622_0.port_a.Q_flow = TC_622_0.Q_flow; TC_622_0.port_b.Q_flow = -TC_622_0.Q_flow; TC_623_0.Q_flow = TC_623_0.G * TC_623_0.dT; TC_623_0.dT = TC_623_0.port_a.T - TC_623_0.port_b.T; TC_623_0.port_a.Q_flow = TC_623_0.Q_flow; TC_623_0.port_b.Q_flow = -TC_623_0.Q_flow; TC_624_0.Q_flow = TC_624_0.G * TC_624_0.dT; TC_624_0.dT = TC_624_0.port_a.T - TC_624_0.port_b.T; TC_624_0.port_a.Q_flow = TC_624_0.Q_flow; TC_624_0.port_b.Q_flow = -TC_624_0.Q_flow; TC_625_0.Q_flow = TC_625_0.G * TC_625_0.dT; TC_625_0.dT = TC_625_0.port_a.T - TC_625_0.port_b.T; TC_625_0.port_a.Q_flow = TC_625_0.Q_flow; TC_625_0.port_b.Q_flow = -TC_625_0.Q_flow; TC_626_0.Q_flow = TC_626_0.G * TC_626_0.dT; TC_626_0.dT = TC_626_0.port_a.T - TC_626_0.port_b.T; TC_626_0.port_a.Q_flow = TC_626_0.Q_flow; TC_626_0.port_b.Q_flow = -TC_626_0.Q_flow; TC_627_0.Q_flow = TC_627_0.G * TC_627_0.dT; TC_627_0.dT = TC_627_0.port_a.T - TC_627_0.port_b.T; TC_627_0.port_a.Q_flow = TC_627_0.Q_flow; TC_627_0.port_b.Q_flow = -TC_627_0.Q_flow; TC_628_0.Q_flow = TC_628_0.G * TC_628_0.dT; TC_628_0.dT = TC_628_0.port_a.T - TC_628_0.port_b.T; TC_628_0.port_a.Q_flow = TC_628_0.Q_flow; TC_628_0.port_b.Q_flow = -TC_628_0.Q_flow; TC_629_0.Q_flow = TC_629_0.G * TC_629_0.dT; TC_629_0.dT = TC_629_0.port_a.T - TC_629_0.port_b.T; TC_629_0.port_a.Q_flow = TC_629_0.Q_flow; TC_629_0.port_b.Q_flow = -TC_629_0.Q_flow; TC_630_0.Q_flow = TC_630_0.G * TC_630_0.dT; TC_630_0.dT = TC_630_0.port_a.T - TC_630_0.port_b.T; TC_630_0.port_a.Q_flow = TC_630_0.Q_flow; TC_630_0.port_b.Q_flow = -TC_630_0.Q_flow; TC_631_0.Q_flow = TC_631_0.G * TC_631_0.dT; TC_631_0.dT = TC_631_0.port_a.T - TC_631_0.port_b.T; TC_631_0.port_a.Q_flow = TC_631_0.Q_flow; TC_631_0.port_b.Q_flow = -TC_631_0.Q_flow; TC_632_0.Q_flow = TC_632_0.G * TC_632_0.dT; TC_632_0.dT = TC_632_0.port_a.T - TC_632_0.port_b.T; TC_632_0.port_a.Q_flow = TC_632_0.Q_flow; TC_632_0.port_b.Q_flow = -TC_632_0.Q_flow; TC_633_0.Q_flow = TC_633_0.G * TC_633_0.dT; TC_633_0.dT = TC_633_0.port_a.T - TC_633_0.port_b.T; TC_633_0.port_a.Q_flow = TC_633_0.Q_flow; TC_633_0.port_b.Q_flow = -TC_633_0.Q_flow; TC_634_0.Q_flow = TC_634_0.G * TC_634_0.dT; TC_634_0.dT = TC_634_0.port_a.T - TC_634_0.port_b.T; TC_634_0.port_a.Q_flow = TC_634_0.Q_flow; TC_634_0.port_b.Q_flow = -TC_634_0.Q_flow; TC_635_0.Q_flow = TC_635_0.G * TC_635_0.dT; TC_635_0.dT = TC_635_0.port_a.T - TC_635_0.port_b.T; TC_635_0.port_a.Q_flow = TC_635_0.Q_flow; TC_635_0.port_b.Q_flow = -TC_635_0.Q_flow; TC_636_0.Q_flow = TC_636_0.G * TC_636_0.dT; TC_636_0.dT = TC_636_0.port_a.T - TC_636_0.port_b.T; TC_636_0.port_a.Q_flow = TC_636_0.Q_flow; TC_636_0.port_b.Q_flow = -TC_636_0.Q_flow; TC_637_0.Q_flow = TC_637_0.G * TC_637_0.dT; TC_637_0.dT = TC_637_0.port_a.T - TC_637_0.port_b.T; TC_637_0.port_a.Q_flow = TC_637_0.Q_flow; TC_637_0.port_b.Q_flow = -TC_637_0.Q_flow; TC_638_0.Q_flow = TC_638_0.G * TC_638_0.dT; TC_638_0.dT = TC_638_0.port_a.T - TC_638_0.port_b.T; TC_638_0.port_a.Q_flow = TC_638_0.Q_flow; TC_638_0.port_b.Q_flow = -TC_638_0.Q_flow; TC_639_0.Q_flow = TC_639_0.G * TC_639_0.dT; TC_639_0.dT = TC_639_0.port_a.T - TC_639_0.port_b.T; TC_639_0.port_a.Q_flow = TC_639_0.Q_flow; TC_639_0.port_b.Q_flow = -TC_639_0.Q_flow; TC_640_0.Q_flow = TC_640_0.G * TC_640_0.dT; TC_640_0.dT = TC_640_0.port_a.T - TC_640_0.port_b.T; TC_640_0.port_a.Q_flow = TC_640_0.Q_flow; TC_640_0.port_b.Q_flow = -TC_640_0.Q_flow; TC_641_0.Q_flow = TC_641_0.G * TC_641_0.dT; TC_641_0.dT = TC_641_0.port_a.T - TC_641_0.port_b.T; TC_641_0.port_a.Q_flow = TC_641_0.Q_flow; TC_641_0.port_b.Q_flow = -TC_641_0.Q_flow; TC_642_0.Q_flow = TC_642_0.G * TC_642_0.dT; TC_642_0.dT = TC_642_0.port_a.T - TC_642_0.port_b.T; TC_642_0.port_a.Q_flow = TC_642_0.Q_flow; TC_642_0.port_b.Q_flow = -TC_642_0.Q_flow; TC_643_0.Q_flow = TC_643_0.G * TC_643_0.dT; TC_643_0.dT = TC_643_0.port_a.T - TC_643_0.port_b.T; TC_643_0.port_a.Q_flow = TC_643_0.Q_flow; TC_643_0.port_b.Q_flow = -TC_643_0.Q_flow; TC_644_0.Q_flow = TC_644_0.G * TC_644_0.dT; TC_644_0.dT = TC_644_0.port_a.T - TC_644_0.port_b.T; TC_644_0.port_a.Q_flow = TC_644_0.Q_flow; TC_644_0.port_b.Q_flow = -TC_644_0.Q_flow; TC_645_0.Q_flow = TC_645_0.G * TC_645_0.dT; TC_645_0.dT = TC_645_0.port_a.T - TC_645_0.port_b.T; TC_645_0.port_a.Q_flow = TC_645_0.Q_flow; TC_645_0.port_b.Q_flow = -TC_645_0.Q_flow; TC_646_0.Q_flow = TC_646_0.G * TC_646_0.dT; TC_646_0.dT = TC_646_0.port_a.T - TC_646_0.port_b.T; TC_646_0.port_a.Q_flow = TC_646_0.Q_flow; TC_646_0.port_b.Q_flow = -TC_646_0.Q_flow; TC_647_0.Q_flow = TC_647_0.G * TC_647_0.dT; TC_647_0.dT = TC_647_0.port_a.T - TC_647_0.port_b.T; TC_647_0.port_a.Q_flow = TC_647_0.Q_flow; TC_647_0.port_b.Q_flow = -TC_647_0.Q_flow; TC_648_0.Q_flow = TC_648_0.G * TC_648_0.dT; TC_648_0.dT = TC_648_0.port_a.T - TC_648_0.port_b.T; TC_648_0.port_a.Q_flow = TC_648_0.Q_flow; TC_648_0.port_b.Q_flow = -TC_648_0.Q_flow; TC_649_0.Q_flow = TC_649_0.G * TC_649_0.dT; TC_649_0.dT = TC_649_0.port_a.T - TC_649_0.port_b.T; TC_649_0.port_a.Q_flow = TC_649_0.Q_flow; TC_649_0.port_b.Q_flow = -TC_649_0.Q_flow; TC_650_0.Q_flow = TC_650_0.G * TC_650_0.dT; TC_650_0.dT = TC_650_0.port_a.T - TC_650_0.port_b.T; TC_650_0.port_a.Q_flow = TC_650_0.Q_flow; TC_650_0.port_b.Q_flow = -TC_650_0.Q_flow; TC_651_0.Q_flow = TC_651_0.G * TC_651_0.dT; TC_651_0.dT = TC_651_0.port_a.T - TC_651_0.port_b.T; TC_651_0.port_a.Q_flow = TC_651_0.Q_flow; TC_651_0.port_b.Q_flow = -TC_651_0.Q_flow; TC_652_0.Q_flow = TC_652_0.G * TC_652_0.dT; TC_652_0.dT = TC_652_0.port_a.T - TC_652_0.port_b.T; TC_652_0.port_a.Q_flow = TC_652_0.Q_flow; TC_652_0.port_b.Q_flow = -TC_652_0.Q_flow; TC_653_0.Q_flow = TC_653_0.G * TC_653_0.dT; TC_653_0.dT = TC_653_0.port_a.T - TC_653_0.port_b.T; TC_653_0.port_a.Q_flow = TC_653_0.Q_flow; TC_653_0.port_b.Q_flow = -TC_653_0.Q_flow; TC_654_0.Q_flow = TC_654_0.G * TC_654_0.dT; TC_654_0.dT = TC_654_0.port_a.T - TC_654_0.port_b.T; TC_654_0.port_a.Q_flow = TC_654_0.Q_flow; TC_654_0.port_b.Q_flow = -TC_654_0.Q_flow; TC_655_0.Q_flow = TC_655_0.G * TC_655_0.dT; TC_655_0.dT = TC_655_0.port_a.T - TC_655_0.port_b.T; TC_655_0.port_a.Q_flow = TC_655_0.Q_flow; TC_655_0.port_b.Q_flow = -TC_655_0.Q_flow; TC_656_0.Q_flow = TC_656_0.G * TC_656_0.dT; TC_656_0.dT = TC_656_0.port_a.T - TC_656_0.port_b.T; TC_656_0.port_a.Q_flow = TC_656_0.Q_flow; TC_656_0.port_b.Q_flow = -TC_656_0.Q_flow; TC_657_0.Q_flow = TC_657_0.G * TC_657_0.dT; TC_657_0.dT = TC_657_0.port_a.T - TC_657_0.port_b.T; TC_657_0.port_a.Q_flow = TC_657_0.Q_flow; TC_657_0.port_b.Q_flow = -TC_657_0.Q_flow; TC_658_0.Q_flow = TC_658_0.G * TC_658_0.dT; TC_658_0.dT = TC_658_0.port_a.T - TC_658_0.port_b.T; TC_658_0.port_a.Q_flow = TC_658_0.Q_flow; TC_658_0.port_b.Q_flow = -TC_658_0.Q_flow; TC_659_0.Q_flow = TC_659_0.G * TC_659_0.dT; TC_659_0.dT = TC_659_0.port_a.T - TC_659_0.port_b.T; TC_659_0.port_a.Q_flow = TC_659_0.Q_flow; TC_659_0.port_b.Q_flow = -TC_659_0.Q_flow; TC_660_0.Q_flow = TC_660_0.G * TC_660_0.dT; TC_660_0.dT = TC_660_0.port_a.T - TC_660_0.port_b.T; TC_660_0.port_a.Q_flow = TC_660_0.Q_flow; TC_660_0.port_b.Q_flow = -TC_660_0.Q_flow; TC_661_0.Q_flow = TC_661_0.G * TC_661_0.dT; TC_661_0.dT = TC_661_0.port_a.T - TC_661_0.port_b.T; TC_661_0.port_a.Q_flow = TC_661_0.Q_flow; TC_661_0.port_b.Q_flow = -TC_661_0.Q_flow; TC_662_0.Q_flow = TC_662_0.G * TC_662_0.dT; TC_662_0.dT = TC_662_0.port_a.T - TC_662_0.port_b.T; TC_662_0.port_a.Q_flow = TC_662_0.Q_flow; TC_662_0.port_b.Q_flow = -TC_662_0.Q_flow; TC_663_0.Q_flow = TC_663_0.G * TC_663_0.dT; TC_663_0.dT = TC_663_0.port_a.T - TC_663_0.port_b.T; TC_663_0.port_a.Q_flow = TC_663_0.Q_flow; TC_663_0.port_b.Q_flow = -TC_663_0.Q_flow; TC_664_0.Q_flow = TC_664_0.G * TC_664_0.dT; TC_664_0.dT = TC_664_0.port_a.T - TC_664_0.port_b.T; TC_664_0.port_a.Q_flow = TC_664_0.Q_flow; TC_664_0.port_b.Q_flow = -TC_664_0.Q_flow; TC_665_0.Q_flow = TC_665_0.G * TC_665_0.dT; TC_665_0.dT = TC_665_0.port_a.T - TC_665_0.port_b.T; TC_665_0.port_a.Q_flow = TC_665_0.Q_flow; TC_665_0.port_b.Q_flow = -TC_665_0.Q_flow; TC_666_0.Q_flow = TC_666_0.G * TC_666_0.dT; TC_666_0.dT = TC_666_0.port_a.T - TC_666_0.port_b.T; TC_666_0.port_a.Q_flow = TC_666_0.Q_flow; TC_666_0.port_b.Q_flow = -TC_666_0.Q_flow; TC_667_0.Q_flow = TC_667_0.G * TC_667_0.dT; TC_667_0.dT = TC_667_0.port_a.T - TC_667_0.port_b.T; TC_667_0.port_a.Q_flow = TC_667_0.Q_flow; TC_667_0.port_b.Q_flow = -TC_667_0.Q_flow; TC_668_0.Q_flow = TC_668_0.G * TC_668_0.dT; TC_668_0.dT = TC_668_0.port_a.T - TC_668_0.port_b.T; TC_668_0.port_a.Q_flow = TC_668_0.Q_flow; TC_668_0.port_b.Q_flow = -TC_668_0.Q_flow; TC_669_0.Q_flow = TC_669_0.G * TC_669_0.dT; TC_669_0.dT = TC_669_0.port_a.T - TC_669_0.port_b.T; TC_669_0.port_a.Q_flow = TC_669_0.Q_flow; TC_669_0.port_b.Q_flow = -TC_669_0.Q_flow; TC_670_0.Q_flow = TC_670_0.G * TC_670_0.dT; TC_670_0.dT = TC_670_0.port_a.T - TC_670_0.port_b.T; TC_670_0.port_a.Q_flow = TC_670_0.Q_flow; TC_670_0.port_b.Q_flow = -TC_670_0.Q_flow; TC_671_0.Q_flow = TC_671_0.G * TC_671_0.dT; TC_671_0.dT = TC_671_0.port_a.T - TC_671_0.port_b.T; TC_671_0.port_a.Q_flow = TC_671_0.Q_flow; TC_671_0.port_b.Q_flow = -TC_671_0.Q_flow; TC_672_0.Q_flow = TC_672_0.G * TC_672_0.dT; TC_672_0.dT = TC_672_0.port_a.T - TC_672_0.port_b.T; TC_672_0.port_a.Q_flow = TC_672_0.Q_flow; TC_672_0.port_b.Q_flow = -TC_672_0.Q_flow; TC_673_0.Q_flow = TC_673_0.G * TC_673_0.dT; TC_673_0.dT = TC_673_0.port_a.T - TC_673_0.port_b.T; TC_673_0.port_a.Q_flow = TC_673_0.Q_flow; TC_673_0.port_b.Q_flow = -TC_673_0.Q_flow; TC_674_0.Q_flow = TC_674_0.G * TC_674_0.dT; TC_674_0.dT = TC_674_0.port_a.T - TC_674_0.port_b.T; TC_674_0.port_a.Q_flow = TC_674_0.Q_flow; TC_674_0.port_b.Q_flow = -TC_674_0.Q_flow; TC_675_0.Q_flow = TC_675_0.G * TC_675_0.dT; TC_675_0.dT = TC_675_0.port_a.T - TC_675_0.port_b.T; TC_675_0.port_a.Q_flow = TC_675_0.Q_flow; TC_675_0.port_b.Q_flow = -TC_675_0.Q_flow; TC_676_0.Q_flow = TC_676_0.G * TC_676_0.dT; TC_676_0.dT = TC_676_0.port_a.T - TC_676_0.port_b.T; TC_676_0.port_a.Q_flow = TC_676_0.Q_flow; TC_676_0.port_b.Q_flow = -TC_676_0.Q_flow; TC_677_0.Q_flow = TC_677_0.G * TC_677_0.dT; TC_677_0.dT = TC_677_0.port_a.T - TC_677_0.port_b.T; TC_677_0.port_a.Q_flow = TC_677_0.Q_flow; TC_677_0.port_b.Q_flow = -TC_677_0.Q_flow; TC_678_0.Q_flow = TC_678_0.G * TC_678_0.dT; TC_678_0.dT = TC_678_0.port_a.T - TC_678_0.port_b.T; TC_678_0.port_a.Q_flow = TC_678_0.Q_flow; TC_678_0.port_b.Q_flow = -TC_678_0.Q_flow; TC_679_0.Q_flow = TC_679_0.G * TC_679_0.dT; TC_679_0.dT = TC_679_0.port_a.T - TC_679_0.port_b.T; TC_679_0.port_a.Q_flow = TC_679_0.Q_flow; TC_679_0.port_b.Q_flow = -TC_679_0.Q_flow; TC_680_0.Q_flow = TC_680_0.G * TC_680_0.dT; TC_680_0.dT = TC_680_0.port_a.T - TC_680_0.port_b.T; TC_680_0.port_a.Q_flow = TC_680_0.Q_flow; TC_680_0.port_b.Q_flow = -TC_680_0.Q_flow; TC_681_0.Q_flow = TC_681_0.G * TC_681_0.dT; TC_681_0.dT = TC_681_0.port_a.T - TC_681_0.port_b.T; TC_681_0.port_a.Q_flow = TC_681_0.Q_flow; TC_681_0.port_b.Q_flow = -TC_681_0.Q_flow; TC_682_0.Q_flow = TC_682_0.G * TC_682_0.dT; TC_682_0.dT = TC_682_0.port_a.T - TC_682_0.port_b.T; TC_682_0.port_a.Q_flow = TC_682_0.Q_flow; TC_682_0.port_b.Q_flow = -TC_682_0.Q_flow; TC_683_0.Q_flow = TC_683_0.G * TC_683_0.dT; TC_683_0.dT = TC_683_0.port_a.T - TC_683_0.port_b.T; TC_683_0.port_a.Q_flow = TC_683_0.Q_flow; TC_683_0.port_b.Q_flow = -TC_683_0.Q_flow; TC_684_0.Q_flow = TC_684_0.G * TC_684_0.dT; TC_684_0.dT = TC_684_0.port_a.T - TC_684_0.port_b.T; TC_684_0.port_a.Q_flow = TC_684_0.Q_flow; TC_684_0.port_b.Q_flow = -TC_684_0.Q_flow; TC_685_0.Q_flow = TC_685_0.G * TC_685_0.dT; TC_685_0.dT = TC_685_0.port_a.T - TC_685_0.port_b.T; TC_685_0.port_a.Q_flow = TC_685_0.Q_flow; TC_685_0.port_b.Q_flow = -TC_685_0.Q_flow; TC_686_0.Q_flow = TC_686_0.G * TC_686_0.dT; TC_686_0.dT = TC_686_0.port_a.T - TC_686_0.port_b.T; TC_686_0.port_a.Q_flow = TC_686_0.Q_flow; TC_686_0.port_b.Q_flow = -TC_686_0.Q_flow; TC_687_0.Q_flow = TC_687_0.G * TC_687_0.dT; TC_687_0.dT = TC_687_0.port_a.T - TC_687_0.port_b.T; TC_687_0.port_a.Q_flow = TC_687_0.Q_flow; TC_687_0.port_b.Q_flow = -TC_687_0.Q_flow; TC_688_0.Q_flow = TC_688_0.G * TC_688_0.dT; TC_688_0.dT = TC_688_0.port_a.T - TC_688_0.port_b.T; TC_688_0.port_a.Q_flow = TC_688_0.Q_flow; TC_688_0.port_b.Q_flow = -TC_688_0.Q_flow; TC_689_0.Q_flow = TC_689_0.G * TC_689_0.dT; TC_689_0.dT = TC_689_0.port_a.T - TC_689_0.port_b.T; TC_689_0.port_a.Q_flow = TC_689_0.Q_flow; TC_689_0.port_b.Q_flow = -TC_689_0.Q_flow; TC_690_0.Q_flow = TC_690_0.G * TC_690_0.dT; TC_690_0.dT = TC_690_0.port_a.T - TC_690_0.port_b.T; TC_690_0.port_a.Q_flow = TC_690_0.Q_flow; TC_690_0.port_b.Q_flow = -TC_690_0.Q_flow; TC_691_0.Q_flow = TC_691_0.G * TC_691_0.dT; TC_691_0.dT = TC_691_0.port_a.T - TC_691_0.port_b.T; TC_691_0.port_a.Q_flow = TC_691_0.Q_flow; TC_691_0.port_b.Q_flow = -TC_691_0.Q_flow; TC_692_0.Q_flow = TC_692_0.G * TC_692_0.dT; TC_692_0.dT = TC_692_0.port_a.T - TC_692_0.port_b.T; TC_692_0.port_a.Q_flow = TC_692_0.Q_flow; TC_692_0.port_b.Q_flow = -TC_692_0.Q_flow; TC_693_0.Q_flow = TC_693_0.G * TC_693_0.dT; TC_693_0.dT = TC_693_0.port_a.T - TC_693_0.port_b.T; TC_693_0.port_a.Q_flow = TC_693_0.Q_flow; TC_693_0.port_b.Q_flow = -TC_693_0.Q_flow; TC_694_0.Q_flow = TC_694_0.G * TC_694_0.dT; TC_694_0.dT = TC_694_0.port_a.T - TC_694_0.port_b.T; TC_694_0.port_a.Q_flow = TC_694_0.Q_flow; TC_694_0.port_b.Q_flow = -TC_694_0.Q_flow; TC_695_0.Q_flow = TC_695_0.G * TC_695_0.dT; TC_695_0.dT = TC_695_0.port_a.T - TC_695_0.port_b.T; TC_695_0.port_a.Q_flow = TC_695_0.Q_flow; TC_695_0.port_b.Q_flow = -TC_695_0.Q_flow; TC_696_0.Q_flow = TC_696_0.G * TC_696_0.dT; TC_696_0.dT = TC_696_0.port_a.T - TC_696_0.port_b.T; TC_696_0.port_a.Q_flow = TC_696_0.Q_flow; TC_696_0.port_b.Q_flow = -TC_696_0.Q_flow; TC_697_0.Q_flow = TC_697_0.G * TC_697_0.dT; TC_697_0.dT = TC_697_0.port_a.T - TC_697_0.port_b.T; TC_697_0.port_a.Q_flow = TC_697_0.Q_flow; TC_697_0.port_b.Q_flow = -TC_697_0.Q_flow; TC_698_0.Q_flow = TC_698_0.G * TC_698_0.dT; TC_698_0.dT = TC_698_0.port_a.T - TC_698_0.port_b.T; TC_698_0.port_a.Q_flow = TC_698_0.Q_flow; TC_698_0.port_b.Q_flow = -TC_698_0.Q_flow; TC_699_0.Q_flow = TC_699_0.G * TC_699_0.dT; TC_699_0.dT = TC_699_0.port_a.T - TC_699_0.port_b.T; TC_699_0.port_a.Q_flow = TC_699_0.Q_flow; TC_699_0.port_b.Q_flow = -TC_699_0.Q_flow; TC_700_0.Q_flow = TC_700_0.G * TC_700_0.dT; TC_700_0.dT = TC_700_0.port_a.T - TC_700_0.port_b.T; TC_700_0.port_a.Q_flow = TC_700_0.Q_flow; TC_700_0.port_b.Q_flow = -TC_700_0.Q_flow; TC_701_0.Q_flow = TC_701_0.G * TC_701_0.dT; TC_701_0.dT = TC_701_0.port_a.T - TC_701_0.port_b.T; TC_701_0.port_a.Q_flow = TC_701_0.Q_flow; TC_701_0.port_b.Q_flow = -TC_701_0.Q_flow; TC_702_0.Q_flow = TC_702_0.G * TC_702_0.dT; TC_702_0.dT = TC_702_0.port_a.T - TC_702_0.port_b.T; TC_702_0.port_a.Q_flow = TC_702_0.Q_flow; TC_702_0.port_b.Q_flow = -TC_702_0.Q_flow; TC_703_0.Q_flow = TC_703_0.G * TC_703_0.dT; TC_703_0.dT = TC_703_0.port_a.T - TC_703_0.port_b.T; TC_703_0.port_a.Q_flow = TC_703_0.Q_flow; TC_703_0.port_b.Q_flow = -TC_703_0.Q_flow; TC_704_0.Q_flow = TC_704_0.G * TC_704_0.dT; TC_704_0.dT = TC_704_0.port_a.T - TC_704_0.port_b.T; TC_704_0.port_a.Q_flow = TC_704_0.Q_flow; TC_704_0.port_b.Q_flow = -TC_704_0.Q_flow; TC_705_0.Q_flow = TC_705_0.G * TC_705_0.dT; TC_705_0.dT = TC_705_0.port_a.T - TC_705_0.port_b.T; TC_705_0.port_a.Q_flow = TC_705_0.Q_flow; TC_705_0.port_b.Q_flow = -TC_705_0.Q_flow; TC_706_0.Q_flow = TC_706_0.G * TC_706_0.dT; TC_706_0.dT = TC_706_0.port_a.T - TC_706_0.port_b.T; TC_706_0.port_a.Q_flow = TC_706_0.Q_flow; TC_706_0.port_b.Q_flow = -TC_706_0.Q_flow; TC_707_0.Q_flow = TC_707_0.G * TC_707_0.dT; TC_707_0.dT = TC_707_0.port_a.T - TC_707_0.port_b.T; TC_707_0.port_a.Q_flow = TC_707_0.Q_flow; TC_707_0.port_b.Q_flow = -TC_707_0.Q_flow; TC_708_0.Q_flow = TC_708_0.G * TC_708_0.dT; TC_708_0.dT = TC_708_0.port_a.T - TC_708_0.port_b.T; TC_708_0.port_a.Q_flow = TC_708_0.Q_flow; TC_708_0.port_b.Q_flow = -TC_708_0.Q_flow; TC_709_0.Q_flow = TC_709_0.G * TC_709_0.dT; TC_709_0.dT = TC_709_0.port_a.T - TC_709_0.port_b.T; TC_709_0.port_a.Q_flow = TC_709_0.Q_flow; TC_709_0.port_b.Q_flow = -TC_709_0.Q_flow; TC_710_0.Q_flow = TC_710_0.G * TC_710_0.dT; TC_710_0.dT = TC_710_0.port_a.T - TC_710_0.port_b.T; TC_710_0.port_a.Q_flow = TC_710_0.Q_flow; TC_710_0.port_b.Q_flow = -TC_710_0.Q_flow; TC_711_0.Q_flow = TC_711_0.G * TC_711_0.dT; TC_711_0.dT = TC_711_0.port_a.T - TC_711_0.port_b.T; TC_711_0.port_a.Q_flow = TC_711_0.Q_flow; TC_711_0.port_b.Q_flow = -TC_711_0.Q_flow; TC_712_0.Q_flow = TC_712_0.G * TC_712_0.dT; TC_712_0.dT = TC_712_0.port_a.T - TC_712_0.port_b.T; TC_712_0.port_a.Q_flow = TC_712_0.Q_flow; TC_712_0.port_b.Q_flow = -TC_712_0.Q_flow; TC_713_0.Q_flow = TC_713_0.G * TC_713_0.dT; TC_713_0.dT = TC_713_0.port_a.T - TC_713_0.port_b.T; TC_713_0.port_a.Q_flow = TC_713_0.Q_flow; TC_713_0.port_b.Q_flow = -TC_713_0.Q_flow; TC_714_0.Q_flow = TC_714_0.G * TC_714_0.dT; TC_714_0.dT = TC_714_0.port_a.T - TC_714_0.port_b.T; TC_714_0.port_a.Q_flow = TC_714_0.Q_flow; TC_714_0.port_b.Q_flow = -TC_714_0.Q_flow; TC_715_0.Q_flow = TC_715_0.G * TC_715_0.dT; TC_715_0.dT = TC_715_0.port_a.T - TC_715_0.port_b.T; TC_715_0.port_a.Q_flow = TC_715_0.Q_flow; TC_715_0.port_b.Q_flow = -TC_715_0.Q_flow; TC_716_0.Q_flow = TC_716_0.G * TC_716_0.dT; TC_716_0.dT = TC_716_0.port_a.T - TC_716_0.port_b.T; TC_716_0.port_a.Q_flow = TC_716_0.Q_flow; TC_716_0.port_b.Q_flow = -TC_716_0.Q_flow; TC_717_0.Q_flow = TC_717_0.G * TC_717_0.dT; TC_717_0.dT = TC_717_0.port_a.T - TC_717_0.port_b.T; TC_717_0.port_a.Q_flow = TC_717_0.Q_flow; TC_717_0.port_b.Q_flow = -TC_717_0.Q_flow; TC_718_0.Q_flow = TC_718_0.G * TC_718_0.dT; TC_718_0.dT = TC_718_0.port_a.T - TC_718_0.port_b.T; TC_718_0.port_a.Q_flow = TC_718_0.Q_flow; TC_718_0.port_b.Q_flow = -TC_718_0.Q_flow; TC_719_0.Q_flow = TC_719_0.G * TC_719_0.dT; TC_719_0.dT = TC_719_0.port_a.T - TC_719_0.port_b.T; TC_719_0.port_a.Q_flow = TC_719_0.Q_flow; TC_719_0.port_b.Q_flow = -TC_719_0.Q_flow; TC_720_0.Q_flow = TC_720_0.G * TC_720_0.dT; TC_720_0.dT = TC_720_0.port_a.T - TC_720_0.port_b.T; TC_720_0.port_a.Q_flow = TC_720_0.Q_flow; TC_720_0.port_b.Q_flow = -TC_720_0.Q_flow; TC_721_0.Q_flow = TC_721_0.G * TC_721_0.dT; TC_721_0.dT = TC_721_0.port_a.T - TC_721_0.port_b.T; TC_721_0.port_a.Q_flow = TC_721_0.Q_flow; TC_721_0.port_b.Q_flow = -TC_721_0.Q_flow; TC_722_0.Q_flow = TC_722_0.G * TC_722_0.dT; TC_722_0.dT = TC_722_0.port_a.T - TC_722_0.port_b.T; TC_722_0.port_a.Q_flow = TC_722_0.Q_flow; TC_722_0.port_b.Q_flow = -TC_722_0.Q_flow; TC_723_0.Q_flow = TC_723_0.G * TC_723_0.dT; TC_723_0.dT = TC_723_0.port_a.T - TC_723_0.port_b.T; TC_723_0.port_a.Q_flow = TC_723_0.Q_flow; TC_723_0.port_b.Q_flow = -TC_723_0.Q_flow; TC_724_0.Q_flow = TC_724_0.G * TC_724_0.dT; TC_724_0.dT = TC_724_0.port_a.T - TC_724_0.port_b.T; TC_724_0.port_a.Q_flow = TC_724_0.Q_flow; TC_724_0.port_b.Q_flow = -TC_724_0.Q_flow; TC_725_0.Q_flow = TC_725_0.G * TC_725_0.dT; TC_725_0.dT = TC_725_0.port_a.T - TC_725_0.port_b.T; TC_725_0.port_a.Q_flow = TC_725_0.Q_flow; TC_725_0.port_b.Q_flow = -TC_725_0.Q_flow; TC_726_0.Q_flow = TC_726_0.G * TC_726_0.dT; TC_726_0.dT = TC_726_0.port_a.T - TC_726_0.port_b.T; TC_726_0.port_a.Q_flow = TC_726_0.Q_flow; TC_726_0.port_b.Q_flow = -TC_726_0.Q_flow; TC_727_0.Q_flow = TC_727_0.G * TC_727_0.dT; TC_727_0.dT = TC_727_0.port_a.T - TC_727_0.port_b.T; TC_727_0.port_a.Q_flow = TC_727_0.Q_flow; TC_727_0.port_b.Q_flow = -TC_727_0.Q_flow; TC_728_0.Q_flow = TC_728_0.G * TC_728_0.dT; TC_728_0.dT = TC_728_0.port_a.T - TC_728_0.port_b.T; TC_728_0.port_a.Q_flow = TC_728_0.Q_flow; TC_728_0.port_b.Q_flow = -TC_728_0.Q_flow; TC_729_0.Q_flow = TC_729_0.G * TC_729_0.dT; TC_729_0.dT = TC_729_0.port_a.T - TC_729_0.port_b.T; TC_729_0.port_a.Q_flow = TC_729_0.Q_flow; TC_729_0.port_b.Q_flow = -TC_729_0.Q_flow; TC_730_0.Q_flow = TC_730_0.G * TC_730_0.dT; TC_730_0.dT = TC_730_0.port_a.T - TC_730_0.port_b.T; TC_730_0.port_a.Q_flow = TC_730_0.Q_flow; TC_730_0.port_b.Q_flow = -TC_730_0.Q_flow; TC_731_0.Q_flow = TC_731_0.G * TC_731_0.dT; TC_731_0.dT = TC_731_0.port_a.T - TC_731_0.port_b.T; TC_731_0.port_a.Q_flow = TC_731_0.Q_flow; TC_731_0.port_b.Q_flow = -TC_731_0.Q_flow; TC_732_0.Q_flow = TC_732_0.G * TC_732_0.dT; TC_732_0.dT = TC_732_0.port_a.T - TC_732_0.port_b.T; TC_732_0.port_a.Q_flow = TC_732_0.Q_flow; TC_732_0.port_b.Q_flow = -TC_732_0.Q_flow; TC_733_0.Q_flow = TC_733_0.G * TC_733_0.dT; TC_733_0.dT = TC_733_0.port_a.T - TC_733_0.port_b.T; TC_733_0.port_a.Q_flow = TC_733_0.Q_flow; TC_733_0.port_b.Q_flow = -TC_733_0.Q_flow; TC_734_0.Q_flow = TC_734_0.G * TC_734_0.dT; TC_734_0.dT = TC_734_0.port_a.T - TC_734_0.port_b.T; TC_734_0.port_a.Q_flow = TC_734_0.Q_flow; TC_734_0.port_b.Q_flow = -TC_734_0.Q_flow; TC_735_0.Q_flow = TC_735_0.G * TC_735_0.dT; TC_735_0.dT = TC_735_0.port_a.T - TC_735_0.port_b.T; TC_735_0.port_a.Q_flow = TC_735_0.Q_flow; TC_735_0.port_b.Q_flow = -TC_735_0.Q_flow; TC_736_0.Q_flow = TC_736_0.G * TC_736_0.dT; TC_736_0.dT = TC_736_0.port_a.T - TC_736_0.port_b.T; TC_736_0.port_a.Q_flow = TC_736_0.Q_flow; TC_736_0.port_b.Q_flow = -TC_736_0.Q_flow; TC_737_0.Q_flow = TC_737_0.G * TC_737_0.dT; TC_737_0.dT = TC_737_0.port_a.T - TC_737_0.port_b.T; TC_737_0.port_a.Q_flow = TC_737_0.Q_flow; TC_737_0.port_b.Q_flow = -TC_737_0.Q_flow; TC_738_0.Q_flow = TC_738_0.G * TC_738_0.dT; TC_738_0.dT = TC_738_0.port_a.T - TC_738_0.port_b.T; TC_738_0.port_a.Q_flow = TC_738_0.Q_flow; TC_738_0.port_b.Q_flow = -TC_738_0.Q_flow; TC_739_0.Q_flow = TC_739_0.G * TC_739_0.dT; TC_739_0.dT = TC_739_0.port_a.T - TC_739_0.port_b.T; TC_739_0.port_a.Q_flow = TC_739_0.Q_flow; TC_739_0.port_b.Q_flow = -TC_739_0.Q_flow; TC_740_0.Q_flow = TC_740_0.G * TC_740_0.dT; TC_740_0.dT = TC_740_0.port_a.T - TC_740_0.port_b.T; TC_740_0.port_a.Q_flow = TC_740_0.Q_flow; TC_740_0.port_b.Q_flow = -TC_740_0.Q_flow; HFIC101.port.Q_flow = (-HFIC101.Q_flow) * (1.0 + HFIC101.alpha * (HFIC101.port.T - HFIC101.T_ref)); HFIC102.port.Q_flow = (-HFIC102.Q_flow) * (1.0 + HFIC102.alpha * (HFIC102.port.T - HFIC102.T_ref)); HFIC103.port.Q_flow = (-HFIC103.Q_flow) * (1.0 + HFIC103.alpha * (HFIC103.port.T - HFIC103.T_ref)); HFIC104.port.Q_flow = (-HFIC104.Q_flow) * (1.0 + HFIC104.alpha * (HFIC104.port.T - HFIC104.T_ref)); HFIC105.port.Q_flow = (-HFIC105.Q_flow) * (1.0 + HFIC105.alpha * (HFIC105.port.T - HFIC105.T_ref)); HFIC106.port.Q_flow = (-HFIC106.Q_flow) * (1.0 + HFIC106.alpha * (HFIC106.port.T - HFIC106.T_ref)); HFIC107.port.Q_flow = (-HFIC107.Q_flow) * (1.0 + HFIC107.alpha * (HFIC107.port.T - HFIC107.T_ref)); HFIC108.port.Q_flow = (-HFIC108.Q_flow) * (1.0 + HFIC108.alpha * (HFIC108.port.T - HFIC108.T_ref)); HFIC109.port.Q_flow = (-HFIC109.Q_flow) * (1.0 + HFIC109.alpha * (HFIC109.port.T - HFIC109.T_ref)); HFIC201.port.Q_flow = (-HFIC201.Q_flow) * (1.0 + HFIC201.alpha * (HFIC201.port.T - HFIC201.T_ref)); HFIC202.port.Q_flow = (-HFIC202.Q_flow) * (1.0 + HFIC202.alpha * (HFIC202.port.T - HFIC202.T_ref)); HFIC203.port.Q_flow = (-HFIC203.Q_flow) * (1.0 + HFIC203.alpha * (HFIC203.port.T - HFIC203.T_ref)); HFIC204.port.Q_flow = (-HFIC204.Q_flow) * (1.0 + HFIC204.alpha * (HFIC204.port.T - HFIC204.T_ref)); HFIC205.port.Q_flow = (-HFIC205.Q_flow) * (1.0 + HFIC205.alpha * (HFIC205.port.T - HFIC205.T_ref)); HFIC206.port.Q_flow = (-HFIC206.Q_flow) * (1.0 + HFIC206.alpha * (HFIC206.port.T - HFIC206.T_ref)); HFIC207.port.Q_flow = (-HFIC207.Q_flow) * (1.0 + HFIC207.alpha * (HFIC207.port.T - HFIC207.T_ref)); HFIC208.port.Q_flow = (-HFIC208.Q_flow) * (1.0 + HFIC208.alpha * (HFIC208.port.T - HFIC208.T_ref)); HFIC209.port.Q_flow = (-HFIC209.Q_flow) * (1.0 + HFIC209.alpha * (HFIC209.port.T - HFIC209.T_ref)); HFIC301.port.Q_flow = (-HFIC301.Q_flow) * (1.0 + HFIC301.alpha * (HFIC301.port.T - HFIC301.T_ref)); HFIC302.port.Q_flow = (-HFIC302.Q_flow) * (1.0 + HFIC302.alpha * (HFIC302.port.T - HFIC302.T_ref)); HFIC303.port.Q_flow = (-HFIC303.Q_flow) * (1.0 + HFIC303.alpha * (HFIC303.port.T - HFIC303.T_ref)); HFIC304.port.Q_flow = (-HFIC304.Q_flow) * (1.0 + HFIC304.alpha * (HFIC304.port.T - HFIC304.T_ref)); HFIC305.port.Q_flow = (-HFIC305.Q_flow) * (1.0 + HFIC305.alpha * (HFIC305.port.T - HFIC305.T_ref)); HFIC306.port.Q_flow = (-HFIC306.Q_flow) * (1.0 + HFIC306.alpha * (HFIC306.port.T - HFIC306.T_ref)); HFIC307.port.Q_flow = (-HFIC307.Q_flow) * (1.0 + HFIC307.alpha * (HFIC307.port.T - HFIC307.T_ref)); HFIC308.port.Q_flow = (-HFIC308.Q_flow) * (1.0 + HFIC308.alpha * (HFIC308.port.T - HFIC308.T_ref)); HFIC309.port.Q_flow = (-HFIC309.Q_flow) * (1.0 + HFIC309.alpha * (HFIC309.port.T - HFIC309.T_ref)); HFIC310.port.Q_flow = (-HFIC310.Q_flow) * (1.0 + HFIC310.alpha * (HFIC310.port.T - HFIC310.T_ref)); HFIC311.port.Q_flow = (-HFIC311.Q_flow) * (1.0 + HFIC311.alpha * (HFIC311.port.T - HFIC311.T_ref)); HFIC312.port.Q_flow = (-HFIC312.Q_flow) * (1.0 + HFIC312.alpha * (HFIC312.port.T - HFIC312.T_ref)); HFIC401.port.Q_flow = (-HFIC401.Q_flow) * (1.0 + HFIC401.alpha * (HFIC401.port.T - HFIC401.T_ref)); HFIC402.port.Q_flow = (-HFIC402.Q_flow) * (1.0 + HFIC402.alpha * (HFIC402.port.T - HFIC402.T_ref)); HFIC403.port.Q_flow = (-HFIC403.Q_flow) * (1.0 + HFIC403.alpha * (HFIC403.port.T - HFIC403.T_ref)); HFIC404.port.Q_flow = (-HFIC404.Q_flow) * (1.0 + HFIC404.alpha * (HFIC404.port.T - HFIC404.T_ref)); HFIC405.port.Q_flow = (-HFIC405.Q_flow) * (1.0 + HFIC405.alpha * (HFIC405.port.T - HFIC405.T_ref)); HFIC406.port.Q_flow = (-HFIC406.Q_flow) * (1.0 + HFIC406.alpha * (HFIC406.port.T - HFIC406.T_ref)); HFIC407.port.Q_flow = (-HFIC407.Q_flow) * (1.0 + HFIC407.alpha * (HFIC407.port.T - HFIC407.T_ref)); HFIC408.port.Q_flow = (-HFIC408.Q_flow) * (1.0 + HFIC408.alpha * (HFIC408.port.T - HFIC408.T_ref)); HFIC409.port.Q_flow = (-HFIC409.Q_flow) * (1.0 + HFIC409.alpha * (HFIC409.port.T - HFIC409.T_ref)); HFIC501.port.Q_flow = (-HFIC501.Q_flow) * (1.0 + HFIC501.alpha * (HFIC501.port.T - HFIC501.T_ref)); HFIC502.port.Q_flow = (-HFIC502.Q_flow) * (1.0 + HFIC502.alpha * (HFIC502.port.T - HFIC502.T_ref)); HFIC503.port.Q_flow = (-HFIC503.Q_flow) * (1.0 + HFIC503.alpha * (HFIC503.port.T - HFIC503.T_ref)); HFIC504.port.Q_flow = (-HFIC504.Q_flow) * (1.0 + HFIC504.alpha * (HFIC504.port.T - HFIC504.T_ref)); HFIC505.port.Q_flow = (-HFIC505.Q_flow) * (1.0 + HFIC505.alpha * (HFIC505.port.T - HFIC505.T_ref)); HFIC506.port.Q_flow = (-HFIC506.Q_flow) * (1.0 + HFIC506.alpha * (HFIC506.port.T - HFIC506.T_ref)); HFIC507.port.Q_flow = (-HFIC507.Q_flow) * (1.0 + HFIC507.alpha * (HFIC507.port.T - HFIC507.T_ref)); HFIC508.port.Q_flow = (-HFIC508.Q_flow) * (1.0 + HFIC508.alpha * (HFIC508.port.T - HFIC508.T_ref)); HFIC509.port.Q_flow = (-HFIC509.Q_flow) * (1.0 + HFIC509.alpha * (HFIC509.port.T - HFIC509.T_ref)); HFIC510.port.Q_flow = (-HFIC510.Q_flow) * (1.0 + HFIC510.alpha * (HFIC510.port.T - HFIC510.T_ref)); HFIC511.port.Q_flow = (-HFIC511.Q_flow) * (1.0 + HFIC511.alpha * (HFIC511.port.T - HFIC511.T_ref)); HFIC512.port.Q_flow = (-HFIC512.Q_flow) * (1.0 + HFIC512.alpha * (HFIC512.port.T - HFIC512.T_ref)); HFIC601.port.Q_flow = (-HFIC601.Q_flow) * (1.0 + HFIC601.alpha * (HFIC601.port.T - HFIC601.T_ref)); HFIC602.port.Q_flow = (-HFIC602.Q_flow) * (1.0 + HFIC602.alpha * (HFIC602.port.T - HFIC602.T_ref)); HFIC603.port.Q_flow = (-HFIC603.Q_flow) * (1.0 + HFIC603.alpha * (HFIC603.port.T - HFIC603.T_ref)); HFIC604.port.Q_flow = (-HFIC604.Q_flow) * (1.0 + HFIC604.alpha * (HFIC604.port.T - HFIC604.T_ref)); HFIC605.port.Q_flow = (-HFIC605.Q_flow) * (1.0 + HFIC605.alpha * (HFIC605.port.T - HFIC605.T_ref)); HFIC606.port.Q_flow = (-HFIC606.Q_flow) * (1.0 + HFIC606.alpha * (HFIC606.port.T - HFIC606.T_ref)); HFIC607.port.Q_flow = (-HFIC607.Q_flow) * (1.0 + HFIC607.alpha * (HFIC607.port.T - HFIC607.T_ref)); HFIC608.port.Q_flow = (-HFIC608.Q_flow) * (1.0 + HFIC608.alpha * (HFIC608.port.T - HFIC608.T_ref)); HFIC609.port.Q_flow = (-HFIC609.Q_flow) * (1.0 + HFIC609.alpha * (HFIC609.port.T - HFIC609.T_ref)); FixedTemp001.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp001.T); FixedTemp002.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp002.T); FixedTemp003.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp003.T); FixedTemp004.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp004.T); FixedTemp005.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp005.T); FixedTemp006.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp006.T); FixedTemp007.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp007.T); FixedTemp008.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp008.T); FixedTemp009.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp009.T); FixedTemp010.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp010.T); FixedTemp011.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp011.T); FixedTemp012.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp012.T); FixedTemp013.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp013.T); FixedTemp014.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp014.T); FixedTemp015.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp015.T); FixedTemp016.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp016.T); FixedTemp017.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp017.T); FixedTemp018.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp018.T); FixedTemp019.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp019.T); FixedTemp020.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp020.T); FixedTemp021.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp021.T); FixedTemp022.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp022.T); FixedTemp023.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp023.T); FixedTemp024.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp024.T); FixedTemp025.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp025.T); FixedTemp026.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp026.T); FixedTemp027.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp027.T); FixedTemp028.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp028.T); FixedTemp029.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp029.T); FixedTemp030.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp030.T); FixedTemp031.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp031.T); FixedTemp032.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp032.T); FixedTemp033.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp033.T); FixedTemp034.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp034.T); FixedTemp035.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp035.T); FixedTemp036.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp036.T); FixedTemp037.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp037.T); FixedTemp038.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp038.T); FixedTemp039.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp039.T); FixedTemp040.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp040.T); FixedTemp041.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp041.T); FixedTemp042.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp042.T); FixedTemp043.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp043.T); FixedTemp044.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp044.T); FixedTemp045.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp045.T); FixedTemp046.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp046.T); FixedTemp047.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp047.T); FixedTemp048.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp048.T); FixedTemp049.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp049.T); FixedTemp050.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp050.T); FixedTemp051.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp051.T); FixedTemp052.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp052.T); FixedTemp053.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp053.T); FixedTemp054.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp054.T); FixedTemp055.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp055.T); FixedTemp056.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp056.T); FixedTemp057.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp057.T); FixedTemp058.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp058.T); FixedTemp059.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp059.T); FixedTemp060.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp060.T); FixedTemp061.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp061.T); FixedTemp062.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp062.T); FixedTemp063.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp063.T); FixedTemp064.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp064.T); FixedTemp065.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp065.T); FixedTemp066.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp066.T); FixedTemp067.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp067.T); FixedTemp068.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp068.T); FixedTemp069.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp069.T); FixedTemp070.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp070.T); FixedTemp071.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp071.T); FixedTemp072.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp072.T); FixedTemp073.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp073.T); FixedTemp074.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp074.T); FixedTemp075.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp075.T); FixedTemp076.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp076.T); FixedTemp077.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp077.T); FixedTemp078.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp078.T); FixedTemp079.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp079.T); FixedTemp080.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp080.T); FixedTemp081.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp081.T); FixedTemp082.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp082.T); FixedTemp083.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp083.T); FixedTemp084.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp084.T); FixedTemp085.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp085.T); FixedTemp086.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp086.T); FixedTemp087.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp087.T); FixedTemp088.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp088.T); FixedTemp089.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp089.T); FixedTemp090.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp090.T); FixedTemp091.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp091.T); FixedTemp092.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp092.T); FixedTemp093.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp093.T); FixedTemp094.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp094.T); FixedTemp095.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp095.T); FixedTemp096.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp096.T); FixedTemp097.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp097.T); FixedTemp098.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp098.T); FixedTemp099.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp099.T); FixedTemp100.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp100.T); FixedTemp101.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp101.T); FixedTemp102.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp102.T); FixedTemp103.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp103.T); FixedTemp104.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp104.T); FixedTemp105.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp105.T); FixedTemp106.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp106.T); FixedTemp107.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp107.T); FixedTemp108.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp108.T); FixedTemp109.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp109.T); FixedTemp110.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp110.T); FixedTemp111.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp111.T); FixedTemp112.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp112.T); FixedTemp113.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp113.T); FixedTemp114.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp114.T); FixedTemp115.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp115.T); FixedTemp116.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp116.T); FixedTemp117.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp117.T); FixedTemp118.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp118.T); FixedTemp119.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp119.T); FixedTemp120.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp120.T); FixedTemp121.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp121.T); FixedTemp122.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp122.T); FixedTemp123.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp123.T); FixedTemp124.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp124.T); FixedTemp125.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp125.T); FixedTemp126.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp126.T); FixedTemp127.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp127.T); FixedTemp128.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp128.T); FixedTemp129.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp129.T); FixedTemp130.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp130.T); FixedTemp131.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp131.T); FixedTemp132.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp132.T); FixedTemp133.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp133.T); FixedTemp134.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp134.T); FixedTemp135.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp135.T); FixedTemp136.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp136.T); FixedTemp137.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp137.T); FixedTemp138.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp138.T); FixedTemp139.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp139.T); FixedTemp140.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp140.T); FixedTemp141.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp141.T); FixedTemp142.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp142.T); FixedTemp143.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp143.T); FixedTemp144.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp144.T); FixedTemp145.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp145.T); FixedTemp146.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp146.T); FixedTemp147.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp147.T); FixedTemp148.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp148.T); FixedTemp149.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp149.T); FixedTemp150.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp150.T); FixedTemp151.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp151.T); FixedTemp152.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp152.T); FixedTemp153.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp153.T); FixedTemp154.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp154.T); FixedTemp155.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp155.T); FixedTemp156.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp156.T); FixedTemp157.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp157.T); FixedTemp158.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp158.T); FixedTemp159.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp159.T); FixedTemp160.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp160.T); FixedTemp161.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp161.T); FixedTemp162.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp162.T); FixedTemp163.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp163.T); FixedTemp164.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp164.T); FixedTemp165.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp165.T); FixedTemp166.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp166.T); FixedTemp167.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp167.T); FixedTemp168.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp168.T); FixedTemp169.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp169.T); FixedTemp170.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp170.T); FixedTemp171.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp171.T); FixedTemp172.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp172.T); FixedTemp173.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp173.T); FixedTemp174.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp174.T); FixedTemp175.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp175.T); FixedTemp176.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp176.T); FixedTemp177.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp177.T); FixedTemp178.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp178.T); FixedTemp179.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp179.T); FixedTemp180.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp180.T); FixedTemp181.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp181.T); FixedTemp182.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp182.T); FixedTemp183.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp183.T); FixedTemp184.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp184.T); FixedTemp185.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp185.T); FixedTemp186.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp186.T); FixedTemp187.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp187.T); FixedTemp188.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp188.T); FixedTemp189.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp189.T); FixedTemp190.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp190.T); FixedTemp191.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp191.T); FixedTemp192.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp192.T); FixedTemp193.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp193.T); FixedTemp194.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp194.T); FixedTemp195.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp195.T); FixedTemp196.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp196.T); FixedTemp197.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp197.T); FixedTemp198.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp198.T); FixedTemp199.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp199.T); FixedTemp200.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp200.T); FixedTemp201.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp201.T); FixedTemp202.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp202.T); FixedTemp203.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp203.T); FixedTemp204.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp204.T); FixedTemp205.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp205.T); FixedTemp206.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp206.T); FixedTemp207.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp207.T); FixedTemp208.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp208.T); FixedTemp209.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp209.T); FixedTemp210.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp210.T); FixedTemp211.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp211.T); FixedTemp212.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp212.T); FixedTemp213.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp213.T); FixedTemp214.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp214.T); FixedTemp215.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp215.T); FixedTemp216.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp216.T); FixedTemp217.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp217.T); FixedTemp218.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp218.T); FixedTemp219.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp219.T); FixedTemp220.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp220.T); FixedTemp221.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp221.T); FixedTemp222.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp222.T); FixedTemp223.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp223.T); FixedTemp224.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp224.T); FixedTemp225.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp225.T); FixedTemp226.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp226.T); FixedTemp227.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp227.T); FixedTemp228.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp228.T); FixedTemp229.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp229.T); FixedTemp230.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp230.T); FixedTemp231.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp231.T); FixedTemp232.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp232.T); FixedTemp233.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp233.T); FixedTemp234.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp234.T); FixedTemp235.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp235.T); FixedTemp236.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp236.T); FixedTemp237.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp237.T); FixedTemp238.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp238.T); FixedTemp239.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp239.T); FixedTemp240.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp240.T); FixedTemp241.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp241.T); FixedTemp242.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp242.T); FixedTemp243.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp243.T); FixedTemp244.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp244.T); FixedTemp245.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp245.T); FixedTemp246.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp246.T); FixedTemp247.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp247.T); FixedTemp248.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp248.T); FixedTemp249.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp249.T); FixedTemp250.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp250.T); FixedTemp251.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp251.T); FixedTemp252.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp252.T); FixedTemp253.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp253.T); FixedTemp254.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp254.T); FixedTemp255.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp255.T); FixedTemp256.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp256.T); FixedTemp257.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp257.T); FixedTemp258.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp258.T); FixedTemp259.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp259.T); FixedTemp260.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp260.T); FixedTemp261.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp261.T); FixedTemp262.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp262.T); FixedTemp263.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp263.T); FixedTemp264.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp264.T); FixedTemp265.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp265.T); FixedTemp266.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp266.T); FixedTemp267.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp267.T); FixedTemp268.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp268.T); FixedTemp269.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp269.T); FixedTemp270.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp270.T); FixedTemp271.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp271.T); FixedTemp272.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp272.T); FixedTemp273.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp273.T); FixedTemp274.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp274.T); FixedTemp275.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp275.T); FixedTemp276.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp276.T); FixedTemp277.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp277.T); FixedTemp278.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp278.T); FixedTemp279.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp279.T); FixedTemp280.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp280.T); FixedTemp281.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp281.T); FixedTemp282.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp282.T); FixedTemp283.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp283.T); FixedTemp284.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp284.T); FixedTemp285.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp285.T); FixedTemp286.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp286.T); FixedTemp287.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp287.T); FixedTemp288.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp288.T); FixedTemp289.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp289.T); FixedTemp290.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp290.T); FixedTemp291.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp291.T); FixedTemp292.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp292.T); FixedTemp293.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp293.T); FixedTemp294.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp294.T); FixedTemp295.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp295.T); FixedTemp296.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp296.T); FixedTemp297.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp297.T); FixedTemp298.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp298.T); FixedTemp299.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp299.T); FixedTemp300.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp300.T); FixedTemp301.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp301.T); FixedTemp302.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp302.T); FixedTemp303.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp303.T); FixedTemp304.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp304.T); FixedTemp305.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp305.T); FixedTemp306.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp306.T); FixedTemp307.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp307.T); FixedTemp308.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp308.T); FixedTemp309.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp309.T); FixedTemp310.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp310.T); FixedTemp311.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp311.T); FixedTemp312.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp312.T); FixedTemp313.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp313.T); FixedTemp314.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp314.T); FixedTemp315.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp315.T); FixedTemp316.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp316.T); FixedTemp317.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp317.T); FixedTemp318.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp318.T); FixedTemp319.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp319.T); FixedTemp320.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp320.T); FixedTemp321.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp321.T); FixedTemp322.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp322.T); FixedTemp323.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp323.T); FixedTemp324.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp324.T); FixedTemp325.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp325.T); FixedTemp326.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp326.T); FixedTemp327.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp327.T); FixedTemp328.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp328.T); FixedTemp329.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp329.T); FixedTemp330.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp330.T); FixedTemp331.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp331.T); FixedTemp332.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp332.T); FixedTemp333.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp333.T); FixedTemp334.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp334.T); FixedTemp335.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp335.T); FixedTemp336.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp336.T); FixedTemp337.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp337.T); FixedTemp338.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp338.T); FixedTemp339.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp339.T); FixedTemp340.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp340.T); FixedTemp341.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp341.T); FixedTemp342.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp342.T); FixedTemp343.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp343.T); FixedTemp344.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp344.T); FixedTemp345.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp345.T); FixedTemp346.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp346.T); FixedTemp347.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp347.T); FixedTemp348.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp348.T); FixedTemp349.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp349.T); FixedTemp350.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp350.T); FixedTemp351.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp351.T); FixedTemp352.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp352.T); FixedTemp353.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp353.T); FixedTemp354.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp354.T); FixedTemp355.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp355.T); FixedTemp356.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp356.T); FixedTemp357.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp357.T); FixedTemp358.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp358.T); FixedTemp359.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp359.T); FixedTemp360.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp360.T); FixedTemp361.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp361.T); FixedTemp362.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp362.T); FixedTemp363.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp363.T); FixedTemp364.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp364.T); FixedTemp365.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp365.T); FixedTemp366.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp366.T); FixedTemp367.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp367.T); FixedTemp368.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp368.T); FixedTemp369.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp369.T); FixedTemp370.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp370.T); FixedTemp371.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp371.T); FixedTemp372.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp372.T); FixedTemp373.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp373.T); FixedTemp374.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp374.T); FixedTemp375.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp375.T); FixedTemp376.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp376.T); FixedTemp377.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp377.T); FixedTemp378.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp378.T); FixedTemp379.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp379.T); FixedTemp380.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp380.T); FixedTemp381.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp381.T); FixedTemp382.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp382.T); FixedTemp383.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp383.T); FixedTemp384.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp384.T); FixedTemp385.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp385.T); FixedTemp386.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp386.T); FixedTemp387.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp387.T); FixedTemp388.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp388.T); FixedTemp389.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp389.T); FixedTemp390.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp390.T); FixedTemp391.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp391.T); FixedTemp392.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp392.T); FixedTemp393.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp393.T); FixedTemp394.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp394.T); FixedTemp395.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp395.T); FixedTemp396.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp396.T); FixedTemp397.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp397.T); FixedTemp398.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp398.T); FixedTemp399.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp399.T); FixedTemp400.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp400.T); FixedTemp401.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp401.T); FixedTemp402.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp402.T); FixedTemp403.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp403.T); FixedTemp404.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp404.T); FixedTemp405.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp405.T); FixedTemp406.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp406.T); FixedTemp407.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp407.T); FixedTemp408.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp408.T); FixedTemp409.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp409.T); FixedTemp410.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp410.T); FixedTemp411.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp411.T); FixedTemp412.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp412.T); FixedTemp413.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp413.T); FixedTemp414.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp414.T); FixedTemp415.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp415.T); FixedTemp416.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp416.T); FixedTemp417.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp417.T); FixedTemp418.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp418.T); FixedTemp419.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp419.T); FixedTemp420.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp420.T); FixedTemp421.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp421.T); FixedTemp422.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp422.T); FixedTemp423.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp423.T); FixedTemp424.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp424.T); FixedTemp425.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp425.T); FixedTemp426.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp426.T); FixedTemp427.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp427.T); FixedTemp428.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp428.T); FixedTemp429.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp429.T); FixedTemp430.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp430.T); FixedTemp431.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp431.T); FixedTemp432.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp432.T); FixedTemp433.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp433.T); FixedTemp434.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp434.T); FixedTemp435.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp435.T); FixedTemp436.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp436.T); FixedTemp437.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp437.T); FixedTemp438.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp438.T); FixedTemp439.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp439.T); FixedTemp440.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp440.T); FixedTemp441.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp441.T); FixedTemp442.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp442.T); FixedTemp443.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp443.T); FixedTemp444.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp444.T); FixedTemp445.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp445.T); FixedTemp446.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp446.T); FixedTemp447.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp447.T); FixedTemp448.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp448.T); FixedTemp449.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp449.T); FixedTemp450.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp450.T); FixedTemp451.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp451.T); FixedTemp452.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp452.T); FixedTemp453.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp453.T); FixedTemp454.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp454.T); FixedTemp455.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp455.T); FixedTemp456.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp456.T); FixedTemp457.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp457.T); FixedTemp458.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp458.T); FixedTemp459.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp459.T); FixedTemp460.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp460.T); FixedTemp461.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp461.T); FixedTemp462.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp462.T); FixedTemp463.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp463.T); FixedTemp464.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp464.T); FixedTemp465.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp465.T); FixedTemp466.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp466.T); FixedTemp467.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp467.T); FixedTemp468.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp468.T); FixedTemp469.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp469.T); FixedTemp470.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp470.T); FixedTemp471.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp471.T); FixedTemp472.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp472.T); FixedTemp473.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp473.T); FixedTemp474.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp474.T); FixedTemp475.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp475.T); FixedTemp476.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp476.T); FixedTemp477.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp477.T); FixedTemp478.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp478.T); FixedTemp479.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp479.T); FixedTemp480.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp480.T); FixedTemp481.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp481.T); FixedTemp482.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp482.T); FixedTemp483.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp483.T); FixedTemp484.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp484.T); FixedTemp485.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp485.T); FixedTemp486.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp486.T); FixedTemp487.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp487.T); FixedTemp488.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp488.T); FixedTemp489.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp489.T); FixedTemp490.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp490.T); FixedTemp491.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp491.T); FixedTemp492.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp492.T); FixedTemp493.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp493.T); FixedTemp494.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp494.T); FixedTemp495.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp495.T); FixedTemp496.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp496.T); FixedTemp497.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp497.T); FixedTemp498.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp498.T); FixedTemp499.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp499.T); FixedTemp500.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp500.T); FixedTemp501.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp501.T); FixedTemp502.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp502.T); FixedTemp503.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp503.T); FixedTemp504.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp504.T); FixedTemp505.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp505.T); FixedTemp506.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp506.T); FixedTemp507.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp507.T); FixedTemp508.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp508.T); FixedTemp509.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp509.T); FixedTemp510.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp510.T); FixedTemp511.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp511.T); FixedTemp512.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp512.T); FixedTemp513.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp513.T); FixedTemp514.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp514.T); FixedTemp515.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp515.T); FixedTemp516.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp516.T); FixedTemp517.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp517.T); FixedTemp518.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp518.T); FixedTemp519.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp519.T); FixedTemp520.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp520.T); FixedTemp521.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp521.T); FixedTemp522.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp522.T); FixedTemp523.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp523.T); FixedTemp524.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp524.T); FixedTemp525.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp525.T); FixedTemp526.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp526.T); FixedTemp527.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp527.T); FixedTemp528.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp528.T); FixedTemp529.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp529.T); FixedTemp530.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp530.T); FixedTemp531.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp531.T); FixedTemp532.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp532.T); FixedTemp533.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp533.T); FixedTemp534.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp534.T); FixedTemp535.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp535.T); FixedTemp536.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp536.T); FixedTemp537.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp537.T); FixedTemp538.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp538.T); FixedTemp539.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp539.T); FixedTemp540.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp540.T); FixedTemp541.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp541.T); FixedTemp542.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp542.T); FixedTemp543.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp543.T); FixedTemp544.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp544.T); FixedTemp545.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp545.T); FixedTemp546.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp546.T); FixedTemp547.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp547.T); FixedTemp548.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp548.T); FixedTemp549.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp549.T); FixedTemp550.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp550.T); FixedTemp551.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp551.T); FixedTemp552.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp552.T); FixedTemp553.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp553.T); FixedTemp554.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp554.T); FixedTemp555.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp555.T); FixedTemp556.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp556.T); FixedTemp557.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp557.T); FixedTemp558.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp558.T); FixedTemp559.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp559.T); FixedTemp560.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp560.T); FixedTemp561.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp561.T); FixedTemp562.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp562.T); FixedTemp563.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp563.T); FixedTemp564.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp564.T); FixedTemp565.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp565.T); FixedTemp566.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp566.T); FixedTemp567.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp567.T); FixedTemp568.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp568.T); FixedTemp569.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp569.T); FixedTemp570.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp570.T); FixedTemp571.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp571.T); FixedTemp572.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp572.T); FixedTemp573.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp573.T); FixedTemp574.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp574.T); FixedTemp575.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp575.T); FixedTemp576.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp576.T); FixedTemp577.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp577.T); FixedTemp578.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp578.T); FixedTemp579.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp579.T); FixedTemp580.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp580.T); FixedTemp581.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp581.T); FixedTemp582.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp582.T); FixedTemp583.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp583.T); FixedTemp584.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp584.T); FixedTemp585.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp585.T); FixedTemp586.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp586.T); FixedTemp587.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp587.T); FixedTemp588.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp588.T); FixedTemp589.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp589.T); FixedTemp590.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp590.T); FixedTemp591.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp591.T); FixedTemp592.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp592.T); FixedTemp593.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp593.T); FixedTemp594.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp594.T); FixedTemp595.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp595.T); FixedTemp596.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp596.T); FixedTemp597.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp597.T); FixedTemp598.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp598.T); FixedTemp599.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp599.T); FixedTemp600.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp600.T); FixedTemp601.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp601.T); FixedTemp602.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp602.T); FixedTemp603.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp603.T); FixedTemp604.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp604.T); FixedTemp605.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp605.T); FixedTemp606.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp606.T); FixedTemp607.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp607.T); FixedTemp608.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp608.T); FixedTemp609.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp609.T); FixedTemp610.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp610.T); FixedTemp611.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp611.T); FixedTemp612.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp612.T); FixedTemp613.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp613.T); FixedTemp614.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp614.T); FixedTemp615.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp615.T); FixedTemp616.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp616.T); FixedTemp617.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp617.T); FixedTemp618.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp618.T); FixedTemp619.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp619.T); FixedTemp620.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp620.T); FixedTemp621.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp621.T); FixedTemp622.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp622.T); FixedTemp623.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp623.T); FixedTemp624.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp624.T); FixedTemp625.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp625.T); FixedTemp626.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp626.T); FixedTemp627.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp627.T); FixedTemp628.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp628.T); FixedTemp629.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp629.T); FixedTemp630.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp630.T); FixedTemp631.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp631.T); FixedTemp632.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp632.T); FixedTemp633.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp633.T); FixedTemp634.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp634.T); FixedTemp635.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp635.T); FixedTemp636.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp636.T); FixedTemp637.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp637.T); FixedTemp638.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp638.T); FixedTemp639.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp639.T); FixedTemp640.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp640.T); FixedTemp641.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp641.T); FixedTemp642.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp642.T); FixedTemp643.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp643.T); FixedTemp644.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp644.T); FixedTemp645.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp645.T); FixedTemp646.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp646.T); FixedTemp647.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp647.T); FixedTemp648.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp648.T); FixedTemp649.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp649.T); FixedTemp650.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp650.T); FixedTemp651.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp651.T); FixedTemp652.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp652.T); FixedTemp653.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp653.T); FixedTemp654.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp654.T); FixedTemp655.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp655.T); FixedTemp656.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp656.T); FixedTemp657.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp657.T); FixedTemp658.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp658.T); FixedTemp659.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp659.T); FixedTemp660.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp660.T); FixedTemp661.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp661.T); FixedTemp662.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp662.T); FixedTemp663.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp663.T); FixedTemp664.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp664.T); FixedTemp665.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp665.T); FixedTemp666.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp666.T); FixedTemp667.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp667.T); FixedTemp668.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp668.T); FixedTemp669.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp669.T); FixedTemp670.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp670.T); FixedTemp671.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp671.T); FixedTemp672.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp672.T); FixedTemp673.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp673.T); FixedTemp674.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp674.T); FixedTemp675.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp675.T); FixedTemp676.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp676.T); FixedTemp677.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp677.T); FixedTemp678.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp678.T); FixedTemp679.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp679.T); FixedTemp680.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp680.T); FixedTemp681.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp681.T); FixedTemp682.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp682.T); FixedTemp683.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp683.T); FixedTemp684.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp684.T); FixedTemp685.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp685.T); FixedTemp686.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp686.T); FixedTemp687.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp687.T); FixedTemp688.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp688.T); FixedTemp689.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp689.T); FixedTemp690.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp690.T); FixedTemp691.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp691.T); FixedTemp692.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp692.T); FixedTemp693.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp693.T); FixedTemp694.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp694.T); FixedTemp695.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp695.T); FixedTemp696.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp696.T); FixedTemp697.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp697.T); FixedTemp698.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp698.T); FixedTemp699.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp699.T); FixedTemp700.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp700.T); FixedTemp701.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp701.T); FixedTemp702.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp702.T); FixedTemp703.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp703.T); FixedTemp704.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp704.T); FixedTemp705.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp705.T); FixedTemp706.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp706.T); FixedTemp707.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp707.T); FixedTemp708.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp708.T); FixedTemp709.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp709.T); FixedTemp710.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp710.T); FixedTemp711.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp711.T); FixedTemp712.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp712.T); FixedTemp713.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp713.T); FixedTemp714.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp714.T); FixedTemp715.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp715.T); FixedTemp716.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp716.T); FixedTemp717.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp717.T); FixedTemp718.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp718.T); FixedTemp719.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp719.T); FixedTemp720.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp720.T); FixedTemp721.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp721.T); FixedTemp722.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp722.T); FixedTemp723.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp723.T); FixedTemp724.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp724.T); FixedTemp725.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp725.T); FixedTemp726.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp726.T); FixedTemp727.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp727.T); FixedTemp728.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp728.T); FixedTemp729.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp729.T); FixedTemp730.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp730.T); FixedTemp731.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp731.T); FixedTemp732.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp732.T); FixedTemp733.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp733.T); FixedTemp734.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp734.T); FixedTemp735.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp735.T); FixedTemp736.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp736.T); FixedTemp737.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp737.T); FixedTemp738.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp738.T); FixedTemp739.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp739.T); FixedTemp740.port.T = Modelica.SIunits.Conversions.from_degC(FixedTemp740.T); TsCABI0CabiA001001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001001001.port.T); TsCABI0CabiA001001001.port.Q_flow = 0.0; TsCABI0CabiA002001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002001001.port.T); TsCABI0CabiA002001001.port.Q_flow = 0.0; TsCABI0CabiA003001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003001001.port.T); TsCABI0CabiA003001001.port.Q_flow = 0.0; TsCABI0CabiA004001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004001001.port.T); TsCABI0CabiA004001001.port.Q_flow = 0.0; TsCABI0CabiA005001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005001001.port.T); TsCABI0CabiA005001001.port.Q_flow = 0.0; TsCABI0CabiA006001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006001001.port.T); TsCABI0CabiA006001001.port.Q_flow = 0.0; TsCABI0CabiA007001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007001001.port.T); TsCABI0CabiA007001001.port.Q_flow = 0.0; TsCABI0CabiA008001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008001001.port.T); TsCABI0CabiA008001001.port.Q_flow = 0.0; TsCABI0CabiA009001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009001001.port.T); TsCABI0CabiA009001001.port.Q_flow = 0.0; TsCABI0CabiA010001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010001001.port.T); TsCABI0CabiA010001001.port.Q_flow = 0.0; TsCABI0CabiA011001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011001001.port.T); TsCABI0CabiA011001001.port.Q_flow = 0.0; TsCABI0CabiA012001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012001001.port.T); TsCABI0CabiA012001001.port.Q_flow = 0.0; TsCABI0CabiA013001001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013001001.port.T); TsCABI0CabiA013001001.port.Q_flow = 0.0; TsCABI0CabiA001002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001002001.port.T); TsCABI0CabiA001002001.port.Q_flow = 0.0; TsCABI0CabiA002002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002002001.port.T); TsCABI0CabiA002002001.port.Q_flow = 0.0; TsCABI0CabiA003002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003002001.port.T); TsCABI0CabiA003002001.port.Q_flow = 0.0; TsCABI0CabiA004002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004002001.port.T); TsCABI0CabiA004002001.port.Q_flow = 0.0; TsCABI0CabiA005002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005002001.port.T); TsCABI0CabiA005002001.port.Q_flow = 0.0; TsCABI0CabiA006002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006002001.port.T); TsCABI0CabiA006002001.port.Q_flow = 0.0; TsCABI0CabiA007002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007002001.port.T); TsCABI0CabiA007002001.port.Q_flow = 0.0; TsCABI0CabiA008002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008002001.port.T); TsCABI0CabiA008002001.port.Q_flow = 0.0; TsCABI0CabiA009002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009002001.port.T); TsCABI0CabiA009002001.port.Q_flow = 0.0; TsCABI0CabiA010002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010002001.port.T); TsCABI0CabiA010002001.port.Q_flow = 0.0; TsCABI0CabiA011002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011002001.port.T); TsCABI0CabiA011002001.port.Q_flow = 0.0; TsCABI0CabiA012002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012002001.port.T); TsCABI0CabiA012002001.port.Q_flow = 0.0; TsCABI0CabiA013002001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013002001.port.T); TsCABI0CabiA013002001.port.Q_flow = 0.0; TsCABI0CabiA001003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001003001.port.T); TsCABI0CabiA001003001.port.Q_flow = 0.0; TsCABI0CabiA002003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002003001.port.T); TsCABI0CabiA002003001.port.Q_flow = 0.0; TsCABI0CabiA003003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003003001.port.T); TsCABI0CabiA003003001.port.Q_flow = 0.0; TsCABI0CabiA004003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004003001.port.T); TsCABI0CabiA004003001.port.Q_flow = 0.0; TsCABI0CabiA005003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005003001.port.T); TsCABI0CabiA005003001.port.Q_flow = 0.0; TsCABI0CabiA006003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006003001.port.T); TsCABI0CabiA006003001.port.Q_flow = 0.0; TsCABI0CabiA007003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007003001.port.T); TsCABI0CabiA007003001.port.Q_flow = 0.0; TsCABI0CabiA008003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008003001.port.T); TsCABI0CabiA008003001.port.Q_flow = 0.0; TsCABI0CabiA009003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009003001.port.T); TsCABI0CabiA009003001.port.Q_flow = 0.0; TsCABI0CabiA010003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010003001.port.T); TsCABI0CabiA010003001.port.Q_flow = 0.0; TsCABI0CabiA011003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011003001.port.T); TsCABI0CabiA011003001.port.Q_flow = 0.0; TsCABI0CabiA012003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012003001.port.T); TsCABI0CabiA012003001.port.Q_flow = 0.0; TsCABI0CabiA013003001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013003001.port.T); TsCABI0CabiA013003001.port.Q_flow = 0.0; TsCABI0CabiA001004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001004001.port.T); TsCABI0CabiA001004001.port.Q_flow = 0.0; TsCABI0CabiA002004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002004001.port.T); TsCABI0CabiA002004001.port.Q_flow = 0.0; TsCABI0CabiA003004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003004001.port.T); TsCABI0CabiA003004001.port.Q_flow = 0.0; TsCABI0CabiA004004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004004001.port.T); TsCABI0CabiA004004001.port.Q_flow = 0.0; TsCABI0CabiA005004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005004001.port.T); TsCABI0CabiA005004001.port.Q_flow = 0.0; TsCABI0CabiA006004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006004001.port.T); TsCABI0CabiA006004001.port.Q_flow = 0.0; TsCABI0CabiA007004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007004001.port.T); TsCABI0CabiA007004001.port.Q_flow = 0.0; TsCABI0CabiA008004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008004001.port.T); TsCABI0CabiA008004001.port.Q_flow = 0.0; TsCABI0CabiA009004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009004001.port.T); TsCABI0CabiA009004001.port.Q_flow = 0.0; TsCABI0CabiA010004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010004001.port.T); TsCABI0CabiA010004001.port.Q_flow = 0.0; TsCABI0CabiA011004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011004001.port.T); TsCABI0CabiA011004001.port.Q_flow = 0.0; TsCABI0CabiA012004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012004001.port.T); TsCABI0CabiA012004001.port.Q_flow = 0.0; TsCABI0CabiA013004001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013004001.port.T); TsCABI0CabiA013004001.port.Q_flow = 0.0; TsCABI0CabiA001005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001005001.port.T); TsCABI0CabiA001005001.port.Q_flow = 0.0; TsCABI0CabiA002005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002005001.port.T); TsCABI0CabiA002005001.port.Q_flow = 0.0; TsCABI0CabiA003005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003005001.port.T); TsCABI0CabiA003005001.port.Q_flow = 0.0; TsCABI0CabiA004005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004005001.port.T); TsCABI0CabiA004005001.port.Q_flow = 0.0; TsCABI0CabiA005005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005005001.port.T); TsCABI0CabiA005005001.port.Q_flow = 0.0; TsCABI0CabiA006005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006005001.port.T); TsCABI0CabiA006005001.port.Q_flow = 0.0; TsCABI0CabiA007005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007005001.port.T); TsCABI0CabiA007005001.port.Q_flow = 0.0; TsCABI0CabiA008005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008005001.port.T); TsCABI0CabiA008005001.port.Q_flow = 0.0; TsCABI0CabiA009005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009005001.port.T); TsCABI0CabiA009005001.port.Q_flow = 0.0; TsCABI0CabiA010005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010005001.port.T); TsCABI0CabiA010005001.port.Q_flow = 0.0; TsCABI0CabiA011005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011005001.port.T); TsCABI0CabiA011005001.port.Q_flow = 0.0; TsCABI0CabiA012005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012005001.port.T); TsCABI0CabiA012005001.port.Q_flow = 0.0; TsCABI0CabiA013005001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013005001.port.T); TsCABI0CabiA013005001.port.Q_flow = 0.0; TsCABI0CabiA001006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001006001.port.T); TsCABI0CabiA001006001.port.Q_flow = 0.0; TsCABI0CabiA002006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002006001.port.T); TsCABI0CabiA002006001.port.Q_flow = 0.0; TsCABI0CabiA003006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003006001.port.T); TsCABI0CabiA003006001.port.Q_flow = 0.0; TsCABI0CabiA004006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004006001.port.T); TsCABI0CabiA004006001.port.Q_flow = 0.0; TsCABI0CabiA005006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005006001.port.T); TsCABI0CabiA005006001.port.Q_flow = 0.0; TsCABI0CabiA006006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006006001.port.T); TsCABI0CabiA006006001.port.Q_flow = 0.0; TsCABI0CabiA007006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007006001.port.T); TsCABI0CabiA007006001.port.Q_flow = 0.0; TsCABI0CabiA008006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008006001.port.T); TsCABI0CabiA008006001.port.Q_flow = 0.0; TsCABI0CabiA009006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009006001.port.T); TsCABI0CabiA009006001.port.Q_flow = 0.0; TsCABI0CabiA010006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010006001.port.T); TsCABI0CabiA010006001.port.Q_flow = 0.0; TsCABI0CabiA011006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011006001.port.T); TsCABI0CabiA011006001.port.Q_flow = 0.0; TsCABI0CabiA012006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012006001.port.T); TsCABI0CabiA012006001.port.Q_flow = 0.0; TsCABI0CabiA013006001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013006001.port.T); TsCABI0CabiA013006001.port.Q_flow = 0.0; TsCABI0CabiA001007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001007001.port.T); TsCABI0CabiA001007001.port.Q_flow = 0.0; TsCABI0CabiA002007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002007001.port.T); TsCABI0CabiA002007001.port.Q_flow = 0.0; TsCABI0CabiA003007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003007001.port.T); TsCABI0CabiA003007001.port.Q_flow = 0.0; TsCABI0CabiA004007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004007001.port.T); TsCABI0CabiA004007001.port.Q_flow = 0.0; TsCABI0CabiA005007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005007001.port.T); TsCABI0CabiA005007001.port.Q_flow = 0.0; TsCABI0CabiA006007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006007001.port.T); TsCABI0CabiA006007001.port.Q_flow = 0.0; TsCABI0CabiA007007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007007001.port.T); TsCABI0CabiA007007001.port.Q_flow = 0.0; TsCABI0CabiA008007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008007001.port.T); TsCABI0CabiA008007001.port.Q_flow = 0.0; TsCABI0CabiA009007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009007001.port.T); TsCABI0CabiA009007001.port.Q_flow = 0.0; TsCABI0CabiA010007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010007001.port.T); TsCABI0CabiA010007001.port.Q_flow = 0.0; TsCABI0CabiA011007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011007001.port.T); TsCABI0CabiA011007001.port.Q_flow = 0.0; TsCABI0CabiA012007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012007001.port.T); TsCABI0CabiA012007001.port.Q_flow = 0.0; TsCABI0CabiA013007001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013007001.port.T); TsCABI0CabiA013007001.port.Q_flow = 0.0; TsCABI0CabiA001008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001008001.port.T); TsCABI0CabiA001008001.port.Q_flow = 0.0; TsCABI0CabiA002008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002008001.port.T); TsCABI0CabiA002008001.port.Q_flow = 0.0; TsCABI0CabiA003008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003008001.port.T); TsCABI0CabiA003008001.port.Q_flow = 0.0; TsCABI0CabiA004008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004008001.port.T); TsCABI0CabiA004008001.port.Q_flow = 0.0; TsCABI0CabiA005008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005008001.port.T); TsCABI0CabiA005008001.port.Q_flow = 0.0; TsCABI0CabiA006008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006008001.port.T); TsCABI0CabiA006008001.port.Q_flow = 0.0; TsCABI0CabiA007008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007008001.port.T); TsCABI0CabiA007008001.port.Q_flow = 0.0; TsCABI0CabiA008008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008008001.port.T); TsCABI0CabiA008008001.port.Q_flow = 0.0; TsCABI0CabiA009008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009008001.port.T); TsCABI0CabiA009008001.port.Q_flow = 0.0; TsCABI0CabiA010008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010008001.port.T); TsCABI0CabiA010008001.port.Q_flow = 0.0; TsCABI0CabiA011008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011008001.port.T); TsCABI0CabiA011008001.port.Q_flow = 0.0; TsCABI0CabiA012008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012008001.port.T); TsCABI0CabiA012008001.port.Q_flow = 0.0; TsCABI0CabiA013008001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013008001.port.T); TsCABI0CabiA013008001.port.Q_flow = 0.0; TsCABI0CabiA001009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001009001.port.T); TsCABI0CabiA001009001.port.Q_flow = 0.0; TsCABI0CabiA002009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002009001.port.T); TsCABI0CabiA002009001.port.Q_flow = 0.0; TsCABI0CabiA003009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003009001.port.T); TsCABI0CabiA003009001.port.Q_flow = 0.0; TsCABI0CabiA004009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004009001.port.T); TsCABI0CabiA004009001.port.Q_flow = 0.0; TsCABI0CabiA005009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005009001.port.T); TsCABI0CabiA005009001.port.Q_flow = 0.0; TsCABI0CabiA006009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006009001.port.T); TsCABI0CabiA006009001.port.Q_flow = 0.0; TsCABI0CabiA007009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007009001.port.T); TsCABI0CabiA007009001.port.Q_flow = 0.0; TsCABI0CabiA008009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008009001.port.T); TsCABI0CabiA008009001.port.Q_flow = 0.0; TsCABI0CabiA009009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009009001.port.T); TsCABI0CabiA009009001.port.Q_flow = 0.0; TsCABI0CabiA010009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010009001.port.T); TsCABI0CabiA010009001.port.Q_flow = 0.0; TsCABI0CabiA011009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011009001.port.T); TsCABI0CabiA011009001.port.Q_flow = 0.0; TsCABI0CabiA012009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012009001.port.T); TsCABI0CabiA012009001.port.Q_flow = 0.0; TsCABI0CabiA013009001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013009001.port.T); TsCABI0CabiA013009001.port.Q_flow = 0.0; TsCABI0CabiA001010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001010001.port.T); TsCABI0CabiA001010001.port.Q_flow = 0.0; TsCABI0CabiA002010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002010001.port.T); TsCABI0CabiA002010001.port.Q_flow = 0.0; TsCABI0CabiA003010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003010001.port.T); TsCABI0CabiA003010001.port.Q_flow = 0.0; TsCABI0CabiA004010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004010001.port.T); TsCABI0CabiA004010001.port.Q_flow = 0.0; TsCABI0CabiA005010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005010001.port.T); TsCABI0CabiA005010001.port.Q_flow = 0.0; TsCABI0CabiA006010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006010001.port.T); TsCABI0CabiA006010001.port.Q_flow = 0.0; TsCABI0CabiA007010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007010001.port.T); TsCABI0CabiA007010001.port.Q_flow = 0.0; TsCABI0CabiA008010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008010001.port.T); TsCABI0CabiA008010001.port.Q_flow = 0.0; TsCABI0CabiA009010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009010001.port.T); TsCABI0CabiA009010001.port.Q_flow = 0.0; TsCABI0CabiA010010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010010001.port.T); TsCABI0CabiA010010001.port.Q_flow = 0.0; TsCABI0CabiA011010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011010001.port.T); TsCABI0CabiA011010001.port.Q_flow = 0.0; TsCABI0CabiA012010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012010001.port.T); TsCABI0CabiA012010001.port.Q_flow = 0.0; TsCABI0CabiA013010001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013010001.port.T); TsCABI0CabiA013010001.port.Q_flow = 0.0; TsCABI0CabiA001011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001011001.port.T); TsCABI0CabiA001011001.port.Q_flow = 0.0; TsCABI0CabiA002011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002011001.port.T); TsCABI0CabiA002011001.port.Q_flow = 0.0; TsCABI0CabiA003011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003011001.port.T); TsCABI0CabiA003011001.port.Q_flow = 0.0; TsCABI0CabiA004011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004011001.port.T); TsCABI0CabiA004011001.port.Q_flow = 0.0; TsCABI0CabiA005011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005011001.port.T); TsCABI0CabiA005011001.port.Q_flow = 0.0; TsCABI0CabiA006011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006011001.port.T); TsCABI0CabiA006011001.port.Q_flow = 0.0; TsCABI0CabiA007011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007011001.port.T); TsCABI0CabiA007011001.port.Q_flow = 0.0; TsCABI0CabiA008011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008011001.port.T); TsCABI0CabiA008011001.port.Q_flow = 0.0; TsCABI0CabiA009011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009011001.port.T); TsCABI0CabiA009011001.port.Q_flow = 0.0; TsCABI0CabiA010011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010011001.port.T); TsCABI0CabiA010011001.port.Q_flow = 0.0; TsCABI0CabiA011011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011011001.port.T); TsCABI0CabiA011011001.port.Q_flow = 0.0; TsCABI0CabiA012011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012011001.port.T); TsCABI0CabiA012011001.port.Q_flow = 0.0; TsCABI0CabiA013011001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013011001.port.T); TsCABI0CabiA013011001.port.Q_flow = 0.0; TsCABI0CabiA001012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001012001.port.T); TsCABI0CabiA001012001.port.Q_flow = 0.0; TsCABI0CabiA002012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002012001.port.T); TsCABI0CabiA002012001.port.Q_flow = 0.0; TsCABI0CabiA003012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003012001.port.T); TsCABI0CabiA003012001.port.Q_flow = 0.0; TsCABI0CabiA004012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004012001.port.T); TsCABI0CabiA004012001.port.Q_flow = 0.0; TsCABI0CabiA005012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005012001.port.T); TsCABI0CabiA005012001.port.Q_flow = 0.0; TsCABI0CabiA006012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006012001.port.T); TsCABI0CabiA006012001.port.Q_flow = 0.0; TsCABI0CabiA007012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007012001.port.T); TsCABI0CabiA007012001.port.Q_flow = 0.0; TsCABI0CabiA008012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008012001.port.T); TsCABI0CabiA008012001.port.Q_flow = 0.0; TsCABI0CabiA009012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009012001.port.T); TsCABI0CabiA009012001.port.Q_flow = 0.0; TsCABI0CabiA010012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010012001.port.T); TsCABI0CabiA010012001.port.Q_flow = 0.0; TsCABI0CabiA011012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011012001.port.T); TsCABI0CabiA011012001.port.Q_flow = 0.0; TsCABI0CabiA012012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012012001.port.T); TsCABI0CabiA012012001.port.Q_flow = 0.0; TsCABI0CabiA013012001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013012001.port.T); TsCABI0CabiA013012001.port.Q_flow = 0.0; TsCABI0CabiA001013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001013001.port.T); TsCABI0CabiA001013001.port.Q_flow = 0.0; TsCABI0CabiA002013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002013001.port.T); TsCABI0CabiA002013001.port.Q_flow = 0.0; TsCABI0CabiA003013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003013001.port.T); TsCABI0CabiA003013001.port.Q_flow = 0.0; TsCABI0CabiA004013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004013001.port.T); TsCABI0CabiA004013001.port.Q_flow = 0.0; TsCABI0CabiA005013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005013001.port.T); TsCABI0CabiA005013001.port.Q_flow = 0.0; TsCABI0CabiA006013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006013001.port.T); TsCABI0CabiA006013001.port.Q_flow = 0.0; TsCABI0CabiA007013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007013001.port.T); TsCABI0CabiA007013001.port.Q_flow = 0.0; TsCABI0CabiA008013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008013001.port.T); TsCABI0CabiA008013001.port.Q_flow = 0.0; TsCABI0CabiA009013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009013001.port.T); TsCABI0CabiA009013001.port.Q_flow = 0.0; TsCABI0CabiA010013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010013001.port.T); TsCABI0CabiA010013001.port.Q_flow = 0.0; TsCABI0CabiA011013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011013001.port.T); TsCABI0CabiA011013001.port.Q_flow = 0.0; TsCABI0CabiA012013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012013001.port.T); TsCABI0CabiA012013001.port.Q_flow = 0.0; TsCABI0CabiA013013001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013013001.port.T); TsCABI0CabiA013013001.port.Q_flow = 0.0; TsCABI0CabiA001014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001014001.port.T); TsCABI0CabiA001014001.port.Q_flow = 0.0; TsCABI0CabiA002014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002014001.port.T); TsCABI0CabiA002014001.port.Q_flow = 0.0; TsCABI0CabiA003014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003014001.port.T); TsCABI0CabiA003014001.port.Q_flow = 0.0; TsCABI0CabiA004014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004014001.port.T); TsCABI0CabiA004014001.port.Q_flow = 0.0; TsCABI0CabiA005014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005014001.port.T); TsCABI0CabiA005014001.port.Q_flow = 0.0; TsCABI0CabiA006014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006014001.port.T); TsCABI0CabiA006014001.port.Q_flow = 0.0; TsCABI0CabiA007014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007014001.port.T); TsCABI0CabiA007014001.port.Q_flow = 0.0; TsCABI0CabiA008014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008014001.port.T); TsCABI0CabiA008014001.port.Q_flow = 0.0; TsCABI0CabiA009014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009014001.port.T); TsCABI0CabiA009014001.port.Q_flow = 0.0; TsCABI0CabiA010014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010014001.port.T); TsCABI0CabiA010014001.port.Q_flow = 0.0; TsCABI0CabiA011014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011014001.port.T); TsCABI0CabiA011014001.port.Q_flow = 0.0; TsCABI0CabiA012014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012014001.port.T); TsCABI0CabiA012014001.port.Q_flow = 0.0; TsCABI0CabiA013014001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013014001.port.T); TsCABI0CabiA013014001.port.Q_flow = 0.0; TsCABI0CabiA001015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001015001.port.T); TsCABI0CabiA001015001.port.Q_flow = 0.0; TsCABI0CabiA002015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002015001.port.T); TsCABI0CabiA002015001.port.Q_flow = 0.0; TsCABI0CabiA003015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003015001.port.T); TsCABI0CabiA003015001.port.Q_flow = 0.0; TsCABI0CabiA004015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004015001.port.T); TsCABI0CabiA004015001.port.Q_flow = 0.0; TsCABI0CabiA005015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005015001.port.T); TsCABI0CabiA005015001.port.Q_flow = 0.0; TsCABI0CabiA006015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006015001.port.T); TsCABI0CabiA006015001.port.Q_flow = 0.0; TsCABI0CabiA007015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007015001.port.T); TsCABI0CabiA007015001.port.Q_flow = 0.0; TsCABI0CabiA008015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008015001.port.T); TsCABI0CabiA008015001.port.Q_flow = 0.0; TsCABI0CabiA009015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009015001.port.T); TsCABI0CabiA009015001.port.Q_flow = 0.0; TsCABI0CabiA010015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010015001.port.T); TsCABI0CabiA010015001.port.Q_flow = 0.0; TsCABI0CabiA011015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011015001.port.T); TsCABI0CabiA011015001.port.Q_flow = 0.0; TsCABI0CabiA012015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012015001.port.T); TsCABI0CabiA012015001.port.Q_flow = 0.0; TsCABI0CabiA013015001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013015001.port.T); TsCABI0CabiA013015001.port.Q_flow = 0.0; TsCABI0CabiA001016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001016001.port.T); TsCABI0CabiA001016001.port.Q_flow = 0.0; TsCABI0CabiA002016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002016001.port.T); TsCABI0CabiA002016001.port.Q_flow = 0.0; TsCABI0CabiA003016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003016001.port.T); TsCABI0CabiA003016001.port.Q_flow = 0.0; TsCABI0CabiA004016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004016001.port.T); TsCABI0CabiA004016001.port.Q_flow = 0.0; TsCABI0CabiA005016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005016001.port.T); TsCABI0CabiA005016001.port.Q_flow = 0.0; TsCABI0CabiA006016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006016001.port.T); TsCABI0CabiA006016001.port.Q_flow = 0.0; TsCABI0CabiA007016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007016001.port.T); TsCABI0CabiA007016001.port.Q_flow = 0.0; TsCABI0CabiA008016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008016001.port.T); TsCABI0CabiA008016001.port.Q_flow = 0.0; TsCABI0CabiA009016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009016001.port.T); TsCABI0CabiA009016001.port.Q_flow = 0.0; TsCABI0CabiA010016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010016001.port.T); TsCABI0CabiA010016001.port.Q_flow = 0.0; TsCABI0CabiA011016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011016001.port.T); TsCABI0CabiA011016001.port.Q_flow = 0.0; TsCABI0CabiA012016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012016001.port.T); TsCABI0CabiA012016001.port.Q_flow = 0.0; TsCABI0CabiA013016001.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013016001.port.T); TsCABI0CabiA013016001.port.Q_flow = 0.0; TsCABI0CabiA002001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002001002.port.T); TsCABI0CabiA002001002.port.Q_flow = 0.0; TsCABI0CabiA003001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003001002.port.T); TsCABI0CabiA003001002.port.Q_flow = 0.0; TsCABI0CabiA004001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004001002.port.T); TsCABI0CabiA004001002.port.Q_flow = 0.0; TsCABI0CabiA005001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005001002.port.T); TsCABI0CabiA005001002.port.Q_flow = 0.0; TsCABI0CabiA006001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006001002.port.T); TsCABI0CabiA006001002.port.Q_flow = 0.0; TsCABI0CabiA007001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007001002.port.T); TsCABI0CabiA007001002.port.Q_flow = 0.0; TsCABI0CabiA008001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008001002.port.T); TsCABI0CabiA008001002.port.Q_flow = 0.0; TsCABI0CabiA009001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009001002.port.T); TsCABI0CabiA009001002.port.Q_flow = 0.0; TsCABI0CabiA010001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010001002.port.T); TsCABI0CabiA010001002.port.Q_flow = 0.0; TsCABI0CabiA011001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011001002.port.T); TsCABI0CabiA011001002.port.Q_flow = 0.0; TsCABI0CabiA012001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012001002.port.T); TsCABI0CabiA012001002.port.Q_flow = 0.0; TsCABI0CabiA013001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013001002.port.T); TsCABI0CabiA013001002.port.Q_flow = 0.0; TsCABI0CabiA001002002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001002002.port.T); TsCABI0CabiA001002002.port.Q_flow = 0.0; TsCABI0CabiA013002002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013002002.port.T); TsCABI0CabiA013002002.port.Q_flow = 0.0; TsCABI0CabiA001003002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001003002.port.T); TsCABI0CabiA001003002.port.Q_flow = 0.0; TsCABI0CabiA013003002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013003002.port.T); TsCABI0CabiA013003002.port.Q_flow = 0.0; TsCABI0CabiA001004002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001004002.port.T); TsCABI0CabiA001004002.port.Q_flow = 0.0; TsCABI0CabiA013004002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013004002.port.T); TsCABI0CabiA013004002.port.Q_flow = 0.0; TsCABI0CabiA001005002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001005002.port.T); TsCABI0CabiA001005002.port.Q_flow = 0.0; TsCABI0CabiA013005002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013005002.port.T); TsCABI0CabiA013005002.port.Q_flow = 0.0; TsCABI0CabiA001006002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001006002.port.T); TsCABI0CabiA001006002.port.Q_flow = 0.0; TsCABI0CabiA013006002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013006002.port.T); TsCABI0CabiA013006002.port.Q_flow = 0.0; TsCABI0CabiA001007002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001007002.port.T); TsCABI0CabiA001007002.port.Q_flow = 0.0; TsCABI0CabiA013007002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013007002.port.T); TsCABI0CabiA013007002.port.Q_flow = 0.0; TsCABI0CabiA001008002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001008002.port.T); TsCABI0CabiA001008002.port.Q_flow = 0.0; TsCABI0CabiA013008002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013008002.port.T); TsCABI0CabiA013008002.port.Q_flow = 0.0; TsCABI0CabiA001009002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001009002.port.T); TsCABI0CabiA001009002.port.Q_flow = 0.0; TsCABI0CabiA013009002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013009002.port.T); TsCABI0CabiA013009002.port.Q_flow = 0.0; TsCABI0CabiA001010002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001010002.port.T); TsCABI0CabiA001010002.port.Q_flow = 0.0; TsCABI0CabiA013010002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013010002.port.T); TsCABI0CabiA013010002.port.Q_flow = 0.0; TsCABI0CabiA001011002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001011002.port.T); TsCABI0CabiA001011002.port.Q_flow = 0.0; TsCABI0CabiA013011002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013011002.port.T); TsCABI0CabiA013011002.port.Q_flow = 0.0; TsCABI0CabiA001012002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001012002.port.T); TsCABI0CabiA001012002.port.Q_flow = 0.0; TsCABI0CabiA013012002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013012002.port.T); TsCABI0CabiA013012002.port.Q_flow = 0.0; TsCABI0CabiA001013002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001013002.port.T); TsCABI0CabiA001013002.port.Q_flow = 0.0; TsCABI0CabiA013013002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013013002.port.T); TsCABI0CabiA013013002.port.Q_flow = 0.0; TsCABI0CabiA001014002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001014002.port.T); TsCABI0CabiA001014002.port.Q_flow = 0.0; TsCABI0CabiA013014002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013014002.port.T); TsCABI0CabiA013014002.port.Q_flow = 0.0; TsCABI0CabiA001015002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001015002.port.T); TsCABI0CabiA001015002.port.Q_flow = 0.0; TsCABI0CabiA013015002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013015002.port.T); TsCABI0CabiA013015002.port.Q_flow = 0.0; TsCABI0CabiA001016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001016002.port.T); TsCABI0CabiA001016002.port.Q_flow = 0.0; TsCABI0CabiA002016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002016002.port.T); TsCABI0CabiA002016002.port.Q_flow = 0.0; TsCABI0CabiA003016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003016002.port.T); TsCABI0CabiA003016002.port.Q_flow = 0.0; TsCABI0CabiA004016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004016002.port.T); TsCABI0CabiA004016002.port.Q_flow = 0.0; TsCABI0CabiA005016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005016002.port.T); TsCABI0CabiA005016002.port.Q_flow = 0.0; TsCABI0CabiA006016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006016002.port.T); TsCABI0CabiA006016002.port.Q_flow = 0.0; TsCABI0CabiA007016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007016002.port.T); TsCABI0CabiA007016002.port.Q_flow = 0.0; TsCABI0CabiA008016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008016002.port.T); TsCABI0CabiA008016002.port.Q_flow = 0.0; TsCABI0CabiA009016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009016002.port.T); TsCABI0CabiA009016002.port.Q_flow = 0.0; TsCABI0CabiA010016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010016002.port.T); TsCABI0CabiA010016002.port.Q_flow = 0.0; TsCABI0CabiA011016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011016002.port.T); TsCABI0CabiA011016002.port.Q_flow = 0.0; TsCABI0CabiA012016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012016002.port.T); TsCABI0CabiA012016002.port.Q_flow = 0.0; TsCABI0CabiA013016002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013016002.port.T); TsCABI0CabiA013016002.port.Q_flow = 0.0; TsCABI0CabiA001001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001001005.port.T); TsCABI0CabiA001001005.port.Q_flow = 0.0; TsCABI0CabiA002001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002001005.port.T); TsCABI0CabiA002001005.port.Q_flow = 0.0; TsCABI0CabiA003001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003001005.port.T); TsCABI0CabiA003001005.port.Q_flow = 0.0; TsCABI0CabiA004001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004001005.port.T); TsCABI0CabiA004001005.port.Q_flow = 0.0; TsCABI0CabiA005001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005001005.port.T); TsCABI0CabiA005001005.port.Q_flow = 0.0; TsCABI0CabiA006001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006001005.port.T); TsCABI0CabiA006001005.port.Q_flow = 0.0; TsCABI0CabiA007001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007001005.port.T); TsCABI0CabiA007001005.port.Q_flow = 0.0; TsCABI0CabiA008001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008001005.port.T); TsCABI0CabiA008001005.port.Q_flow = 0.0; TsCABI0CabiA009001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009001005.port.T); TsCABI0CabiA009001005.port.Q_flow = 0.0; TsCABI0CabiA010001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010001005.port.T); TsCABI0CabiA010001005.port.Q_flow = 0.0; TsCABI0CabiA011001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011001005.port.T); TsCABI0CabiA011001005.port.Q_flow = 0.0; TsCABI0CabiA012001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012001005.port.T); TsCABI0CabiA012001005.port.Q_flow = 0.0; TsCABI0CabiA013001005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013001005.port.T); TsCABI0CabiA013001005.port.Q_flow = 0.0; TsCABI0CabiA001002005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001002005.port.T); TsCABI0CabiA001002005.port.Q_flow = 0.0; TsCABI0CabiA013002005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013002005.port.T); TsCABI0CabiA013002005.port.Q_flow = 0.0; TsCABI0CabiA001003005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001003005.port.T); TsCABI0CabiA001003005.port.Q_flow = 0.0; TsCABI0CabiA013003005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013003005.port.T); TsCABI0CabiA013003005.port.Q_flow = 0.0; TsCABI0CabiA001004005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001004005.port.T); TsCABI0CabiA001004005.port.Q_flow = 0.0; TsCABI0CabiA013004005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013004005.port.T); TsCABI0CabiA013004005.port.Q_flow = 0.0; TsCABI0CabiA001005005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001005005.port.T); TsCABI0CabiA001005005.port.Q_flow = 0.0; TsCABI0CabiA013005005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013005005.port.T); TsCABI0CabiA013005005.port.Q_flow = 0.0; TsCABI0CabiA001006005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001006005.port.T); TsCABI0CabiA001006005.port.Q_flow = 0.0; TsCABI0CabiA013006005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013006005.port.T); TsCABI0CabiA013006005.port.Q_flow = 0.0; TsCABI0CabiA001007005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001007005.port.T); TsCABI0CabiA001007005.port.Q_flow = 0.0; TsCABI0CabiA013007005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013007005.port.T); TsCABI0CabiA013007005.port.Q_flow = 0.0; TsCABI0CabiA001008005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001008005.port.T); TsCABI0CabiA001008005.port.Q_flow = 0.0; TsCABI0CabiA013008005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013008005.port.T); TsCABI0CabiA013008005.port.Q_flow = 0.0; TsCABI0CabiA001009005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001009005.port.T); TsCABI0CabiA001009005.port.Q_flow = 0.0; TsCABI0CabiA013009005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013009005.port.T); TsCABI0CabiA013009005.port.Q_flow = 0.0; TsCABI0CabiA001010005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001010005.port.T); TsCABI0CabiA001010005.port.Q_flow = 0.0; TsCABI0CabiA013010005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013010005.port.T); TsCABI0CabiA013010005.port.Q_flow = 0.0; TsCABI0CabiA001011005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001011005.port.T); TsCABI0CabiA001011005.port.Q_flow = 0.0; TsCABI0CabiA013011005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013011005.port.T); TsCABI0CabiA013011005.port.Q_flow = 0.0; TsCABI0CabiA001012005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001012005.port.T); TsCABI0CabiA001012005.port.Q_flow = 0.0; TsCABI0CabiA013012005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013012005.port.T); TsCABI0CabiA013012005.port.Q_flow = 0.0; TsCABI0CabiA001013005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001013005.port.T); TsCABI0CabiA001013005.port.Q_flow = 0.0; TsCABI0CabiA013013005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013013005.port.T); TsCABI0CabiA013013005.port.Q_flow = 0.0; TsCABI0CabiA001014005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001014005.port.T); TsCABI0CabiA001014005.port.Q_flow = 0.0; TsCABI0CabiA013014005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013014005.port.T); TsCABI0CabiA013014005.port.Q_flow = 0.0; TsCABI0CabiA001015005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001015005.port.T); TsCABI0CabiA001015005.port.Q_flow = 0.0; TsCABI0CabiA013015005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013015005.port.T); TsCABI0CabiA013015005.port.Q_flow = 0.0; TsCABI0CabiA001016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001016005.port.T); TsCABI0CabiA001016005.port.Q_flow = 0.0; TsCABI0CabiA002016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002016005.port.T); TsCABI0CabiA002016005.port.Q_flow = 0.0; TsCABI0CabiA003016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003016005.port.T); TsCABI0CabiA003016005.port.Q_flow = 0.0; TsCABI0CabiA004016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004016005.port.T); TsCABI0CabiA004016005.port.Q_flow = 0.0; TsCABI0CabiA005016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005016005.port.T); TsCABI0CabiA005016005.port.Q_flow = 0.0; TsCABI0CabiA006016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006016005.port.T); TsCABI0CabiA006016005.port.Q_flow = 0.0; TsCABI0CabiA007016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007016005.port.T); TsCABI0CabiA007016005.port.Q_flow = 0.0; TsCABI0CabiA008016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008016005.port.T); TsCABI0CabiA008016005.port.Q_flow = 0.0; TsCABI0CabiA009016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009016005.port.T); TsCABI0CabiA009016005.port.Q_flow = 0.0; TsCABI0CabiA010016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010016005.port.T); TsCABI0CabiA010016005.port.Q_flow = 0.0; TsCABI0CabiA011016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011016005.port.T); TsCABI0CabiA011016005.port.Q_flow = 0.0; TsCABI0CabiA012016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012016005.port.T); TsCABI0CabiA012016005.port.Q_flow = 0.0; TsCABI0CabiA013016005.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013016005.port.T); TsCABI0CabiA013016005.port.Q_flow = 0.0; TsCABI0CabiA001001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001001004.port.T); TsCABI0CabiA001001004.port.Q_flow = 0.0; TsCABI0CabiA002001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002001004.port.T); TsCABI0CabiA002001004.port.Q_flow = 0.0; TsCABI0CabiA003001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003001004.port.T); TsCABI0CabiA003001004.port.Q_flow = 0.0; TsCABI0CabiA004001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004001004.port.T); TsCABI0CabiA004001004.port.Q_flow = 0.0; TsCABI0CabiA005001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005001004.port.T); TsCABI0CabiA005001004.port.Q_flow = 0.0; TsCABI0CabiA006001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006001004.port.T); TsCABI0CabiA006001004.port.Q_flow = 0.0; TsCABI0CabiA007001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007001004.port.T); TsCABI0CabiA007001004.port.Q_flow = 0.0; TsCABI0CabiA008001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008001004.port.T); TsCABI0CabiA008001004.port.Q_flow = 0.0; TsCABI0CabiA009001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009001004.port.T); TsCABI0CabiA009001004.port.Q_flow = 0.0; TsCABI0CabiA010001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010001004.port.T); TsCABI0CabiA010001004.port.Q_flow = 0.0; TsCABI0CabiA011001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011001004.port.T); TsCABI0CabiA011001004.port.Q_flow = 0.0; TsCABI0CabiA012001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012001004.port.T); TsCABI0CabiA012001004.port.Q_flow = 0.0; TsCABI0CabiA013001004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013001004.port.T); TsCABI0CabiA013001004.port.Q_flow = 0.0; TsCABI0CabiA001002004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001002004.port.T); TsCABI0CabiA001002004.port.Q_flow = 0.0; TsCABI0CabiA013002004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013002004.port.T); TsCABI0CabiA013002004.port.Q_flow = 0.0; TsCABI0CabiA001003004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001003004.port.T); TsCABI0CabiA001003004.port.Q_flow = 0.0; TsCABI0CabiA013003004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013003004.port.T); TsCABI0CabiA013003004.port.Q_flow = 0.0; TsCABI0CabiA001004004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001004004.port.T); TsCABI0CabiA001004004.port.Q_flow = 0.0; TsCABI0CabiA013004004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013004004.port.T); TsCABI0CabiA013004004.port.Q_flow = 0.0; TsCABI0CabiA001005004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001005004.port.T); TsCABI0CabiA001005004.port.Q_flow = 0.0; TsCABI0CabiA013005004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013005004.port.T); TsCABI0CabiA013005004.port.Q_flow = 0.0; TsCABI0CabiA001006004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001006004.port.T); TsCABI0CabiA001006004.port.Q_flow = 0.0; TsCABI0CabiA013006004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013006004.port.T); TsCABI0CabiA013006004.port.Q_flow = 0.0; TsCABI0CabiA001007004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001007004.port.T); TsCABI0CabiA001007004.port.Q_flow = 0.0; TsCABI0CabiA013007004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013007004.port.T); TsCABI0CabiA013007004.port.Q_flow = 0.0; TsCABI0CabiA001008004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001008004.port.T); TsCABI0CabiA001008004.port.Q_flow = 0.0; TsCABI0CabiA013008004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013008004.port.T); TsCABI0CabiA013008004.port.Q_flow = 0.0; TsCABI0CabiA001009004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001009004.port.T); TsCABI0CabiA001009004.port.Q_flow = 0.0; TsCABI0CabiA013009004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013009004.port.T); TsCABI0CabiA013009004.port.Q_flow = 0.0; TsCABI0CabiA001010004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001010004.port.T); TsCABI0CabiA001010004.port.Q_flow = 0.0; TsCABI0CabiA013010004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013010004.port.T); TsCABI0CabiA013010004.port.Q_flow = 0.0; TsCABI0CabiA001011004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001011004.port.T); TsCABI0CabiA001011004.port.Q_flow = 0.0; TsCABI0CabiA013011004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013011004.port.T); TsCABI0CabiA013011004.port.Q_flow = 0.0; TsCABI0CabiA001012004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001012004.port.T); TsCABI0CabiA001012004.port.Q_flow = 0.0; TsCABI0CabiA013012004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013012004.port.T); TsCABI0CabiA013012004.port.Q_flow = 0.0; TsCABI0CabiA001013004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001013004.port.T); TsCABI0CabiA001013004.port.Q_flow = 0.0; TsCABI0CabiA013013004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013013004.port.T); TsCABI0CabiA013013004.port.Q_flow = 0.0; TsCABI0CabiA001014004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001014004.port.T); TsCABI0CabiA001014004.port.Q_flow = 0.0; TsCABI0CabiA013014004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013014004.port.T); TsCABI0CabiA013014004.port.Q_flow = 0.0; TsCABI0CabiA001015004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001015004.port.T); TsCABI0CabiA001015004.port.Q_flow = 0.0; TsCABI0CabiA013015004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013015004.port.T); TsCABI0CabiA013015004.port.Q_flow = 0.0; TsCABI0CabiA001016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001016004.port.T); TsCABI0CabiA001016004.port.Q_flow = 0.0; TsCABI0CabiA002016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002016004.port.T); TsCABI0CabiA002016004.port.Q_flow = 0.0; TsCABI0CabiA003016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003016004.port.T); TsCABI0CabiA003016004.port.Q_flow = 0.0; TsCABI0CabiA004016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004016004.port.T); TsCABI0CabiA004016004.port.Q_flow = 0.0; TsCABI0CabiA005016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005016004.port.T); TsCABI0CabiA005016004.port.Q_flow = 0.0; TsCABI0CabiA006016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006016004.port.T); TsCABI0CabiA006016004.port.Q_flow = 0.0; TsCABI0CabiA007016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007016004.port.T); TsCABI0CabiA007016004.port.Q_flow = 0.0; TsCABI0CabiA008016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008016004.port.T); TsCABI0CabiA008016004.port.Q_flow = 0.0; TsCABI0CabiA009016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009016004.port.T); TsCABI0CabiA009016004.port.Q_flow = 0.0; TsCABI0CabiA010016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010016004.port.T); TsCABI0CabiA010016004.port.Q_flow = 0.0; TsCABI0CabiA011016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011016004.port.T); TsCABI0CabiA011016004.port.Q_flow = 0.0; TsCABI0CabiA012016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012016004.port.T); TsCABI0CabiA012016004.port.Q_flow = 0.0; TsCABI0CabiA013016004.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013016004.port.T); TsCABI0CabiA013016004.port.Q_flow = 0.0; TsCABI0CabiA001001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001001003.port.T); TsCABI0CabiA001001003.port.Q_flow = 0.0; TsCABI0CabiA002001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002001003.port.T); TsCABI0CabiA002001003.port.Q_flow = 0.0; TsCABI0CabiA003001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003001003.port.T); TsCABI0CabiA003001003.port.Q_flow = 0.0; TsCABI0CabiA004001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004001003.port.T); TsCABI0CabiA004001003.port.Q_flow = 0.0; TsCABI0CabiA005001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005001003.port.T); TsCABI0CabiA005001003.port.Q_flow = 0.0; TsCABI0CabiA006001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006001003.port.T); TsCABI0CabiA006001003.port.Q_flow = 0.0; TsCABI0CabiA007001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007001003.port.T); TsCABI0CabiA007001003.port.Q_flow = 0.0; TsCABI0CabiA008001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008001003.port.T); TsCABI0CabiA008001003.port.Q_flow = 0.0; TsCABI0CabiA009001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009001003.port.T); TsCABI0CabiA009001003.port.Q_flow = 0.0; TsCABI0CabiA010001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010001003.port.T); TsCABI0CabiA010001003.port.Q_flow = 0.0; TsCABI0CabiA011001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011001003.port.T); TsCABI0CabiA011001003.port.Q_flow = 0.0; TsCABI0CabiA012001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012001003.port.T); TsCABI0CabiA012001003.port.Q_flow = 0.0; TsCABI0CabiA013001003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013001003.port.T); TsCABI0CabiA013001003.port.Q_flow = 0.0; TsCABI0CabiA001002003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001002003.port.T); TsCABI0CabiA001002003.port.Q_flow = 0.0; TsCABI0CabiA013002003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013002003.port.T); TsCABI0CabiA013002003.port.Q_flow = 0.0; TsCABI0CabiA001003003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001003003.port.T); TsCABI0CabiA001003003.port.Q_flow = 0.0; TsCABI0CabiA013003003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013003003.port.T); TsCABI0CabiA013003003.port.Q_flow = 0.0; TsCABI0CabiA001004003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001004003.port.T); TsCABI0CabiA001004003.port.Q_flow = 0.0; TsCABI0CabiA013004003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013004003.port.T); TsCABI0CabiA013004003.port.Q_flow = 0.0; TsCABI0CabiA001005003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001005003.port.T); TsCABI0CabiA001005003.port.Q_flow = 0.0; TsCABI0CabiA013005003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013005003.port.T); TsCABI0CabiA013005003.port.Q_flow = 0.0; TsCABI0CabiA001006003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001006003.port.T); TsCABI0CabiA001006003.port.Q_flow = 0.0; TsCABI0CabiA013006003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013006003.port.T); TsCABI0CabiA013006003.port.Q_flow = 0.0; TsCABI0CabiA001007003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001007003.port.T); TsCABI0CabiA001007003.port.Q_flow = 0.0; TsCABI0CabiA013007003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013007003.port.T); TsCABI0CabiA013007003.port.Q_flow = 0.0; TsCABI0CabiA001008003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001008003.port.T); TsCABI0CabiA001008003.port.Q_flow = 0.0; TsCABI0CabiA013008003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013008003.port.T); TsCABI0CabiA013008003.port.Q_flow = 0.0; TsCABI0CabiA001009003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001009003.port.T); TsCABI0CabiA001009003.port.Q_flow = 0.0; TsCABI0CabiA013009003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013009003.port.T); TsCABI0CabiA013009003.port.Q_flow = 0.0; TsCABI0CabiA001010003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001010003.port.T); TsCABI0CabiA001010003.port.Q_flow = 0.0; TsCABI0CabiA013010003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013010003.port.T); TsCABI0CabiA013010003.port.Q_flow = 0.0; TsCABI0CabiA001011003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001011003.port.T); TsCABI0CabiA001011003.port.Q_flow = 0.0; TsCABI0CabiA013011003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013011003.port.T); TsCABI0CabiA013011003.port.Q_flow = 0.0; TsCABI0CabiA001012003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001012003.port.T); TsCABI0CabiA001012003.port.Q_flow = 0.0; TsCABI0CabiA013012003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013012003.port.T); TsCABI0CabiA013012003.port.Q_flow = 0.0; TsCABI0CabiA001013003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001013003.port.T); TsCABI0CabiA001013003.port.Q_flow = 0.0; TsCABI0CabiA013013003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013013003.port.T); TsCABI0CabiA013013003.port.Q_flow = 0.0; TsCABI0CabiA001014003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001014003.port.T); TsCABI0CabiA001014003.port.Q_flow = 0.0; TsCABI0CabiA013014003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013014003.port.T); TsCABI0CabiA013014003.port.Q_flow = 0.0; TsCABI0CabiA001015003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001015003.port.T); TsCABI0CabiA001015003.port.Q_flow = 0.0; TsCABI0CabiA013015003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013015003.port.T); TsCABI0CabiA013015003.port.Q_flow = 0.0; TsCABI0CabiA001016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001016003.port.T); TsCABI0CabiA001016003.port.Q_flow = 0.0; TsCABI0CabiA002016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002016003.port.T); TsCABI0CabiA002016003.port.Q_flow = 0.0; TsCABI0CabiA003016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003016003.port.T); TsCABI0CabiA003016003.port.Q_flow = 0.0; TsCABI0CabiA004016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004016003.port.T); TsCABI0CabiA004016003.port.Q_flow = 0.0; TsCABI0CabiA005016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005016003.port.T); TsCABI0CabiA005016003.port.Q_flow = 0.0; TsCABI0CabiA006016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006016003.port.T); TsCABI0CabiA006016003.port.Q_flow = 0.0; TsCABI0CabiA007016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007016003.port.T); TsCABI0CabiA007016003.port.Q_flow = 0.0; TsCABI0CabiA008016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008016003.port.T); TsCABI0CabiA008016003.port.Q_flow = 0.0; TsCABI0CabiA009016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009016003.port.T); TsCABI0CabiA009016003.port.Q_flow = 0.0; TsCABI0CabiA010016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010016003.port.T); TsCABI0CabiA010016003.port.Q_flow = 0.0; TsCABI0CabiA011016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011016003.port.T); TsCABI0CabiA011016003.port.Q_flow = 0.0; TsCABI0CabiA012016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012016003.port.T); TsCABI0CabiA012016003.port.Q_flow = 0.0; TsCABI0CabiA013016003.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013016003.port.T); TsCABI0CabiA013016003.port.Q_flow = 0.0; TsCABI0CabiA001001002.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001001002.port.T); TsCABI0CabiA001001002.port.Q_flow = 0.0; TsCABI0CabiA001001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001001006.port.T); TsCABI0CabiA001001006.port.Q_flow = 0.0; TsCABI0CabiA002001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002001006.port.T); TsCABI0CabiA002001006.port.Q_flow = 0.0; TsCABI0CabiA003001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003001006.port.T); TsCABI0CabiA003001006.port.Q_flow = 0.0; TsCABI0CabiA004001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004001006.port.T); TsCABI0CabiA004001006.port.Q_flow = 0.0; TsCABI0CabiA005001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005001006.port.T); TsCABI0CabiA005001006.port.Q_flow = 0.0; TsCABI0CabiA006001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006001006.port.T); TsCABI0CabiA006001006.port.Q_flow = 0.0; TsCABI0CabiA007001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007001006.port.T); TsCABI0CabiA007001006.port.Q_flow = 0.0; TsCABI0CabiA008001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008001006.port.T); TsCABI0CabiA008001006.port.Q_flow = 0.0; TsCABI0CabiA009001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009001006.port.T); TsCABI0CabiA009001006.port.Q_flow = 0.0; TsCABI0CabiA010001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010001006.port.T); TsCABI0CabiA010001006.port.Q_flow = 0.0; TsCABI0CabiA011001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011001006.port.T); TsCABI0CabiA011001006.port.Q_flow = 0.0; TsCABI0CabiA012001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012001006.port.T); TsCABI0CabiA012001006.port.Q_flow = 0.0; TsCABI0CabiA013001006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013001006.port.T); TsCABI0CabiA013001006.port.Q_flow = 0.0; TsCABI0CabiA001002006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001002006.port.T); TsCABI0CabiA001002006.port.Q_flow = 0.0; TsCABI0CabiA013002006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013002006.port.T); TsCABI0CabiA013002006.port.Q_flow = 0.0; TsCABI0CabiA001003006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001003006.port.T); TsCABI0CabiA001003006.port.Q_flow = 0.0; TsCABI0CabiA013003006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013003006.port.T); TsCABI0CabiA013003006.port.Q_flow = 0.0; TsCABI0CabiA001004006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001004006.port.T); TsCABI0CabiA001004006.port.Q_flow = 0.0; TsCABI0CabiA013004006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013004006.port.T); TsCABI0CabiA013004006.port.Q_flow = 0.0; TsCABI0CabiA001005006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001005006.port.T); TsCABI0CabiA001005006.port.Q_flow = 0.0; TsCABI0CabiA013005006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013005006.port.T); TsCABI0CabiA013005006.port.Q_flow = 0.0; TsCABI0CabiA001006006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001006006.port.T); TsCABI0CabiA001006006.port.Q_flow = 0.0; TsCABI0CabiA013006006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013006006.port.T); TsCABI0CabiA013006006.port.Q_flow = 0.0; TsCABI0CabiA001007006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001007006.port.T); TsCABI0CabiA001007006.port.Q_flow = 0.0; TsCABI0CabiA013007006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013007006.port.T); TsCABI0CabiA013007006.port.Q_flow = 0.0; TsCABI0CabiA001008006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001008006.port.T); TsCABI0CabiA001008006.port.Q_flow = 0.0; TsCABI0CabiA013008006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013008006.port.T); TsCABI0CabiA013008006.port.Q_flow = 0.0; TsCABI0CabiA001009006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001009006.port.T); TsCABI0CabiA001009006.port.Q_flow = 0.0; TsCABI0CabiA013009006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013009006.port.T); TsCABI0CabiA013009006.port.Q_flow = 0.0; TsCABI0CabiA001010006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001010006.port.T); TsCABI0CabiA001010006.port.Q_flow = 0.0; TsCABI0CabiA013010006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013010006.port.T); TsCABI0CabiA013010006.port.Q_flow = 0.0; TsCABI0CabiA001011006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001011006.port.T); TsCABI0CabiA001011006.port.Q_flow = 0.0; TsCABI0CabiA013011006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013011006.port.T); TsCABI0CabiA013011006.port.Q_flow = 0.0; TsCABI0CabiA001012006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001012006.port.T); TsCABI0CabiA001012006.port.Q_flow = 0.0; TsCABI0CabiA013012006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013012006.port.T); TsCABI0CabiA013012006.port.Q_flow = 0.0; TsCABI0CabiA001013006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001013006.port.T); TsCABI0CabiA001013006.port.Q_flow = 0.0; TsCABI0CabiA013013006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013013006.port.T); TsCABI0CabiA013013006.port.Q_flow = 0.0; TsCABI0CabiA001014006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001014006.port.T); TsCABI0CabiA001014006.port.Q_flow = 0.0; TsCABI0CabiA013014006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013014006.port.T); TsCABI0CabiA013014006.port.Q_flow = 0.0; TsCABI0CabiA001015006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001015006.port.T); TsCABI0CabiA001015006.port.Q_flow = 0.0; TsCABI0CabiA013015006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013015006.port.T); TsCABI0CabiA013015006.port.Q_flow = 0.0; TsCABI0CabiA001016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001016006.port.T); TsCABI0CabiA001016006.port.Q_flow = 0.0; TsCABI0CabiA002016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002016006.port.T); TsCABI0CabiA002016006.port.Q_flow = 0.0; TsCABI0CabiA003016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003016006.port.T); TsCABI0CabiA003016006.port.Q_flow = 0.0; TsCABI0CabiA004016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004016006.port.T); TsCABI0CabiA004016006.port.Q_flow = 0.0; TsCABI0CabiA005016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005016006.port.T); TsCABI0CabiA005016006.port.Q_flow = 0.0; TsCABI0CabiA006016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006016006.port.T); TsCABI0CabiA006016006.port.Q_flow = 0.0; TsCABI0CabiA007016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007016006.port.T); TsCABI0CabiA007016006.port.Q_flow = 0.0; TsCABI0CabiA008016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008016006.port.T); TsCABI0CabiA008016006.port.Q_flow = 0.0; TsCABI0CabiA009016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009016006.port.T); TsCABI0CabiA009016006.port.Q_flow = 0.0; TsCABI0CabiA010016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010016006.port.T); TsCABI0CabiA010016006.port.Q_flow = 0.0; TsCABI0CabiA011016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011016006.port.T); TsCABI0CabiA011016006.port.Q_flow = 0.0; TsCABI0CabiA012016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012016006.port.T); TsCABI0CabiA012016006.port.Q_flow = 0.0; TsCABI0CabiA013016006.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013016006.port.T); TsCABI0CabiA013016006.port.Q_flow = 0.0; TsCABI0CabiA001001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001001007.port.T); TsCABI0CabiA001001007.port.Q_flow = 0.0; TsCABI0CabiA002001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002001007.port.T); TsCABI0CabiA002001007.port.Q_flow = 0.0; TsCABI0CabiA003001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003001007.port.T); TsCABI0CabiA003001007.port.Q_flow = 0.0; TsCABI0CabiA004001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004001007.port.T); TsCABI0CabiA004001007.port.Q_flow = 0.0; TsCABI0CabiA005001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005001007.port.T); TsCABI0CabiA005001007.port.Q_flow = 0.0; TsCABI0CabiA006001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006001007.port.T); TsCABI0CabiA006001007.port.Q_flow = 0.0; TsCABI0CabiA007001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007001007.port.T); TsCABI0CabiA007001007.port.Q_flow = 0.0; TsCABI0CabiA008001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008001007.port.T); TsCABI0CabiA008001007.port.Q_flow = 0.0; TsCABI0CabiA009001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009001007.port.T); TsCABI0CabiA009001007.port.Q_flow = 0.0; TsCABI0CabiA010001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010001007.port.T); TsCABI0CabiA010001007.port.Q_flow = 0.0; TsCABI0CabiA011001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011001007.port.T); TsCABI0CabiA011001007.port.Q_flow = 0.0; TsCABI0CabiA012001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012001007.port.T); TsCABI0CabiA012001007.port.Q_flow = 0.0; TsCABI0CabiA013001007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013001007.port.T); TsCABI0CabiA013001007.port.Q_flow = 0.0; TsCABI0CabiA001002007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001002007.port.T); TsCABI0CabiA001002007.port.Q_flow = 0.0; TsCABI0CabiA013002007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013002007.port.T); TsCABI0CabiA013002007.port.Q_flow = 0.0; TsCABI0CabiA001003007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001003007.port.T); TsCABI0CabiA001003007.port.Q_flow = 0.0; TsCABI0CabiA013003007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013003007.port.T); TsCABI0CabiA013003007.port.Q_flow = 0.0; TsCABI0CabiA001004007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001004007.port.T); TsCABI0CabiA001004007.port.Q_flow = 0.0; TsCABI0CabiA013004007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013004007.port.T); TsCABI0CabiA013004007.port.Q_flow = 0.0; TsCABI0CabiA001005007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001005007.port.T); TsCABI0CabiA001005007.port.Q_flow = 0.0; TsCABI0CabiA013005007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013005007.port.T); TsCABI0CabiA013005007.port.Q_flow = 0.0; TsCABI0CabiA001006007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001006007.port.T); TsCABI0CabiA001006007.port.Q_flow = 0.0; TsCABI0CabiA013006007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013006007.port.T); TsCABI0CabiA013006007.port.Q_flow = 0.0; TsCABI0CabiA001007007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001007007.port.T); TsCABI0CabiA001007007.port.Q_flow = 0.0; TsCABI0CabiA013007007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013007007.port.T); TsCABI0CabiA013007007.port.Q_flow = 0.0; TsCABI0CabiA001008007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001008007.port.T); TsCABI0CabiA001008007.port.Q_flow = 0.0; TsCABI0CabiA013008007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013008007.port.T); TsCABI0CabiA013008007.port.Q_flow = 0.0; TsCABI0CabiA001009007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001009007.port.T); TsCABI0CabiA001009007.port.Q_flow = 0.0; TsCABI0CabiA013009007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013009007.port.T); TsCABI0CabiA013009007.port.Q_flow = 0.0; TsCABI0CabiA001010007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001010007.port.T); TsCABI0CabiA001010007.port.Q_flow = 0.0; TsCABI0CabiA013010007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013010007.port.T); TsCABI0CabiA013010007.port.Q_flow = 0.0; TsCABI0CabiA001011007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001011007.port.T); TsCABI0CabiA001011007.port.Q_flow = 0.0; TsCABI0CabiA013011007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013011007.port.T); TsCABI0CabiA013011007.port.Q_flow = 0.0; TsCABI0CabiA001012007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001012007.port.T); TsCABI0CabiA001012007.port.Q_flow = 0.0; TsCABI0CabiA013012007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013012007.port.T); TsCABI0CabiA013012007.port.Q_flow = 0.0; TsCABI0CabiA001013007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001013007.port.T); TsCABI0CabiA001013007.port.Q_flow = 0.0; TsCABI0CabiA013013007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013013007.port.T); TsCABI0CabiA013013007.port.Q_flow = 0.0; TsCABI0CabiA001014007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001014007.port.T); TsCABI0CabiA001014007.port.Q_flow = 0.0; TsCABI0CabiA013014007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013014007.port.T); TsCABI0CabiA013014007.port.Q_flow = 0.0; TsCABI0CabiA001015007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001015007.port.T); TsCABI0CabiA001015007.port.Q_flow = 0.0; TsCABI0CabiA013015007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013015007.port.T); TsCABI0CabiA013015007.port.Q_flow = 0.0; TsCABI0CabiA001016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001016007.port.T); TsCABI0CabiA001016007.port.Q_flow = 0.0; TsCABI0CabiA002016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002016007.port.T); TsCABI0CabiA002016007.port.Q_flow = 0.0; TsCABI0CabiA003016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003016007.port.T); TsCABI0CabiA003016007.port.Q_flow = 0.0; TsCABI0CabiA004016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004016007.port.T); TsCABI0CabiA004016007.port.Q_flow = 0.0; TsCABI0CabiA005016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005016007.port.T); TsCABI0CabiA005016007.port.Q_flow = 0.0; TsCABI0CabiA006016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006016007.port.T); TsCABI0CabiA006016007.port.Q_flow = 0.0; TsCABI0CabiA007016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007016007.port.T); TsCABI0CabiA007016007.port.Q_flow = 0.0; TsCABI0CabiA008016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008016007.port.T); TsCABI0CabiA008016007.port.Q_flow = 0.0; TsCABI0CabiA009016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009016007.port.T); TsCABI0CabiA009016007.port.Q_flow = 0.0; TsCABI0CabiA010016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010016007.port.T); TsCABI0CabiA010016007.port.Q_flow = 0.0; TsCABI0CabiA011016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011016007.port.T); TsCABI0CabiA011016007.port.Q_flow = 0.0; TsCABI0CabiA012016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012016007.port.T); TsCABI0CabiA012016007.port.Q_flow = 0.0; TsCABI0CabiA013016007.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013016007.port.T); TsCABI0CabiA013016007.port.Q_flow = 0.0; TsCABI0CabiA001001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001001008.port.T); TsCABI0CabiA001001008.port.Q_flow = 0.0; TsCABI0CabiA002001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002001008.port.T); TsCABI0CabiA002001008.port.Q_flow = 0.0; TsCABI0CabiA003001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003001008.port.T); TsCABI0CabiA003001008.port.Q_flow = 0.0; TsCABI0CabiA004001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004001008.port.T); TsCABI0CabiA004001008.port.Q_flow = 0.0; TsCABI0CabiA005001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005001008.port.T); TsCABI0CabiA005001008.port.Q_flow = 0.0; TsCABI0CabiA006001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006001008.port.T); TsCABI0CabiA006001008.port.Q_flow = 0.0; TsCABI0CabiA007001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007001008.port.T); TsCABI0CabiA007001008.port.Q_flow = 0.0; TsCABI0CabiA008001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008001008.port.T); TsCABI0CabiA008001008.port.Q_flow = 0.0; TsCABI0CabiA009001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009001008.port.T); TsCABI0CabiA009001008.port.Q_flow = 0.0; TsCABI0CabiA010001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010001008.port.T); TsCABI0CabiA010001008.port.Q_flow = 0.0; TsCABI0CabiA011001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011001008.port.T); TsCABI0CabiA011001008.port.Q_flow = 0.0; TsCABI0CabiA012001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012001008.port.T); TsCABI0CabiA012001008.port.Q_flow = 0.0; TsCABI0CabiA013001008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013001008.port.T); TsCABI0CabiA013001008.port.Q_flow = 0.0; TsCABI0CabiA001002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001002008.port.T); TsCABI0CabiA001002008.port.Q_flow = 0.0; TsCABI0CabiA002002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002002008.port.T); TsCABI0CabiA002002008.port.Q_flow = 0.0; TsCABI0CabiA003002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003002008.port.T); TsCABI0CabiA003002008.port.Q_flow = 0.0; TsCABI0CabiA004002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004002008.port.T); TsCABI0CabiA004002008.port.Q_flow = 0.0; TsCABI0CabiA005002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005002008.port.T); TsCABI0CabiA005002008.port.Q_flow = 0.0; TsCABI0CabiA006002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006002008.port.T); TsCABI0CabiA006002008.port.Q_flow = 0.0; TsCABI0CabiA007002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007002008.port.T); TsCABI0CabiA007002008.port.Q_flow = 0.0; TsCABI0CabiA008002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008002008.port.T); TsCABI0CabiA008002008.port.Q_flow = 0.0; TsCABI0CabiA009002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009002008.port.T); TsCABI0CabiA009002008.port.Q_flow = 0.0; TsCABI0CabiA010002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010002008.port.T); TsCABI0CabiA010002008.port.Q_flow = 0.0; TsCABI0CabiA011002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011002008.port.T); TsCABI0CabiA011002008.port.Q_flow = 0.0; TsCABI0CabiA012002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012002008.port.T); TsCABI0CabiA012002008.port.Q_flow = 0.0; TsCABI0CabiA013002008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013002008.port.T); TsCABI0CabiA013002008.port.Q_flow = 0.0; TsCABI0CabiA001003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001003008.port.T); TsCABI0CabiA001003008.port.Q_flow = 0.0; TsCABI0CabiA002003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002003008.port.T); TsCABI0CabiA002003008.port.Q_flow = 0.0; TsCABI0CabiA003003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003003008.port.T); TsCABI0CabiA003003008.port.Q_flow = 0.0; TsCABI0CabiA004003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004003008.port.T); TsCABI0CabiA004003008.port.Q_flow = 0.0; TsCABI0CabiA005003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005003008.port.T); TsCABI0CabiA005003008.port.Q_flow = 0.0; TsCABI0CabiA006003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006003008.port.T); TsCABI0CabiA006003008.port.Q_flow = 0.0; TsCABI0CabiA007003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007003008.port.T); TsCABI0CabiA007003008.port.Q_flow = 0.0; TsCABI0CabiA008003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008003008.port.T); TsCABI0CabiA008003008.port.Q_flow = 0.0; TsCABI0CabiA009003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009003008.port.T); TsCABI0CabiA009003008.port.Q_flow = 0.0; TsCABI0CabiA010003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010003008.port.T); TsCABI0CabiA010003008.port.Q_flow = 0.0; TsCABI0CabiA011003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011003008.port.T); TsCABI0CabiA011003008.port.Q_flow = 0.0; TsCABI0CabiA012003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012003008.port.T); TsCABI0CabiA012003008.port.Q_flow = 0.0; TsCABI0CabiA013003008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013003008.port.T); TsCABI0CabiA013003008.port.Q_flow = 0.0; TsCABI0CabiA001004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001004008.port.T); TsCABI0CabiA001004008.port.Q_flow = 0.0; TsCABI0CabiA002004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002004008.port.T); TsCABI0CabiA002004008.port.Q_flow = 0.0; TsCABI0CabiA003004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003004008.port.T); TsCABI0CabiA003004008.port.Q_flow = 0.0; TsCABI0CabiA004004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004004008.port.T); TsCABI0CabiA004004008.port.Q_flow = 0.0; TsCABI0CabiA005004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005004008.port.T); TsCABI0CabiA005004008.port.Q_flow = 0.0; TsCABI0CabiA006004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006004008.port.T); TsCABI0CabiA006004008.port.Q_flow = 0.0; TsCABI0CabiA007004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007004008.port.T); TsCABI0CabiA007004008.port.Q_flow = 0.0; TsCABI0CabiA008004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008004008.port.T); TsCABI0CabiA008004008.port.Q_flow = 0.0; TsCABI0CabiA009004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009004008.port.T); TsCABI0CabiA009004008.port.Q_flow = 0.0; TsCABI0CabiA010004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010004008.port.T); TsCABI0CabiA010004008.port.Q_flow = 0.0; TsCABI0CabiA011004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011004008.port.T); TsCABI0CabiA011004008.port.Q_flow = 0.0; TsCABI0CabiA012004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012004008.port.T); TsCABI0CabiA012004008.port.Q_flow = 0.0; TsCABI0CabiA013004008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013004008.port.T); TsCABI0CabiA013004008.port.Q_flow = 0.0; TsCABI0CabiA001005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001005008.port.T); TsCABI0CabiA001005008.port.Q_flow = 0.0; TsCABI0CabiA002005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002005008.port.T); TsCABI0CabiA002005008.port.Q_flow = 0.0; TsCABI0CabiA003005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003005008.port.T); TsCABI0CabiA003005008.port.Q_flow = 0.0; TsCABI0CabiA004005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004005008.port.T); TsCABI0CabiA004005008.port.Q_flow = 0.0; TsCABI0CabiA005005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005005008.port.T); TsCABI0CabiA005005008.port.Q_flow = 0.0; TsCABI0CabiA006005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006005008.port.T); TsCABI0CabiA006005008.port.Q_flow = 0.0; TsCABI0CabiA007005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007005008.port.T); TsCABI0CabiA007005008.port.Q_flow = 0.0; TsCABI0CabiA008005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008005008.port.T); TsCABI0CabiA008005008.port.Q_flow = 0.0; TsCABI0CabiA009005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009005008.port.T); TsCABI0CabiA009005008.port.Q_flow = 0.0; TsCABI0CabiA010005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010005008.port.T); TsCABI0CabiA010005008.port.Q_flow = 0.0; TsCABI0CabiA011005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011005008.port.T); TsCABI0CabiA011005008.port.Q_flow = 0.0; TsCABI0CabiA012005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012005008.port.T); TsCABI0CabiA012005008.port.Q_flow = 0.0; TsCABI0CabiA013005008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013005008.port.T); TsCABI0CabiA013005008.port.Q_flow = 0.0; TsCABI0CabiA001006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001006008.port.T); TsCABI0CabiA001006008.port.Q_flow = 0.0; TsCABI0CabiA002006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002006008.port.T); TsCABI0CabiA002006008.port.Q_flow = 0.0; TsCABI0CabiA003006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003006008.port.T); TsCABI0CabiA003006008.port.Q_flow = 0.0; TsCABI0CabiA004006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004006008.port.T); TsCABI0CabiA004006008.port.Q_flow = 0.0; TsCABI0CabiA005006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005006008.port.T); TsCABI0CabiA005006008.port.Q_flow = 0.0; TsCABI0CabiA006006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006006008.port.T); TsCABI0CabiA006006008.port.Q_flow = 0.0; TsCABI0CabiA007006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007006008.port.T); TsCABI0CabiA007006008.port.Q_flow = 0.0; TsCABI0CabiA008006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008006008.port.T); TsCABI0CabiA008006008.port.Q_flow = 0.0; TsCABI0CabiA009006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009006008.port.T); TsCABI0CabiA009006008.port.Q_flow = 0.0; TsCABI0CabiA010006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010006008.port.T); TsCABI0CabiA010006008.port.Q_flow = 0.0; TsCABI0CabiA011006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011006008.port.T); TsCABI0CabiA011006008.port.Q_flow = 0.0; TsCABI0CabiA012006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012006008.port.T); TsCABI0CabiA012006008.port.Q_flow = 0.0; TsCABI0CabiA013006008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013006008.port.T); TsCABI0CabiA013006008.port.Q_flow = 0.0; TsCABI0CabiA001007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001007008.port.T); TsCABI0CabiA001007008.port.Q_flow = 0.0; TsCABI0CabiA002007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002007008.port.T); TsCABI0CabiA002007008.port.Q_flow = 0.0; TsCABI0CabiA003007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003007008.port.T); TsCABI0CabiA003007008.port.Q_flow = 0.0; TsCABI0CabiA004007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004007008.port.T); TsCABI0CabiA004007008.port.Q_flow = 0.0; TsCABI0CabiA005007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005007008.port.T); TsCABI0CabiA005007008.port.Q_flow = 0.0; TsCABI0CabiA006007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006007008.port.T); TsCABI0CabiA006007008.port.Q_flow = 0.0; TsCABI0CabiA007007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007007008.port.T); TsCABI0CabiA007007008.port.Q_flow = 0.0; TsCABI0CabiA008007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008007008.port.T); TsCABI0CabiA008007008.port.Q_flow = 0.0; TsCABI0CabiA009007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009007008.port.T); TsCABI0CabiA009007008.port.Q_flow = 0.0; TsCABI0CabiA010007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010007008.port.T); TsCABI0CabiA010007008.port.Q_flow = 0.0; TsCABI0CabiA011007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011007008.port.T); TsCABI0CabiA011007008.port.Q_flow = 0.0; TsCABI0CabiA012007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012007008.port.T); TsCABI0CabiA012007008.port.Q_flow = 0.0; TsCABI0CabiA013007008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013007008.port.T); TsCABI0CabiA013007008.port.Q_flow = 0.0; TsCABI0CabiA001008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001008008.port.T); TsCABI0CabiA001008008.port.Q_flow = 0.0; TsCABI0CabiA002008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002008008.port.T); TsCABI0CabiA002008008.port.Q_flow = 0.0; TsCABI0CabiA003008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003008008.port.T); TsCABI0CabiA003008008.port.Q_flow = 0.0; TsCABI0CabiA004008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004008008.port.T); TsCABI0CabiA004008008.port.Q_flow = 0.0; TsCABI0CabiA005008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005008008.port.T); TsCABI0CabiA005008008.port.Q_flow = 0.0; TsCABI0CabiA006008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006008008.port.T); TsCABI0CabiA006008008.port.Q_flow = 0.0; TsCABI0CabiA007008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007008008.port.T); TsCABI0CabiA007008008.port.Q_flow = 0.0; TsCABI0CabiA008008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008008008.port.T); TsCABI0CabiA008008008.port.Q_flow = 0.0; TsCABI0CabiA009008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009008008.port.T); TsCABI0CabiA009008008.port.Q_flow = 0.0; TsCABI0CabiA010008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010008008.port.T); TsCABI0CabiA010008008.port.Q_flow = 0.0; TsCABI0CabiA011008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011008008.port.T); TsCABI0CabiA011008008.port.Q_flow = 0.0; TsCABI0CabiA012008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012008008.port.T); TsCABI0CabiA012008008.port.Q_flow = 0.0; TsCABI0CabiA013008008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013008008.port.T); TsCABI0CabiA013008008.port.Q_flow = 0.0; TsCABI0CabiA001009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001009008.port.T); TsCABI0CabiA001009008.port.Q_flow = 0.0; TsCABI0CabiA002009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002009008.port.T); TsCABI0CabiA002009008.port.Q_flow = 0.0; TsCABI0CabiA003009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003009008.port.T); TsCABI0CabiA003009008.port.Q_flow = 0.0; TsCABI0CabiA004009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004009008.port.T); TsCABI0CabiA004009008.port.Q_flow = 0.0; TsCABI0CabiA005009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005009008.port.T); TsCABI0CabiA005009008.port.Q_flow = 0.0; TsCABI0CabiA006009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006009008.port.T); TsCABI0CabiA006009008.port.Q_flow = 0.0; TsCABI0CabiA007009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007009008.port.T); TsCABI0CabiA007009008.port.Q_flow = 0.0; TsCABI0CabiA008009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008009008.port.T); TsCABI0CabiA008009008.port.Q_flow = 0.0; TsCABI0CabiA009009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009009008.port.T); TsCABI0CabiA009009008.port.Q_flow = 0.0; TsCABI0CabiA010009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010009008.port.T); TsCABI0CabiA010009008.port.Q_flow = 0.0; TsCABI0CabiA011009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011009008.port.T); TsCABI0CabiA011009008.port.Q_flow = 0.0; TsCABI0CabiA012009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012009008.port.T); TsCABI0CabiA012009008.port.Q_flow = 0.0; TsCABI0CabiA013009008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013009008.port.T); TsCABI0CabiA013009008.port.Q_flow = 0.0; TsCABI0CabiA001010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001010008.port.T); TsCABI0CabiA001010008.port.Q_flow = 0.0; TsCABI0CabiA002010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002010008.port.T); TsCABI0CabiA002010008.port.Q_flow = 0.0; TsCABI0CabiA003010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003010008.port.T); TsCABI0CabiA003010008.port.Q_flow = 0.0; TsCABI0CabiA004010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004010008.port.T); TsCABI0CabiA004010008.port.Q_flow = 0.0; TsCABI0CabiA005010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005010008.port.T); TsCABI0CabiA005010008.port.Q_flow = 0.0; TsCABI0CabiA006010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006010008.port.T); TsCABI0CabiA006010008.port.Q_flow = 0.0; TsCABI0CabiA007010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007010008.port.T); TsCABI0CabiA007010008.port.Q_flow = 0.0; TsCABI0CabiA008010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008010008.port.T); TsCABI0CabiA008010008.port.Q_flow = 0.0; TsCABI0CabiA009010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009010008.port.T); TsCABI0CabiA009010008.port.Q_flow = 0.0; TsCABI0CabiA010010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010010008.port.T); TsCABI0CabiA010010008.port.Q_flow = 0.0; TsCABI0CabiA011010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011010008.port.T); TsCABI0CabiA011010008.port.Q_flow = 0.0; TsCABI0CabiA012010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012010008.port.T); TsCABI0CabiA012010008.port.Q_flow = 0.0; TsCABI0CabiA013010008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013010008.port.T); TsCABI0CabiA013010008.port.Q_flow = 0.0; TsCABI0CabiA001011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001011008.port.T); TsCABI0CabiA001011008.port.Q_flow = 0.0; TsCABI0CabiA002011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002011008.port.T); TsCABI0CabiA002011008.port.Q_flow = 0.0; TsCABI0CabiA003011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003011008.port.T); TsCABI0CabiA003011008.port.Q_flow = 0.0; TsCABI0CabiA004011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004011008.port.T); TsCABI0CabiA004011008.port.Q_flow = 0.0; TsCABI0CabiA005011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005011008.port.T); TsCABI0CabiA005011008.port.Q_flow = 0.0; TsCABI0CabiA006011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006011008.port.T); TsCABI0CabiA006011008.port.Q_flow = 0.0; TsCABI0CabiA007011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007011008.port.T); TsCABI0CabiA007011008.port.Q_flow = 0.0; TsCABI0CabiA008011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008011008.port.T); TsCABI0CabiA008011008.port.Q_flow = 0.0; TsCABI0CabiA009011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009011008.port.T); TsCABI0CabiA009011008.port.Q_flow = 0.0; TsCABI0CabiA010011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010011008.port.T); TsCABI0CabiA010011008.port.Q_flow = 0.0; TsCABI0CabiA011011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011011008.port.T); TsCABI0CabiA011011008.port.Q_flow = 0.0; TsCABI0CabiA012011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012011008.port.T); TsCABI0CabiA012011008.port.Q_flow = 0.0; TsCABI0CabiA013011008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013011008.port.T); TsCABI0CabiA013011008.port.Q_flow = 0.0; TsCABI0CabiA001012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001012008.port.T); TsCABI0CabiA001012008.port.Q_flow = 0.0; TsCABI0CabiA002012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002012008.port.T); TsCABI0CabiA002012008.port.Q_flow = 0.0; TsCABI0CabiA003012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003012008.port.T); TsCABI0CabiA003012008.port.Q_flow = 0.0; TsCABI0CabiA004012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004012008.port.T); TsCABI0CabiA004012008.port.Q_flow = 0.0; TsCABI0CabiA005012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005012008.port.T); TsCABI0CabiA005012008.port.Q_flow = 0.0; TsCABI0CabiA006012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006012008.port.T); TsCABI0CabiA006012008.port.Q_flow = 0.0; TsCABI0CabiA007012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007012008.port.T); TsCABI0CabiA007012008.port.Q_flow = 0.0; TsCABI0CabiA008012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008012008.port.T); TsCABI0CabiA008012008.port.Q_flow = 0.0; TsCABI0CabiA009012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009012008.port.T); TsCABI0CabiA009012008.port.Q_flow = 0.0; TsCABI0CabiA010012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010012008.port.T); TsCABI0CabiA010012008.port.Q_flow = 0.0; TsCABI0CabiA011012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011012008.port.T); TsCABI0CabiA011012008.port.Q_flow = 0.0; TsCABI0CabiA012012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012012008.port.T); TsCABI0CabiA012012008.port.Q_flow = 0.0; TsCABI0CabiA013012008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013012008.port.T); TsCABI0CabiA013012008.port.Q_flow = 0.0; TsCABI0CabiA001013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001013008.port.T); TsCABI0CabiA001013008.port.Q_flow = 0.0; TsCABI0CabiA002013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002013008.port.T); TsCABI0CabiA002013008.port.Q_flow = 0.0; TsCABI0CabiA003013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003013008.port.T); TsCABI0CabiA003013008.port.Q_flow = 0.0; TsCABI0CabiA004013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004013008.port.T); TsCABI0CabiA004013008.port.Q_flow = 0.0; TsCABI0CabiA005013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005013008.port.T); TsCABI0CabiA005013008.port.Q_flow = 0.0; TsCABI0CabiA006013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006013008.port.T); TsCABI0CabiA006013008.port.Q_flow = 0.0; TsCABI0CabiA007013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007013008.port.T); TsCABI0CabiA007013008.port.Q_flow = 0.0; TsCABI0CabiA008013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008013008.port.T); TsCABI0CabiA008013008.port.Q_flow = 0.0; TsCABI0CabiA009013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009013008.port.T); TsCABI0CabiA009013008.port.Q_flow = 0.0; TsCABI0CabiA010013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010013008.port.T); TsCABI0CabiA010013008.port.Q_flow = 0.0; TsCABI0CabiA011013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011013008.port.T); TsCABI0CabiA011013008.port.Q_flow = 0.0; TsCABI0CabiA012013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012013008.port.T); TsCABI0CabiA012013008.port.Q_flow = 0.0; TsCABI0CabiA013013008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013013008.port.T); TsCABI0CabiA013013008.port.Q_flow = 0.0; TsCABI0CabiA001014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001014008.port.T); TsCABI0CabiA001014008.port.Q_flow = 0.0; TsCABI0CabiA002014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002014008.port.T); TsCABI0CabiA002014008.port.Q_flow = 0.0; TsCABI0CabiA003014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003014008.port.T); TsCABI0CabiA003014008.port.Q_flow = 0.0; TsCABI0CabiA004014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004014008.port.T); TsCABI0CabiA004014008.port.Q_flow = 0.0; TsCABI0CabiA005014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005014008.port.T); TsCABI0CabiA005014008.port.Q_flow = 0.0; TsCABI0CabiA006014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006014008.port.T); TsCABI0CabiA006014008.port.Q_flow = 0.0; TsCABI0CabiA007014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007014008.port.T); TsCABI0CabiA007014008.port.Q_flow = 0.0; TsCABI0CabiA008014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008014008.port.T); TsCABI0CabiA008014008.port.Q_flow = 0.0; TsCABI0CabiA009014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009014008.port.T); TsCABI0CabiA009014008.port.Q_flow = 0.0; TsCABI0CabiA010014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010014008.port.T); TsCABI0CabiA010014008.port.Q_flow = 0.0; TsCABI0CabiA011014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011014008.port.T); TsCABI0CabiA011014008.port.Q_flow = 0.0; TsCABI0CabiA012014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012014008.port.T); TsCABI0CabiA012014008.port.Q_flow = 0.0; TsCABI0CabiA013014008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013014008.port.T); TsCABI0CabiA013014008.port.Q_flow = 0.0; TsCABI0CabiA001015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001015008.port.T); TsCABI0CabiA001015008.port.Q_flow = 0.0; TsCABI0CabiA002015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002015008.port.T); TsCABI0CabiA002015008.port.Q_flow = 0.0; TsCABI0CabiA003015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003015008.port.T); TsCABI0CabiA003015008.port.Q_flow = 0.0; TsCABI0CabiA004015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004015008.port.T); TsCABI0CabiA004015008.port.Q_flow = 0.0; TsCABI0CabiA005015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005015008.port.T); TsCABI0CabiA005015008.port.Q_flow = 0.0; TsCABI0CabiA006015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006015008.port.T); TsCABI0CabiA006015008.port.Q_flow = 0.0; TsCABI0CabiA007015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007015008.port.T); TsCABI0CabiA007015008.port.Q_flow = 0.0; TsCABI0CabiA008015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008015008.port.T); TsCABI0CabiA008015008.port.Q_flow = 0.0; TsCABI0CabiA009015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009015008.port.T); TsCABI0CabiA009015008.port.Q_flow = 0.0; TsCABI0CabiA010015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010015008.port.T); TsCABI0CabiA010015008.port.Q_flow = 0.0; TsCABI0CabiA011015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011015008.port.T); TsCABI0CabiA011015008.port.Q_flow = 0.0; TsCABI0CabiA012015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012015008.port.T); TsCABI0CabiA012015008.port.Q_flow = 0.0; TsCABI0CabiA013015008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013015008.port.T); TsCABI0CabiA013015008.port.Q_flow = 0.0; TsCABI0CabiA001016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA001016008.port.T); TsCABI0CabiA001016008.port.Q_flow = 0.0; TsCABI0CabiA002016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA002016008.port.T); TsCABI0CabiA002016008.port.Q_flow = 0.0; TsCABI0CabiA003016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA003016008.port.T); TsCABI0CabiA003016008.port.Q_flow = 0.0; TsCABI0CabiA004016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA004016008.port.T); TsCABI0CabiA004016008.port.Q_flow = 0.0; TsCABI0CabiA005016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA005016008.port.T); TsCABI0CabiA005016008.port.Q_flow = 0.0; TsCABI0CabiA006016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA006016008.port.T); TsCABI0CabiA006016008.port.Q_flow = 0.0; TsCABI0CabiA007016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA007016008.port.T); TsCABI0CabiA007016008.port.Q_flow = 0.0; TsCABI0CabiA008016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA008016008.port.T); TsCABI0CabiA008016008.port.Q_flow = 0.0; TsCABI0CabiA009016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA009016008.port.T); TsCABI0CabiA009016008.port.Q_flow = 0.0; TsCABI0CabiA010016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA010016008.port.T); TsCABI0CabiA010016008.port.Q_flow = 0.0; TsCABI0CabiA011016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA011016008.port.T); TsCABI0CabiA011016008.port.Q_flow = 0.0; TsCABI0CabiA012016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA012016008.port.T); TsCABI0CabiA012016008.port.Q_flow = 0.0; TsCABI0CabiA013016008.T = Modelica.SIunits.Conversions.to_degC(TsCABI0CabiA013016008.port.T); TsCABI0CabiA013016008.port.Q_flow = 0.0; TsGS0CabiA004005002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA004005002.port.T); TsGS0CabiA004005002.port.Q_flow = 0.0; TsGS0CabiA005005002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA005005002.port.T); TsGS0CabiA005005002.port.Q_flow = 0.0; TsGS0CabiA006005002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA006005002.port.T); TsGS0CabiA006005002.port.Q_flow = 0.0; TsGS0CabiA007005002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA007005002.port.T); TsGS0CabiA007005002.port.Q_flow = 0.0; TsGS0CabiA008005002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA008005002.port.T); TsGS0CabiA008005002.port.Q_flow = 0.0; TsGS0CabiA009005002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA009005002.port.T); TsGS0CabiA009005002.port.Q_flow = 0.0; TsGS0CabiA010005002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA010005002.port.T); TsGS0CabiA010005002.port.Q_flow = 0.0; TsGS0CabiA011005002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA011005002.port.T); TsGS0CabiA011005002.port.Q_flow = 0.0; TsGS0CabiA004006002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA004006002.port.T); TsGS0CabiA004006002.port.Q_flow = 0.0; TsGS0CabiA005006002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA005006002.port.T); TsGS0CabiA005006002.port.Q_flow = 0.0; TsGS0CabiA006006002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA006006002.port.T); TsGS0CabiA006006002.port.Q_flow = 0.0; TsGS0CabiA007006002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA007006002.port.T); TsGS0CabiA007006002.port.Q_flow = 0.0; TsGS0CabiA008006002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA008006002.port.T); TsGS0CabiA008006002.port.Q_flow = 0.0; TsGS0CabiA009006002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA009006002.port.T); TsGS0CabiA009006002.port.Q_flow = 0.0; TsGS0CabiA010006002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA010006002.port.T); TsGS0CabiA010006002.port.Q_flow = 0.0; TsGS0CabiA011006002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA011006002.port.T); TsGS0CabiA011006002.port.Q_flow = 0.0; TsGS0CabiA004007002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA004007002.port.T); TsGS0CabiA004007002.port.Q_flow = 0.0; TsGS0CabiA005007002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA005007002.port.T); TsGS0CabiA005007002.port.Q_flow = 0.0; TsGS0CabiA006007002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA006007002.port.T); TsGS0CabiA006007002.port.Q_flow = 0.0; TsGS0CabiA007007002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA007007002.port.T); TsGS0CabiA007007002.port.Q_flow = 0.0; TsGS0CabiA008007002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA008007002.port.T); TsGS0CabiA008007002.port.Q_flow = 0.0; TsGS0CabiA009007002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA009007002.port.T); TsGS0CabiA009007002.port.Q_flow = 0.0; TsGS0CabiA010007002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA010007002.port.T); TsGS0CabiA010007002.port.Q_flow = 0.0; TsGS0CabiA011007002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA011007002.port.T); TsGS0CabiA011007002.port.Q_flow = 0.0; TsGS0CabiA004008002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA004008002.port.T); TsGS0CabiA004008002.port.Q_flow = 0.0; TsGS0CabiA005008002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA005008002.port.T); TsGS0CabiA005008002.port.Q_flow = 0.0; TsGS0CabiA006008002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA006008002.port.T); TsGS0CabiA006008002.port.Q_flow = 0.0; TsGS0CabiA007008002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA007008002.port.T); TsGS0CabiA007008002.port.Q_flow = 0.0; TsGS0CabiA008008002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA008008002.port.T); TsGS0CabiA008008002.port.Q_flow = 0.0; TsGS0CabiA009008002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA009008002.port.T); TsGS0CabiA009008002.port.Q_flow = 0.0; TsGS0CabiA010008002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA010008002.port.T); TsGS0CabiA010008002.port.Q_flow = 0.0; TsGS0CabiA011008002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA011008002.port.T); TsGS0CabiA011008002.port.Q_flow = 0.0; TsGS0CabiA004009002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA004009002.port.T); TsGS0CabiA004009002.port.Q_flow = 0.0; TsGS0CabiA005009002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA005009002.port.T); TsGS0CabiA005009002.port.Q_flow = 0.0; TsGS0CabiA006009002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA006009002.port.T); TsGS0CabiA006009002.port.Q_flow = 0.0; TsGS0CabiA007009002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA007009002.port.T); TsGS0CabiA007009002.port.Q_flow = 0.0; TsGS0CabiA008009002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA008009002.port.T); TsGS0CabiA008009002.port.Q_flow = 0.0; TsGS0CabiA009009002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA009009002.port.T); TsGS0CabiA009009002.port.Q_flow = 0.0; TsGS0CabiA010009002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA010009002.port.T); TsGS0CabiA010009002.port.Q_flow = 0.0; TsGS0CabiA011009002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA011009002.port.T); TsGS0CabiA011009002.port.Q_flow = 0.0; TsGS0CabiA004010002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA004010002.port.T); TsGS0CabiA004010002.port.Q_flow = 0.0; TsGS0CabiA005010002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA005010002.port.T); TsGS0CabiA005010002.port.Q_flow = 0.0; TsGS0CabiA006010002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA006010002.port.T); TsGS0CabiA006010002.port.Q_flow = 0.0; TsGS0CabiA007010002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA007010002.port.T); TsGS0CabiA007010002.port.Q_flow = 0.0; TsGS0CabiA008010002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA008010002.port.T); TsGS0CabiA008010002.port.Q_flow = 0.0; TsGS0CabiA009010002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA009010002.port.T); TsGS0CabiA009010002.port.Q_flow = 0.0; TsGS0CabiA010010002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA010010002.port.T); TsGS0CabiA010010002.port.Q_flow = 0.0; TsGS0CabiA011010002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA011010002.port.T); TsGS0CabiA011010002.port.Q_flow = 0.0; TsGS0CabiA004011002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA004011002.port.T); TsGS0CabiA004011002.port.Q_flow = 0.0; TsGS0CabiA005011002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA005011002.port.T); TsGS0CabiA005011002.port.Q_flow = 0.0; TsGS0CabiA006011002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA006011002.port.T); TsGS0CabiA006011002.port.Q_flow = 0.0; TsGS0CabiA007011002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA007011002.port.T); TsGS0CabiA007011002.port.Q_flow = 0.0; TsGS0CabiA008011002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA008011002.port.T); TsGS0CabiA008011002.port.Q_flow = 0.0; TsGS0CabiA009011002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA009011002.port.T); TsGS0CabiA009011002.port.Q_flow = 0.0; TsGS0CabiA010011002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA010011002.port.T); TsGS0CabiA010011002.port.Q_flow = 0.0; TsGS0CabiA011011002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA011011002.port.T); TsGS0CabiA011011002.port.Q_flow = 0.0; TsGS0CabiA004012002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA004012002.port.T); TsGS0CabiA004012002.port.Q_flow = 0.0; TsGS0CabiA005012002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA005012002.port.T); TsGS0CabiA005012002.port.Q_flow = 0.0; TsGS0CabiA006012002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA006012002.port.T); TsGS0CabiA006012002.port.Q_flow = 0.0; TsGS0CabiA007012002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA007012002.port.T); TsGS0CabiA007012002.port.Q_flow = 0.0; TsGS0CabiA008012002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA008012002.port.T); TsGS0CabiA008012002.port.Q_flow = 0.0; TsGS0CabiA009012002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA009012002.port.T); TsGS0CabiA009012002.port.Q_flow = 0.0; TsGS0CabiA010012002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA010012002.port.T); TsGS0CabiA010012002.port.Q_flow = 0.0; TsGS0CabiA011012002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA011012002.port.T); TsGS0CabiA011012002.port.Q_flow = 0.0; TsGS0CabiA004013002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA004013002.port.T); TsGS0CabiA004013002.port.Q_flow = 0.0; TsGS0CabiA005013002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA005013002.port.T); TsGS0CabiA005013002.port.Q_flow = 0.0; TsGS0CabiA006013002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA006013002.port.T); TsGS0CabiA006013002.port.Q_flow = 0.0; TsGS0CabiA007013002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA007013002.port.T); TsGS0CabiA007013002.port.Q_flow = 0.0; TsGS0CabiA008013002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA008013002.port.T); TsGS0CabiA008013002.port.Q_flow = 0.0; TsGS0CabiA009013002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA009013002.port.T); TsGS0CabiA009013002.port.Q_flow = 0.0; TsGS0CabiA010013002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA010013002.port.T); TsGS0CabiA010013002.port.Q_flow = 0.0; TsGS0CabiA011013002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA011013002.port.T); TsGS0CabiA011013002.port.Q_flow = 0.0; TsGS0CabiA004004002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA004004002.port.T); TsGS0CabiA004004002.port.Q_flow = 0.0; TsGS0CabiA005004002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA005004002.port.T); TsGS0CabiA005004002.port.Q_flow = 0.0; TsGS0CabiA006004002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA006004002.port.T); TsGS0CabiA006004002.port.Q_flow = 0.0; TsGS0CabiA007004002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA007004002.port.T); TsGS0CabiA007004002.port.Q_flow = 0.0; TsGS0CabiA008004002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA008004002.port.T); TsGS0CabiA008004002.port.Q_flow = 0.0; TsGS0CabiA009004002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA009004002.port.T); TsGS0CabiA009004002.port.Q_flow = 0.0; TsGS0CabiA010004002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA010004002.port.T); TsGS0CabiA010004002.port.Q_flow = 0.0; TsGS0CabiA011004002.T = Modelica.SIunits.Conversions.to_degC(TsGS0CabiA011004002.port.T); TsGS0CabiA011004002.port.Q_flow = 0.0; TsAIR0CabiA002015007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002015007.port.T); TsAIR0CabiA002015007.port.Q_flow = 0.0; TsAIR0CabiA003015007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003015007.port.T); TsAIR0CabiA003015007.port.Q_flow = 0.0; TsAIR0CabiA004015007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004015007.port.T); TsAIR0CabiA004015007.port.Q_flow = 0.0; TsAIR0CabiA005015007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005015007.port.T); TsAIR0CabiA005015007.port.Q_flow = 0.0; TsAIR0CabiA006015007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006015007.port.T); TsAIR0CabiA006015007.port.Q_flow = 0.0; TsAIR0CabiA007015007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007015007.port.T); TsAIR0CabiA007015007.port.Q_flow = 0.0; TsAIR0CabiA008015007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008015007.port.T); TsAIR0CabiA008015007.port.Q_flow = 0.0; TsAIR0CabiA009015007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009015007.port.T); TsAIR0CabiA009015007.port.Q_flow = 0.0; TsAIR0CabiA010015007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010015007.port.T); TsAIR0CabiA010015007.port.Q_flow = 0.0; TsAIR0CabiA011015007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011015007.port.T); TsAIR0CabiA011015007.port.Q_flow = 0.0; TsAIR0CabiA012015007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012015007.port.T); TsAIR0CabiA012015007.port.Q_flow = 0.0; TsAIR0CabiA002014007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002014007.port.T); TsAIR0CabiA002014007.port.Q_flow = 0.0; TsAIR0CabiA003014007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003014007.port.T); TsAIR0CabiA003014007.port.Q_flow = 0.0; TsAIR0CabiA004014007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004014007.port.T); TsAIR0CabiA004014007.port.Q_flow = 0.0; TsAIR0CabiA005014007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005014007.port.T); TsAIR0CabiA005014007.port.Q_flow = 0.0; TsAIR0CabiA006014007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006014007.port.T); TsAIR0CabiA006014007.port.Q_flow = 0.0; TsAIR0CabiA007014007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007014007.port.T); TsAIR0CabiA007014007.port.Q_flow = 0.0; TsAIR0CabiA008014007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008014007.port.T); TsAIR0CabiA008014007.port.Q_flow = 0.0; TsAIR0CabiA009014007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009014007.port.T); TsAIR0CabiA009014007.port.Q_flow = 0.0; TsAIR0CabiA010014007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010014007.port.T); TsAIR0CabiA010014007.port.Q_flow = 0.0; TsAIR0CabiA011014007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011014007.port.T); TsAIR0CabiA011014007.port.Q_flow = 0.0; TsAIR0CabiA012014007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012014007.port.T); TsAIR0CabiA012014007.port.Q_flow = 0.0; TsAIR0CabiA002007007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002007007.port.T); TsAIR0CabiA002007007.port.Q_flow = 0.0; TsAIR0CabiA003007007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003007007.port.T); TsAIR0CabiA003007007.port.Q_flow = 0.0; TsAIR0CabiA004007007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004007007.port.T); TsAIR0CabiA004007007.port.Q_flow = 0.0; TsAIR0CabiA005007007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005007007.port.T); TsAIR0CabiA005007007.port.Q_flow = 0.0; TsAIR0CabiA006007007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006007007.port.T); TsAIR0CabiA006007007.port.Q_flow = 0.0; TsAIR0CabiA007007007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007007007.port.T); TsAIR0CabiA007007007.port.Q_flow = 0.0; TsAIR0CabiA008007007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008007007.port.T); TsAIR0CabiA008007007.port.Q_flow = 0.0; TsAIR0CabiA009007007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009007007.port.T); TsAIR0CabiA009007007.port.Q_flow = 0.0; TsAIR0CabiA010007007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010007007.port.T); TsAIR0CabiA010007007.port.Q_flow = 0.0; TsAIR0CabiA011007007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011007007.port.T); TsAIR0CabiA011007007.port.Q_flow = 0.0; TsAIR0CabiA012007007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012007007.port.T); TsAIR0CabiA012007007.port.Q_flow = 0.0; TsAIR0CabiA002008007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002008007.port.T); TsAIR0CabiA002008007.port.Q_flow = 0.0; TsAIR0CabiA003008007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003008007.port.T); TsAIR0CabiA003008007.port.Q_flow = 0.0; TsAIR0CabiA004008007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004008007.port.T); TsAIR0CabiA004008007.port.Q_flow = 0.0; TsAIR0CabiA005008007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005008007.port.T); TsAIR0CabiA005008007.port.Q_flow = 0.0; TsAIR0CabiA006008007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006008007.port.T); TsAIR0CabiA006008007.port.Q_flow = 0.0; TsAIR0CabiA007008007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007008007.port.T); TsAIR0CabiA007008007.port.Q_flow = 0.0; TsAIR0CabiA008008007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008008007.port.T); TsAIR0CabiA008008007.port.Q_flow = 0.0; TsAIR0CabiA009008007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009008007.port.T); TsAIR0CabiA009008007.port.Q_flow = 0.0; TsAIR0CabiA010008007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010008007.port.T); TsAIR0CabiA010008007.port.Q_flow = 0.0; TsAIR0CabiA011008007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011008007.port.T); TsAIR0CabiA011008007.port.Q_flow = 0.0; TsAIR0CabiA012008007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012008007.port.T); TsAIR0CabiA012008007.port.Q_flow = 0.0; TsAIR0CabiA002009007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002009007.port.T); TsAIR0CabiA002009007.port.Q_flow = 0.0; TsAIR0CabiA003009007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003009007.port.T); TsAIR0CabiA003009007.port.Q_flow = 0.0; TsAIR0CabiA004009007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004009007.port.T); TsAIR0CabiA004009007.port.Q_flow = 0.0; TsAIR0CabiA005009007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005009007.port.T); TsAIR0CabiA005009007.port.Q_flow = 0.0; TsAIR0CabiA006009007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006009007.port.T); TsAIR0CabiA006009007.port.Q_flow = 0.0; TsAIR0CabiA007009007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007009007.port.T); TsAIR0CabiA007009007.port.Q_flow = 0.0; TsAIR0CabiA008009007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008009007.port.T); TsAIR0CabiA008009007.port.Q_flow = 0.0; TsAIR0CabiA009009007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009009007.port.T); TsAIR0CabiA009009007.port.Q_flow = 0.0; TsAIR0CabiA010009007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010009007.port.T); TsAIR0CabiA010009007.port.Q_flow = 0.0; TsAIR0CabiA011009007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011009007.port.T); TsAIR0CabiA011009007.port.Q_flow = 0.0; TsAIR0CabiA012009007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012009007.port.T); TsAIR0CabiA012009007.port.Q_flow = 0.0; TsAIR0CabiA002010007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002010007.port.T); TsAIR0CabiA002010007.port.Q_flow = 0.0; TsAIR0CabiA003010007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003010007.port.T); TsAIR0CabiA003010007.port.Q_flow = 0.0; TsAIR0CabiA004010007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004010007.port.T); TsAIR0CabiA004010007.port.Q_flow = 0.0; TsAIR0CabiA005010007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005010007.port.T); TsAIR0CabiA005010007.port.Q_flow = 0.0; TsAIR0CabiA006010007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006010007.port.T); TsAIR0CabiA006010007.port.Q_flow = 0.0; TsAIR0CabiA007010007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007010007.port.T); TsAIR0CabiA007010007.port.Q_flow = 0.0; TsAIR0CabiA008010007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008010007.port.T); TsAIR0CabiA008010007.port.Q_flow = 0.0; TsAIR0CabiA009010007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009010007.port.T); TsAIR0CabiA009010007.port.Q_flow = 0.0; TsAIR0CabiA010010007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010010007.port.T); TsAIR0CabiA010010007.port.Q_flow = 0.0; TsAIR0CabiA011010007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011010007.port.T); TsAIR0CabiA011010007.port.Q_flow = 0.0; TsAIR0CabiA012010007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012010007.port.T); TsAIR0CabiA012010007.port.Q_flow = 0.0; TsAIR0CabiA002011007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002011007.port.T); TsAIR0CabiA002011007.port.Q_flow = 0.0; TsAIR0CabiA003011007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003011007.port.T); TsAIR0CabiA003011007.port.Q_flow = 0.0; TsAIR0CabiA004011007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004011007.port.T); TsAIR0CabiA004011007.port.Q_flow = 0.0; TsAIR0CabiA005011007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005011007.port.T); TsAIR0CabiA005011007.port.Q_flow = 0.0; TsAIR0CabiA006011007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006011007.port.T); TsAIR0CabiA006011007.port.Q_flow = 0.0; TsAIR0CabiA007011007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007011007.port.T); TsAIR0CabiA007011007.port.Q_flow = 0.0; TsAIR0CabiA008011007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008011007.port.T); TsAIR0CabiA008011007.port.Q_flow = 0.0; TsAIR0CabiA009011007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009011007.port.T); TsAIR0CabiA009011007.port.Q_flow = 0.0; TsAIR0CabiA010011007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010011007.port.T); TsAIR0CabiA010011007.port.Q_flow = 0.0; TsAIR0CabiA011011007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011011007.port.T); TsAIR0CabiA011011007.port.Q_flow = 0.0; TsAIR0CabiA012011007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012011007.port.T); TsAIR0CabiA012011007.port.Q_flow = 0.0; TsAIR0CabiA002012007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002012007.port.T); TsAIR0CabiA002012007.port.Q_flow = 0.0; TsAIR0CabiA003012007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003012007.port.T); TsAIR0CabiA003012007.port.Q_flow = 0.0; TsAIR0CabiA004012007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004012007.port.T); TsAIR0CabiA004012007.port.Q_flow = 0.0; TsAIR0CabiA005012007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005012007.port.T); TsAIR0CabiA005012007.port.Q_flow = 0.0; TsAIR0CabiA006012007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006012007.port.T); TsAIR0CabiA006012007.port.Q_flow = 0.0; TsAIR0CabiA007012007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007012007.port.T); TsAIR0CabiA007012007.port.Q_flow = 0.0; TsAIR0CabiA008012007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008012007.port.T); TsAIR0CabiA008012007.port.Q_flow = 0.0; TsAIR0CabiA009012007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009012007.port.T); TsAIR0CabiA009012007.port.Q_flow = 0.0; TsAIR0CabiA010012007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010012007.port.T); TsAIR0CabiA010012007.port.Q_flow = 0.0; TsAIR0CabiA011012007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011012007.port.T); TsAIR0CabiA011012007.port.Q_flow = 0.0; TsAIR0CabiA012012007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012012007.port.T); TsAIR0CabiA012012007.port.Q_flow = 0.0; TsAIR0CabiA002013007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002013007.port.T); TsAIR0CabiA002013007.port.Q_flow = 0.0; TsAIR0CabiA003013007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003013007.port.T); TsAIR0CabiA003013007.port.Q_flow = 0.0; TsAIR0CabiA004013007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004013007.port.T); TsAIR0CabiA004013007.port.Q_flow = 0.0; TsAIR0CabiA005013007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005013007.port.T); TsAIR0CabiA005013007.port.Q_flow = 0.0; TsAIR0CabiA006013007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006013007.port.T); TsAIR0CabiA006013007.port.Q_flow = 0.0; TsAIR0CabiA007013007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007013007.port.T); TsAIR0CabiA007013007.port.Q_flow = 0.0; TsAIR0CabiA008013007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008013007.port.T); TsAIR0CabiA008013007.port.Q_flow = 0.0; TsAIR0CabiA009013007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009013007.port.T); TsAIR0CabiA009013007.port.Q_flow = 0.0; TsAIR0CabiA010013007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010013007.port.T); TsAIR0CabiA010013007.port.Q_flow = 0.0; TsAIR0CabiA011013007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011013007.port.T); TsAIR0CabiA011013007.port.Q_flow = 0.0; TsAIR0CabiA012013007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012013007.port.T); TsAIR0CabiA012013007.port.Q_flow = 0.0; TsAIR0CabiA002002007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002002007.port.T); TsAIR0CabiA002002007.port.Q_flow = 0.0; TsAIR0CabiA003002007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003002007.port.T); TsAIR0CabiA003002007.port.Q_flow = 0.0; TsAIR0CabiA004002007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004002007.port.T); TsAIR0CabiA004002007.port.Q_flow = 0.0; TsAIR0CabiA005002007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005002007.port.T); TsAIR0CabiA005002007.port.Q_flow = 0.0; TsAIR0CabiA006002007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006002007.port.T); TsAIR0CabiA006002007.port.Q_flow = 0.0; TsAIR0CabiA007002007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007002007.port.T); TsAIR0CabiA007002007.port.Q_flow = 0.0; TsAIR0CabiA008002007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008002007.port.T); TsAIR0CabiA008002007.port.Q_flow = 0.0; TsAIR0CabiA009002007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009002007.port.T); TsAIR0CabiA009002007.port.Q_flow = 0.0; TsAIR0CabiA010002007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010002007.port.T); TsAIR0CabiA010002007.port.Q_flow = 0.0; TsAIR0CabiA011002007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011002007.port.T); TsAIR0CabiA011002007.port.Q_flow = 0.0; TsAIR0CabiA012002007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012002007.port.T); TsAIR0CabiA012002007.port.Q_flow = 0.0; TsAIR0CabiA002003007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002003007.port.T); TsAIR0CabiA002003007.port.Q_flow = 0.0; TsAIR0CabiA003003007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003003007.port.T); TsAIR0CabiA003003007.port.Q_flow = 0.0; TsAIR0CabiA004003007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004003007.port.T); TsAIR0CabiA004003007.port.Q_flow = 0.0; TsAIR0CabiA005003007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005003007.port.T); TsAIR0CabiA005003007.port.Q_flow = 0.0; TsAIR0CabiA006003007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006003007.port.T); TsAIR0CabiA006003007.port.Q_flow = 0.0; TsAIR0CabiA007003007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007003007.port.T); TsAIR0CabiA007003007.port.Q_flow = 0.0; TsAIR0CabiA008003007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008003007.port.T); TsAIR0CabiA008003007.port.Q_flow = 0.0; TsAIR0CabiA009003007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009003007.port.T); TsAIR0CabiA009003007.port.Q_flow = 0.0; TsAIR0CabiA010003007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010003007.port.T); TsAIR0CabiA010003007.port.Q_flow = 0.0; TsAIR0CabiA011003007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011003007.port.T); TsAIR0CabiA011003007.port.Q_flow = 0.0; TsAIR0CabiA012003007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012003007.port.T); TsAIR0CabiA012003007.port.Q_flow = 0.0; TsAIR0CabiA002004007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002004007.port.T); TsAIR0CabiA002004007.port.Q_flow = 0.0; TsAIR0CabiA003004007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003004007.port.T); TsAIR0CabiA003004007.port.Q_flow = 0.0; TsAIR0CabiA004004007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004004007.port.T); TsAIR0CabiA004004007.port.Q_flow = 0.0; TsAIR0CabiA005004007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005004007.port.T); TsAIR0CabiA005004007.port.Q_flow = 0.0; TsAIR0CabiA006004007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006004007.port.T); TsAIR0CabiA006004007.port.Q_flow = 0.0; TsAIR0CabiA007004007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007004007.port.T); TsAIR0CabiA007004007.port.Q_flow = 0.0; TsAIR0CabiA008004007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008004007.port.T); TsAIR0CabiA008004007.port.Q_flow = 0.0; TsAIR0CabiA009004007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009004007.port.T); TsAIR0CabiA009004007.port.Q_flow = 0.0; TsAIR0CabiA010004007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010004007.port.T); TsAIR0CabiA010004007.port.Q_flow = 0.0; TsAIR0CabiA011004007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011004007.port.T); TsAIR0CabiA011004007.port.Q_flow = 0.0; TsAIR0CabiA012004007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012004007.port.T); TsAIR0CabiA012004007.port.Q_flow = 0.0; TsAIR0CabiA002005007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002005007.port.T); TsAIR0CabiA002005007.port.Q_flow = 0.0; TsAIR0CabiA003005007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003005007.port.T); TsAIR0CabiA003005007.port.Q_flow = 0.0; TsAIR0CabiA004005007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004005007.port.T); TsAIR0CabiA004005007.port.Q_flow = 0.0; TsAIR0CabiA005005007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005005007.port.T); TsAIR0CabiA005005007.port.Q_flow = 0.0; TsAIR0CabiA006005007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006005007.port.T); TsAIR0CabiA006005007.port.Q_flow = 0.0; TsAIR0CabiA007005007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007005007.port.T); TsAIR0CabiA007005007.port.Q_flow = 0.0; TsAIR0CabiA008005007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008005007.port.T); TsAIR0CabiA008005007.port.Q_flow = 0.0; TsAIR0CabiA009005007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009005007.port.T); TsAIR0CabiA009005007.port.Q_flow = 0.0; TsAIR0CabiA010005007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010005007.port.T); TsAIR0CabiA010005007.port.Q_flow = 0.0; TsAIR0CabiA011005007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011005007.port.T); TsAIR0CabiA011005007.port.Q_flow = 0.0; TsAIR0CabiA012005007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012005007.port.T); TsAIR0CabiA012005007.port.Q_flow = 0.0; TsAIR0CabiA002006007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002006007.port.T); TsAIR0CabiA002006007.port.Q_flow = 0.0; TsAIR0CabiA003006007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003006007.port.T); TsAIR0CabiA003006007.port.Q_flow = 0.0; TsAIR0CabiA004006007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004006007.port.T); TsAIR0CabiA004006007.port.Q_flow = 0.0; TsAIR0CabiA005006007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005006007.port.T); TsAIR0CabiA005006007.port.Q_flow = 0.0; TsAIR0CabiA006006007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006006007.port.T); TsAIR0CabiA006006007.port.Q_flow = 0.0; TsAIR0CabiA007006007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007006007.port.T); TsAIR0CabiA007006007.port.Q_flow = 0.0; TsAIR0CabiA008006007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008006007.port.T); TsAIR0CabiA008006007.port.Q_flow = 0.0; TsAIR0CabiA009006007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009006007.port.T); TsAIR0CabiA009006007.port.Q_flow = 0.0; TsAIR0CabiA010006007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010006007.port.T); TsAIR0CabiA010006007.port.Q_flow = 0.0; TsAIR0CabiA011006007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011006007.port.T); TsAIR0CabiA011006007.port.Q_flow = 0.0; TsAIR0CabiA012006007.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012006007.port.T); TsAIR0CabiA012006007.port.Q_flow = 0.0; TsAIR0CabiA011009006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011009006.port.T); TsAIR0CabiA011009006.port.Q_flow = 0.0; TsAIR0CabiA012009006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012009006.port.T); TsAIR0CabiA012009006.port.Q_flow = 0.0; TsAIR0CabiA002010006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002010006.port.T); TsAIR0CabiA002010006.port.Q_flow = 0.0; TsAIR0CabiA003010006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003010006.port.T); TsAIR0CabiA003010006.port.Q_flow = 0.0; TsAIR0CabiA004010006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004010006.port.T); TsAIR0CabiA004010006.port.Q_flow = 0.0; TsAIR0CabiA005010006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005010006.port.T); TsAIR0CabiA005010006.port.Q_flow = 0.0; TsAIR0CabiA006010006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006010006.port.T); TsAIR0CabiA006010006.port.Q_flow = 0.0; TsAIR0CabiA007010006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007010006.port.T); TsAIR0CabiA007010006.port.Q_flow = 0.0; TsAIR0CabiA011010006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011010006.port.T); TsAIR0CabiA011010006.port.Q_flow = 0.0; TsAIR0CabiA012010006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012010006.port.T); TsAIR0CabiA012010006.port.Q_flow = 0.0; TsAIR0CabiA002011006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002011006.port.T); TsAIR0CabiA002011006.port.Q_flow = 0.0; TsAIR0CabiA003011006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003011006.port.T); TsAIR0CabiA003011006.port.Q_flow = 0.0; TsAIR0CabiA007011006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007011006.port.T); TsAIR0CabiA007011006.port.Q_flow = 0.0; TsAIR0CabiA011011006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011011006.port.T); TsAIR0CabiA011011006.port.Q_flow = 0.0; TsAIR0CabiA012011006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012011006.port.T); TsAIR0CabiA012011006.port.Q_flow = 0.0; TsAIR0CabiA002012006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002012006.port.T); TsAIR0CabiA002012006.port.Q_flow = 0.0; TsAIR0CabiA003012006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003012006.port.T); TsAIR0CabiA003012006.port.Q_flow = 0.0; TsAIR0CabiA007012006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007012006.port.T); TsAIR0CabiA007012006.port.Q_flow = 0.0; TsAIR0CabiA008012006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008012006.port.T); TsAIR0CabiA008012006.port.Q_flow = 0.0; TsAIR0CabiA009012006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009012006.port.T); TsAIR0CabiA009012006.port.Q_flow = 0.0; TsAIR0CabiA010012006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010012006.port.T); TsAIR0CabiA010012006.port.Q_flow = 0.0; TsAIR0CabiA011012006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011012006.port.T); TsAIR0CabiA011012006.port.Q_flow = 0.0; TsAIR0CabiA012012006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012012006.port.T); TsAIR0CabiA012012006.port.Q_flow = 0.0; TsAIR0CabiA002013006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002013006.port.T); TsAIR0CabiA002013006.port.Q_flow = 0.0; TsAIR0CabiA003013006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003013006.port.T); TsAIR0CabiA003013006.port.Q_flow = 0.0; TsAIR0CabiA007013006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007013006.port.T); TsAIR0CabiA007013006.port.Q_flow = 0.0; TsAIR0CabiA008013006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008013006.port.T); TsAIR0CabiA008013006.port.Q_flow = 0.0; TsAIR0CabiA009013006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009013006.port.T); TsAIR0CabiA009013006.port.Q_flow = 0.0; TsAIR0CabiA010013006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010013006.port.T); TsAIR0CabiA010013006.port.Q_flow = 0.0; TsAIR0CabiA011013006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011013006.port.T); TsAIR0CabiA011013006.port.Q_flow = 0.0; TsAIR0CabiA012013006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012013006.port.T); TsAIR0CabiA012013006.port.Q_flow = 0.0; TsAIR0CabiA002014006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002014006.port.T); TsAIR0CabiA002014006.port.Q_flow = 0.0; TsAIR0CabiA003014006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003014006.port.T); TsAIR0CabiA003014006.port.Q_flow = 0.0; TsAIR0CabiA004014006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004014006.port.T); TsAIR0CabiA004014006.port.Q_flow = 0.0; TsAIR0CabiA005014006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005014006.port.T); TsAIR0CabiA005014006.port.Q_flow = 0.0; TsAIR0CabiA006014006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006014006.port.T); TsAIR0CabiA006014006.port.Q_flow = 0.0; TsAIR0CabiA007014006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007014006.port.T); TsAIR0CabiA007014006.port.Q_flow = 0.0; TsAIR0CabiA008014006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008014006.port.T); TsAIR0CabiA008014006.port.Q_flow = 0.0; TsAIR0CabiA009014006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009014006.port.T); TsAIR0CabiA009014006.port.Q_flow = 0.0; TsAIR0CabiA010014006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010014006.port.T); TsAIR0CabiA010014006.port.Q_flow = 0.0; TsAIR0CabiA011014006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011014006.port.T); TsAIR0CabiA011014006.port.Q_flow = 0.0; TsAIR0CabiA012014006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012014006.port.T); TsAIR0CabiA012014006.port.Q_flow = 0.0; TsAIR0CabiA002015006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002015006.port.T); TsAIR0CabiA002015006.port.Q_flow = 0.0; TsAIR0CabiA003015006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003015006.port.T); TsAIR0CabiA003015006.port.Q_flow = 0.0; TsAIR0CabiA004015006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004015006.port.T); TsAIR0CabiA004015006.port.Q_flow = 0.0; TsAIR0CabiA005015006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005015006.port.T); TsAIR0CabiA005015006.port.Q_flow = 0.0; TsAIR0CabiA006015006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006015006.port.T); TsAIR0CabiA006015006.port.Q_flow = 0.0; TsAIR0CabiA007015006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007015006.port.T); TsAIR0CabiA007015006.port.Q_flow = 0.0; TsAIR0CabiA008015006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008015006.port.T); TsAIR0CabiA008015006.port.Q_flow = 0.0; TsAIR0CabiA009015006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009015006.port.T); TsAIR0CabiA009015006.port.Q_flow = 0.0; TsAIR0CabiA010015006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010015006.port.T); TsAIR0CabiA010015006.port.Q_flow = 0.0; TsAIR0CabiA011015006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011015006.port.T); TsAIR0CabiA011015006.port.Q_flow = 0.0; TsAIR0CabiA012015006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012015006.port.T); TsAIR0CabiA012015006.port.Q_flow = 0.0; TsAIR0CabiA010005006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010005006.port.T); TsAIR0CabiA010005006.port.Q_flow = 0.0; TsAIR0CabiA011005006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011005006.port.T); TsAIR0CabiA011005006.port.Q_flow = 0.0; TsAIR0CabiA012005006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012005006.port.T); TsAIR0CabiA012005006.port.Q_flow = 0.0; TsAIR0CabiA002006006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002006006.port.T); TsAIR0CabiA002006006.port.Q_flow = 0.0; TsAIR0CabiA003006006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003006006.port.T); TsAIR0CabiA003006006.port.Q_flow = 0.0; TsAIR0CabiA004006006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004006006.port.T); TsAIR0CabiA004006006.port.Q_flow = 0.0; TsAIR0CabiA005006006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005006006.port.T); TsAIR0CabiA005006006.port.Q_flow = 0.0; TsAIR0CabiA010006006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010006006.port.T); TsAIR0CabiA010006006.port.Q_flow = 0.0; TsAIR0CabiA011006006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011006006.port.T); TsAIR0CabiA011006006.port.Q_flow = 0.0; TsAIR0CabiA012006006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012006006.port.T); TsAIR0CabiA012006006.port.Q_flow = 0.0; TsAIR0CabiA002007006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002007006.port.T); TsAIR0CabiA002007006.port.Q_flow = 0.0; TsAIR0CabiA003007006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003007006.port.T); TsAIR0CabiA003007006.port.Q_flow = 0.0; TsAIR0CabiA004007006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004007006.port.T); TsAIR0CabiA004007006.port.Q_flow = 0.0; TsAIR0CabiA005007006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005007006.port.T); TsAIR0CabiA005007006.port.Q_flow = 0.0; TsAIR0CabiA006007006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006007006.port.T); TsAIR0CabiA006007006.port.Q_flow = 0.0; TsAIR0CabiA007007006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007007006.port.T); TsAIR0CabiA007007006.port.Q_flow = 0.0; TsAIR0CabiA008007006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008007006.port.T); TsAIR0CabiA008007006.port.Q_flow = 0.0; TsAIR0CabiA009007006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009007006.port.T); TsAIR0CabiA009007006.port.Q_flow = 0.0; TsAIR0CabiA010007006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010007006.port.T); TsAIR0CabiA010007006.port.Q_flow = 0.0; TsAIR0CabiA011007006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011007006.port.T); TsAIR0CabiA011007006.port.Q_flow = 0.0; TsAIR0CabiA012007006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012007006.port.T); TsAIR0CabiA012007006.port.Q_flow = 0.0; TsAIR0CabiA002008006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002008006.port.T); TsAIR0CabiA002008006.port.Q_flow = 0.0; TsAIR0CabiA003008006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003008006.port.T); TsAIR0CabiA003008006.port.Q_flow = 0.0; TsAIR0CabiA004008006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004008006.port.T); TsAIR0CabiA004008006.port.Q_flow = 0.0; TsAIR0CabiA005008006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005008006.port.T); TsAIR0CabiA005008006.port.Q_flow = 0.0; TsAIR0CabiA006008006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006008006.port.T); TsAIR0CabiA006008006.port.Q_flow = 0.0; TsAIR0CabiA007008006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007008006.port.T); TsAIR0CabiA007008006.port.Q_flow = 0.0; TsAIR0CabiA008008006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008008006.port.T); TsAIR0CabiA008008006.port.Q_flow = 0.0; TsAIR0CabiA009008006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009008006.port.T); TsAIR0CabiA009008006.port.Q_flow = 0.0; TsAIR0CabiA010008006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010008006.port.T); TsAIR0CabiA010008006.port.Q_flow = 0.0; TsAIR0CabiA011008006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011008006.port.T); TsAIR0CabiA011008006.port.Q_flow = 0.0; TsAIR0CabiA012008006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012008006.port.T); TsAIR0CabiA012008006.port.Q_flow = 0.0; TsAIR0CabiA002009006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002009006.port.T); TsAIR0CabiA002009006.port.Q_flow = 0.0; TsAIR0CabiA003009006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003009006.port.T); TsAIR0CabiA003009006.port.Q_flow = 0.0; TsAIR0CabiA004009006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004009006.port.T); TsAIR0CabiA004009006.port.Q_flow = 0.0; TsAIR0CabiA005009006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005009006.port.T); TsAIR0CabiA005009006.port.Q_flow = 0.0; TsAIR0CabiA006009006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006009006.port.T); TsAIR0CabiA006009006.port.Q_flow = 0.0; TsAIR0CabiA007009006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007009006.port.T); TsAIR0CabiA007009006.port.Q_flow = 0.0; TsAIR0CabiA002002006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002002006.port.T); TsAIR0CabiA002002006.port.Q_flow = 0.0; TsAIR0CabiA003002006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003002006.port.T); TsAIR0CabiA003002006.port.Q_flow = 0.0; TsAIR0CabiA004002006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004002006.port.T); TsAIR0CabiA004002006.port.Q_flow = 0.0; TsAIR0CabiA005002006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005002006.port.T); TsAIR0CabiA005002006.port.Q_flow = 0.0; TsAIR0CabiA006002006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006002006.port.T); TsAIR0CabiA006002006.port.Q_flow = 0.0; TsAIR0CabiA007002006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007002006.port.T); TsAIR0CabiA007002006.port.Q_flow = 0.0; TsAIR0CabiA008002006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008002006.port.T); TsAIR0CabiA008002006.port.Q_flow = 0.0; TsAIR0CabiA009002006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009002006.port.T); TsAIR0CabiA009002006.port.Q_flow = 0.0; TsAIR0CabiA010002006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010002006.port.T); TsAIR0CabiA010002006.port.Q_flow = 0.0; TsAIR0CabiA011002006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011002006.port.T); TsAIR0CabiA011002006.port.Q_flow = 0.0; TsAIR0CabiA012002006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012002006.port.T); TsAIR0CabiA012002006.port.Q_flow = 0.0; TsAIR0CabiA002003006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002003006.port.T); TsAIR0CabiA002003006.port.Q_flow = 0.0; TsAIR0CabiA003003006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003003006.port.T); TsAIR0CabiA003003006.port.Q_flow = 0.0; TsAIR0CabiA004003006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004003006.port.T); TsAIR0CabiA004003006.port.Q_flow = 0.0; TsAIR0CabiA005003006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005003006.port.T); TsAIR0CabiA005003006.port.Q_flow = 0.0; TsAIR0CabiA006003006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006003006.port.T); TsAIR0CabiA006003006.port.Q_flow = 0.0; TsAIR0CabiA007003006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007003006.port.T); TsAIR0CabiA007003006.port.Q_flow = 0.0; TsAIR0CabiA008003006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008003006.port.T); TsAIR0CabiA008003006.port.Q_flow = 0.0; TsAIR0CabiA009003006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009003006.port.T); TsAIR0CabiA009003006.port.Q_flow = 0.0; TsAIR0CabiA010003006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010003006.port.T); TsAIR0CabiA010003006.port.Q_flow = 0.0; TsAIR0CabiA011003006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011003006.port.T); TsAIR0CabiA011003006.port.Q_flow = 0.0; TsAIR0CabiA012003006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012003006.port.T); TsAIR0CabiA012003006.port.Q_flow = 0.0; TsAIR0CabiA002004006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002004006.port.T); TsAIR0CabiA002004006.port.Q_flow = 0.0; TsAIR0CabiA003004006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003004006.port.T); TsAIR0CabiA003004006.port.Q_flow = 0.0; TsAIR0CabiA004004006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004004006.port.T); TsAIR0CabiA004004006.port.Q_flow = 0.0; TsAIR0CabiA005004006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005004006.port.T); TsAIR0CabiA005004006.port.Q_flow = 0.0; TsAIR0CabiA010004006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010004006.port.T); TsAIR0CabiA010004006.port.Q_flow = 0.0; TsAIR0CabiA011004006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011004006.port.T); TsAIR0CabiA011004006.port.Q_flow = 0.0; TsAIR0CabiA012004006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012004006.port.T); TsAIR0CabiA012004006.port.Q_flow = 0.0; TsAIR0CabiA002005006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002005006.port.T); TsAIR0CabiA002005006.port.Q_flow = 0.0; TsAIR0CabiA003005006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003005006.port.T); TsAIR0CabiA003005006.port.Q_flow = 0.0; TsAIR0CabiA004005006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004005006.port.T); TsAIR0CabiA004005006.port.Q_flow = 0.0; TsAIR0CabiA005005006.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005005006.port.T); TsAIR0CabiA005005006.port.Q_flow = 0.0; TsAIR0CabiA002002005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002002005.port.T); TsAIR0CabiA002002005.port.Q_flow = 0.0; TsAIR0CabiA003002005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003002005.port.T); TsAIR0CabiA003002005.port.Q_flow = 0.0; TsAIR0CabiA004002005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004002005.port.T); TsAIR0CabiA004002005.port.Q_flow = 0.0; TsAIR0CabiA005002005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005002005.port.T); TsAIR0CabiA005002005.port.Q_flow = 0.0; TsAIR0CabiA006002005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006002005.port.T); TsAIR0CabiA006002005.port.Q_flow = 0.0; TsAIR0CabiA007002005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007002005.port.T); TsAIR0CabiA007002005.port.Q_flow = 0.0; TsAIR0CabiA008002005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008002005.port.T); TsAIR0CabiA008002005.port.Q_flow = 0.0; TsAIR0CabiA009002005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009002005.port.T); TsAIR0CabiA009002005.port.Q_flow = 0.0; TsAIR0CabiA010002005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010002005.port.T); TsAIR0CabiA010002005.port.Q_flow = 0.0; TsAIR0CabiA011002005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011002005.port.T); TsAIR0CabiA011002005.port.Q_flow = 0.0; TsAIR0CabiA012002005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012002005.port.T); TsAIR0CabiA012002005.port.Q_flow = 0.0; TsAIR0CabiA002003005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002003005.port.T); TsAIR0CabiA002003005.port.Q_flow = 0.0; TsAIR0CabiA012003005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012003005.port.T); TsAIR0CabiA012003005.port.Q_flow = 0.0; TsAIR0CabiA002004005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002004005.port.T); TsAIR0CabiA002004005.port.Q_flow = 0.0; TsAIR0CabiA012004005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012004005.port.T); TsAIR0CabiA012004005.port.Q_flow = 0.0; TsAIR0CabiA002005005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002005005.port.T); TsAIR0CabiA002005005.port.Q_flow = 0.0; TsAIR0CabiA012005005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012005005.port.T); TsAIR0CabiA012005005.port.Q_flow = 0.0; TsAIR0CabiA002006005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002006005.port.T); TsAIR0CabiA002006005.port.Q_flow = 0.0; TsAIR0CabiA012006005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012006005.port.T); TsAIR0CabiA012006005.port.Q_flow = 0.0; TsAIR0CabiA002007005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002007005.port.T); TsAIR0CabiA002007005.port.Q_flow = 0.0; TsAIR0CabiA012007005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012007005.port.T); TsAIR0CabiA012007005.port.Q_flow = 0.0; TsAIR0CabiA002008005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002008005.port.T); TsAIR0CabiA002008005.port.Q_flow = 0.0; TsAIR0CabiA012008005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012008005.port.T); TsAIR0CabiA012008005.port.Q_flow = 0.0; TsAIR0CabiA002009005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002009005.port.T); TsAIR0CabiA002009005.port.Q_flow = 0.0; TsAIR0CabiA012009005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012009005.port.T); TsAIR0CabiA012009005.port.Q_flow = 0.0; TsAIR0CabiA002010005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002010005.port.T); TsAIR0CabiA002010005.port.Q_flow = 0.0; TsAIR0CabiA012010005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012010005.port.T); TsAIR0CabiA012010005.port.Q_flow = 0.0; TsAIR0CabiA002011005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002011005.port.T); TsAIR0CabiA002011005.port.Q_flow = 0.0; TsAIR0CabiA012011005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012011005.port.T); TsAIR0CabiA012011005.port.Q_flow = 0.0; TsAIR0CabiA002012005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002012005.port.T); TsAIR0CabiA002012005.port.Q_flow = 0.0; TsAIR0CabiA012012005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012012005.port.T); TsAIR0CabiA012012005.port.Q_flow = 0.0; TsAIR0CabiA002013005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002013005.port.T); TsAIR0CabiA002013005.port.Q_flow = 0.0; TsAIR0CabiA012013005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012013005.port.T); TsAIR0CabiA012013005.port.Q_flow = 0.0; TsAIR0CabiA002014005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002014005.port.T); TsAIR0CabiA002014005.port.Q_flow = 0.0; TsAIR0CabiA012014005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012014005.port.T); TsAIR0CabiA012014005.port.Q_flow = 0.0; TsAIR0CabiA002015005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002015005.port.T); TsAIR0CabiA002015005.port.Q_flow = 0.0; TsAIR0CabiA003015005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003015005.port.T); TsAIR0CabiA003015005.port.Q_flow = 0.0; TsAIR0CabiA004015005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004015005.port.T); TsAIR0CabiA004015005.port.Q_flow = 0.0; TsAIR0CabiA005015005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005015005.port.T); TsAIR0CabiA005015005.port.Q_flow = 0.0; TsAIR0CabiA006015005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006015005.port.T); TsAIR0CabiA006015005.port.Q_flow = 0.0; TsAIR0CabiA007015005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007015005.port.T); TsAIR0CabiA007015005.port.Q_flow = 0.0; TsAIR0CabiA008015005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008015005.port.T); TsAIR0CabiA008015005.port.Q_flow = 0.0; TsAIR0CabiA009015005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009015005.port.T); TsAIR0CabiA009015005.port.Q_flow = 0.0; TsAIR0CabiA010015005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010015005.port.T); TsAIR0CabiA010015005.port.Q_flow = 0.0; TsAIR0CabiA011015005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011015005.port.T); TsAIR0CabiA011015005.port.Q_flow = 0.0; TsAIR0CabiA012015005.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012015005.port.T); TsAIR0CabiA012015005.port.Q_flow = 0.0; TsAIR0CabiA002002004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002002004.port.T); TsAIR0CabiA002002004.port.Q_flow = 0.0; TsAIR0CabiA003002004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003002004.port.T); TsAIR0CabiA003002004.port.Q_flow = 0.0; TsAIR0CabiA004002004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004002004.port.T); TsAIR0CabiA004002004.port.Q_flow = 0.0; TsAIR0CabiA005002004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005002004.port.T); TsAIR0CabiA005002004.port.Q_flow = 0.0; TsAIR0CabiA006002004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006002004.port.T); TsAIR0CabiA006002004.port.Q_flow = 0.0; TsAIR0CabiA007002004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007002004.port.T); TsAIR0CabiA007002004.port.Q_flow = 0.0; TsAIR0CabiA008002004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008002004.port.T); TsAIR0CabiA008002004.port.Q_flow = 0.0; TsAIR0CabiA009002004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009002004.port.T); TsAIR0CabiA009002004.port.Q_flow = 0.0; TsAIR0CabiA010002004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010002004.port.T); TsAIR0CabiA010002004.port.Q_flow = 0.0; TsAIR0CabiA011002004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011002004.port.T); TsAIR0CabiA011002004.port.Q_flow = 0.0; TsAIR0CabiA012002004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012002004.port.T); TsAIR0CabiA012002004.port.Q_flow = 0.0; TsAIR0CabiA002003004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002003004.port.T); TsAIR0CabiA002003004.port.Q_flow = 0.0; TsAIR0CabiA003003004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003003004.port.T); TsAIR0CabiA003003004.port.Q_flow = 0.0; TsAIR0CabiA004003004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004003004.port.T); TsAIR0CabiA004003004.port.Q_flow = 0.0; TsAIR0CabiA005003004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005003004.port.T); TsAIR0CabiA005003004.port.Q_flow = 0.0; TsAIR0CabiA006003004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006003004.port.T); TsAIR0CabiA006003004.port.Q_flow = 0.0; TsAIR0CabiA007003004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007003004.port.T); TsAIR0CabiA007003004.port.Q_flow = 0.0; TsAIR0CabiA008003004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008003004.port.T); TsAIR0CabiA008003004.port.Q_flow = 0.0; TsAIR0CabiA009003004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009003004.port.T); TsAIR0CabiA009003004.port.Q_flow = 0.0; TsAIR0CabiA010003004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010003004.port.T); TsAIR0CabiA010003004.port.Q_flow = 0.0; TsAIR0CabiA011003004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011003004.port.T); TsAIR0CabiA011003004.port.Q_flow = 0.0; TsAIR0CabiA012003004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012003004.port.T); TsAIR0CabiA012003004.port.Q_flow = 0.0; TsAIR0CabiA002004004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002004004.port.T); TsAIR0CabiA002004004.port.Q_flow = 0.0; TsAIR0CabiA003004004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003004004.port.T); TsAIR0CabiA003004004.port.Q_flow = 0.0; TsAIR0CabiA008004004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008004004.port.T); TsAIR0CabiA008004004.port.Q_flow = 0.0; TsAIR0CabiA009004004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009004004.port.T); TsAIR0CabiA009004004.port.Q_flow = 0.0; TsAIR0CabiA010004004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010004004.port.T); TsAIR0CabiA010004004.port.Q_flow = 0.0; TsAIR0CabiA011004004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011004004.port.T); TsAIR0CabiA011004004.port.Q_flow = 0.0; TsAIR0CabiA012004004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012004004.port.T); TsAIR0CabiA012004004.port.Q_flow = 0.0; TsAIR0CabiA002005004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002005004.port.T); TsAIR0CabiA002005004.port.Q_flow = 0.0; TsAIR0CabiA003005004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003005004.port.T); TsAIR0CabiA003005004.port.Q_flow = 0.0; TsAIR0CabiA008005004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008005004.port.T); TsAIR0CabiA008005004.port.Q_flow = 0.0; TsAIR0CabiA009005004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009005004.port.T); TsAIR0CabiA009005004.port.Q_flow = 0.0; TsAIR0CabiA010005004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010005004.port.T); TsAIR0CabiA010005004.port.Q_flow = 0.0; TsAIR0CabiA011005004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011005004.port.T); TsAIR0CabiA011005004.port.Q_flow = 0.0; TsAIR0CabiA012005004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012005004.port.T); TsAIR0CabiA012005004.port.Q_flow = 0.0; TsAIR0CabiA002006004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002006004.port.T); TsAIR0CabiA002006004.port.Q_flow = 0.0; TsAIR0CabiA003006004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003006004.port.T); TsAIR0CabiA003006004.port.Q_flow = 0.0; TsAIR0CabiA008006004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008006004.port.T); TsAIR0CabiA008006004.port.Q_flow = 0.0; TsAIR0CabiA009006004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009006004.port.T); TsAIR0CabiA009006004.port.Q_flow = 0.0; TsAIR0CabiA010006004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010006004.port.T); TsAIR0CabiA010006004.port.Q_flow = 0.0; TsAIR0CabiA011006004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011006004.port.T); TsAIR0CabiA011006004.port.Q_flow = 0.0; TsAIR0CabiA012006004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012006004.port.T); TsAIR0CabiA012006004.port.Q_flow = 0.0; TsAIR0CabiA002007004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002007004.port.T); TsAIR0CabiA002007004.port.Q_flow = 0.0; TsAIR0CabiA003007004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003007004.port.T); TsAIR0CabiA003007004.port.Q_flow = 0.0; TsAIR0CabiA004007004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004007004.port.T); TsAIR0CabiA004007004.port.Q_flow = 0.0; TsAIR0CabiA005007004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005007004.port.T); TsAIR0CabiA005007004.port.Q_flow = 0.0; TsAIR0CabiA006007004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006007004.port.T); TsAIR0CabiA006007004.port.Q_flow = 0.0; TsAIR0CabiA007007004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007007004.port.T); TsAIR0CabiA007007004.port.Q_flow = 0.0; TsAIR0CabiA008007004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008007004.port.T); TsAIR0CabiA008007004.port.Q_flow = 0.0; TsAIR0CabiA009007004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009007004.port.T); TsAIR0CabiA009007004.port.Q_flow = 0.0; TsAIR0CabiA010007004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010007004.port.T); TsAIR0CabiA010007004.port.Q_flow = 0.0; TsAIR0CabiA011007004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011007004.port.T); TsAIR0CabiA011007004.port.Q_flow = 0.0; TsAIR0CabiA012007004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012007004.port.T); TsAIR0CabiA012007004.port.Q_flow = 0.0; TsAIR0CabiA002008004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002008004.port.T); TsAIR0CabiA002008004.port.Q_flow = 0.0; TsAIR0CabiA003008004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003008004.port.T); TsAIR0CabiA003008004.port.Q_flow = 0.0; TsAIR0CabiA004008004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004008004.port.T); TsAIR0CabiA004008004.port.Q_flow = 0.0; TsAIR0CabiA005008004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005008004.port.T); TsAIR0CabiA005008004.port.Q_flow = 0.0; TsAIR0CabiA006008004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006008004.port.T); TsAIR0CabiA006008004.port.Q_flow = 0.0; TsAIR0CabiA007008004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007008004.port.T); TsAIR0CabiA007008004.port.Q_flow = 0.0; TsAIR0CabiA011008004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011008004.port.T); TsAIR0CabiA011008004.port.Q_flow = 0.0; TsAIR0CabiA012008004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012008004.port.T); TsAIR0CabiA012008004.port.Q_flow = 0.0; TsAIR0CabiA002009004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002009004.port.T); TsAIR0CabiA002009004.port.Q_flow = 0.0; TsAIR0CabiA003009004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003009004.port.T); TsAIR0CabiA003009004.port.Q_flow = 0.0; TsAIR0CabiA004009004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004009004.port.T); TsAIR0CabiA004009004.port.Q_flow = 0.0; TsAIR0CabiA005009004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005009004.port.T); TsAIR0CabiA005009004.port.Q_flow = 0.0; TsAIR0CabiA006009004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006009004.port.T); TsAIR0CabiA006009004.port.Q_flow = 0.0; TsAIR0CabiA007009004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007009004.port.T); TsAIR0CabiA007009004.port.Q_flow = 0.0; TsAIR0CabiA011009004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011009004.port.T); TsAIR0CabiA011009004.port.Q_flow = 0.0; TsAIR0CabiA012009004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012009004.port.T); TsAIR0CabiA012009004.port.Q_flow = 0.0; TsAIR0CabiA002010004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002010004.port.T); TsAIR0CabiA002010004.port.Q_flow = 0.0; TsAIR0CabiA003010004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003010004.port.T); TsAIR0CabiA003010004.port.Q_flow = 0.0; TsAIR0CabiA004010004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004010004.port.T); TsAIR0CabiA004010004.port.Q_flow = 0.0; TsAIR0CabiA005010004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005010004.port.T); TsAIR0CabiA005010004.port.Q_flow = 0.0; TsAIR0CabiA006010004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006010004.port.T); TsAIR0CabiA006010004.port.Q_flow = 0.0; TsAIR0CabiA007010004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007010004.port.T); TsAIR0CabiA007010004.port.Q_flow = 0.0; TsAIR0CabiA011010004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011010004.port.T); TsAIR0CabiA011010004.port.Q_flow = 0.0; TsAIR0CabiA012010004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012010004.port.T); TsAIR0CabiA012010004.port.Q_flow = 0.0; TsAIR0CabiA002011004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002011004.port.T); TsAIR0CabiA002011004.port.Q_flow = 0.0; TsAIR0CabiA003011004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003011004.port.T); TsAIR0CabiA003011004.port.Q_flow = 0.0; TsAIR0CabiA007011004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007011004.port.T); TsAIR0CabiA007011004.port.Q_flow = 0.0; TsAIR0CabiA008011004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008011004.port.T); TsAIR0CabiA008011004.port.Q_flow = 0.0; TsAIR0CabiA009011004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009011004.port.T); TsAIR0CabiA009011004.port.Q_flow = 0.0; TsAIR0CabiA010011004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010011004.port.T); TsAIR0CabiA010011004.port.Q_flow = 0.0; TsAIR0CabiA011011004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011011004.port.T); TsAIR0CabiA011011004.port.Q_flow = 0.0; TsAIR0CabiA012011004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012011004.port.T); TsAIR0CabiA012011004.port.Q_flow = 0.0; TsAIR0CabiA002012004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002012004.port.T); TsAIR0CabiA002012004.port.Q_flow = 0.0; TsAIR0CabiA003012004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003012004.port.T); TsAIR0CabiA003012004.port.Q_flow = 0.0; TsAIR0CabiA007012004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007012004.port.T); TsAIR0CabiA007012004.port.Q_flow = 0.0; TsAIR0CabiA008012004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008012004.port.T); TsAIR0CabiA008012004.port.Q_flow = 0.0; TsAIR0CabiA009012004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009012004.port.T); TsAIR0CabiA009012004.port.Q_flow = 0.0; TsAIR0CabiA010012004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010012004.port.T); TsAIR0CabiA010012004.port.Q_flow = 0.0; TsAIR0CabiA011012004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011012004.port.T); TsAIR0CabiA011012004.port.Q_flow = 0.0; TsAIR0CabiA012012004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012012004.port.T); TsAIR0CabiA012012004.port.Q_flow = 0.0; TsAIR0CabiA002013004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002013004.port.T); TsAIR0CabiA002013004.port.Q_flow = 0.0; TsAIR0CabiA003013004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003013004.port.T); TsAIR0CabiA003013004.port.Q_flow = 0.0; TsAIR0CabiA007013004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007013004.port.T); TsAIR0CabiA007013004.port.Q_flow = 0.0; TsAIR0CabiA008013004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008013004.port.T); TsAIR0CabiA008013004.port.Q_flow = 0.0; TsAIR0CabiA009013004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009013004.port.T); TsAIR0CabiA009013004.port.Q_flow = 0.0; TsAIR0CabiA010013004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010013004.port.T); TsAIR0CabiA010013004.port.Q_flow = 0.0; TsAIR0CabiA011013004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011013004.port.T); TsAIR0CabiA011013004.port.Q_flow = 0.0; TsAIR0CabiA012013004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012013004.port.T); TsAIR0CabiA012013004.port.Q_flow = 0.0; TsAIR0CabiA002014004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002014004.port.T); TsAIR0CabiA002014004.port.Q_flow = 0.0; TsAIR0CabiA003014004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003014004.port.T); TsAIR0CabiA003014004.port.Q_flow = 0.0; TsAIR0CabiA004014004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004014004.port.T); TsAIR0CabiA004014004.port.Q_flow = 0.0; TsAIR0CabiA005014004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005014004.port.T); TsAIR0CabiA005014004.port.Q_flow = 0.0; TsAIR0CabiA006014004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006014004.port.T); TsAIR0CabiA006014004.port.Q_flow = 0.0; TsAIR0CabiA007014004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007014004.port.T); TsAIR0CabiA007014004.port.Q_flow = 0.0; TsAIR0CabiA008014004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008014004.port.T); TsAIR0CabiA008014004.port.Q_flow = 0.0; TsAIR0CabiA009014004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009014004.port.T); TsAIR0CabiA009014004.port.Q_flow = 0.0; TsAIR0CabiA010014004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010014004.port.T); TsAIR0CabiA010014004.port.Q_flow = 0.0; TsAIR0CabiA011014004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011014004.port.T); TsAIR0CabiA011014004.port.Q_flow = 0.0; TsAIR0CabiA012014004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012014004.port.T); TsAIR0CabiA012014004.port.Q_flow = 0.0; TsAIR0CabiA002015004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002015004.port.T); TsAIR0CabiA002015004.port.Q_flow = 0.0; TsAIR0CabiA003015004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003015004.port.T); TsAIR0CabiA003015004.port.Q_flow = 0.0; TsAIR0CabiA004015004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004015004.port.T); TsAIR0CabiA004015004.port.Q_flow = 0.0; TsAIR0CabiA005015004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005015004.port.T); TsAIR0CabiA005015004.port.Q_flow = 0.0; TsAIR0CabiA006015004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006015004.port.T); TsAIR0CabiA006015004.port.Q_flow = 0.0; TsAIR0CabiA007015004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007015004.port.T); TsAIR0CabiA007015004.port.Q_flow = 0.0; TsAIR0CabiA008015004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008015004.port.T); TsAIR0CabiA008015004.port.Q_flow = 0.0; TsAIR0CabiA009015004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009015004.port.T); TsAIR0CabiA009015004.port.Q_flow = 0.0; TsAIR0CabiA010015004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010015004.port.T); TsAIR0CabiA010015004.port.Q_flow = 0.0; TsAIR0CabiA011015004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011015004.port.T); TsAIR0CabiA011015004.port.Q_flow = 0.0; TsAIR0CabiA012015004.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012015004.port.T); TsAIR0CabiA012015004.port.Q_flow = 0.0; TsAIR0CabiA002002003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002002003.port.T); TsAIR0CabiA002002003.port.Q_flow = 0.0; TsAIR0CabiA003002003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003002003.port.T); TsAIR0CabiA003002003.port.Q_flow = 0.0; TsAIR0CabiA004002003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004002003.port.T); TsAIR0CabiA004002003.port.Q_flow = 0.0; TsAIR0CabiA005002003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005002003.port.T); TsAIR0CabiA005002003.port.Q_flow = 0.0; TsAIR0CabiA006002003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006002003.port.T); TsAIR0CabiA006002003.port.Q_flow = 0.0; TsAIR0CabiA007002003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007002003.port.T); TsAIR0CabiA007002003.port.Q_flow = 0.0; TsAIR0CabiA008002003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008002003.port.T); TsAIR0CabiA008002003.port.Q_flow = 0.0; TsAIR0CabiA009002003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009002003.port.T); TsAIR0CabiA009002003.port.Q_flow = 0.0; TsAIR0CabiA010002003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010002003.port.T); TsAIR0CabiA010002003.port.Q_flow = 0.0; TsAIR0CabiA011002003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011002003.port.T); TsAIR0CabiA011002003.port.Q_flow = 0.0; TsAIR0CabiA012002003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012002003.port.T); TsAIR0CabiA012002003.port.Q_flow = 0.0; TsAIR0CabiA002003003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002003003.port.T); TsAIR0CabiA002003003.port.Q_flow = 0.0; TsAIR0CabiA003003003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003003003.port.T); TsAIR0CabiA003003003.port.Q_flow = 0.0; TsAIR0CabiA004003003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004003003.port.T); TsAIR0CabiA004003003.port.Q_flow = 0.0; TsAIR0CabiA005003003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005003003.port.T); TsAIR0CabiA005003003.port.Q_flow = 0.0; TsAIR0CabiA006003003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006003003.port.T); TsAIR0CabiA006003003.port.Q_flow = 0.0; TsAIR0CabiA007003003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007003003.port.T); TsAIR0CabiA007003003.port.Q_flow = 0.0; TsAIR0CabiA008003003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008003003.port.T); TsAIR0CabiA008003003.port.Q_flow = 0.0; TsAIR0CabiA009003003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009003003.port.T); TsAIR0CabiA009003003.port.Q_flow = 0.0; TsAIR0CabiA010003003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010003003.port.T); TsAIR0CabiA010003003.port.Q_flow = 0.0; TsAIR0CabiA011003003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011003003.port.T); TsAIR0CabiA011003003.port.Q_flow = 0.0; TsAIR0CabiA012003003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012003003.port.T); TsAIR0CabiA012003003.port.Q_flow = 0.0; TsAIR0CabiA002004003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002004003.port.T); TsAIR0CabiA002004003.port.Q_flow = 0.0; TsAIR0CabiA003004003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003004003.port.T); TsAIR0CabiA003004003.port.Q_flow = 0.0; TsAIR0CabiA004004003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004004003.port.T); TsAIR0CabiA004004003.port.Q_flow = 0.0; TsAIR0CabiA005004003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005004003.port.T); TsAIR0CabiA005004003.port.Q_flow = 0.0; TsAIR0CabiA006004003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006004003.port.T); TsAIR0CabiA006004003.port.Q_flow = 0.0; TsAIR0CabiA007004003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007004003.port.T); TsAIR0CabiA007004003.port.Q_flow = 0.0; TsAIR0CabiA008004003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008004003.port.T); TsAIR0CabiA008004003.port.Q_flow = 0.0; TsAIR0CabiA009004003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009004003.port.T); TsAIR0CabiA009004003.port.Q_flow = 0.0; TsAIR0CabiA010004003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010004003.port.T); TsAIR0CabiA010004003.port.Q_flow = 0.0; TsAIR0CabiA011004003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011004003.port.T); TsAIR0CabiA011004003.port.Q_flow = 0.0; TsAIR0CabiA012004003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012004003.port.T); TsAIR0CabiA012004003.port.Q_flow = 0.0; TsAIR0CabiA002005003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002005003.port.T); TsAIR0CabiA002005003.port.Q_flow = 0.0; TsAIR0CabiA003005003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003005003.port.T); TsAIR0CabiA003005003.port.Q_flow = 0.0; TsAIR0CabiA004005003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004005003.port.T); TsAIR0CabiA004005003.port.Q_flow = 0.0; TsAIR0CabiA005005003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005005003.port.T); TsAIR0CabiA005005003.port.Q_flow = 0.0; TsAIR0CabiA006005003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006005003.port.T); TsAIR0CabiA006005003.port.Q_flow = 0.0; TsAIR0CabiA007005003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007005003.port.T); TsAIR0CabiA007005003.port.Q_flow = 0.0; TsAIR0CabiA008005003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008005003.port.T); TsAIR0CabiA008005003.port.Q_flow = 0.0; TsAIR0CabiA009005003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009005003.port.T); TsAIR0CabiA009005003.port.Q_flow = 0.0; TsAIR0CabiA010005003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010005003.port.T); TsAIR0CabiA010005003.port.Q_flow = 0.0; TsAIR0CabiA011005003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011005003.port.T); TsAIR0CabiA011005003.port.Q_flow = 0.0; TsAIR0CabiA012005003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012005003.port.T); TsAIR0CabiA012005003.port.Q_flow = 0.0; TsAIR0CabiA002006003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002006003.port.T); TsAIR0CabiA002006003.port.Q_flow = 0.0; TsAIR0CabiA003006003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003006003.port.T); TsAIR0CabiA003006003.port.Q_flow = 0.0; TsAIR0CabiA004006003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004006003.port.T); TsAIR0CabiA004006003.port.Q_flow = 0.0; TsAIR0CabiA005006003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005006003.port.T); TsAIR0CabiA005006003.port.Q_flow = 0.0; TsAIR0CabiA006006003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006006003.port.T); TsAIR0CabiA006006003.port.Q_flow = 0.0; TsAIR0CabiA007006003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007006003.port.T); TsAIR0CabiA007006003.port.Q_flow = 0.0; TsAIR0CabiA008006003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008006003.port.T); TsAIR0CabiA008006003.port.Q_flow = 0.0; TsAIR0CabiA009006003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009006003.port.T); TsAIR0CabiA009006003.port.Q_flow = 0.0; TsAIR0CabiA010006003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010006003.port.T); TsAIR0CabiA010006003.port.Q_flow = 0.0; TsAIR0CabiA011006003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011006003.port.T); TsAIR0CabiA011006003.port.Q_flow = 0.0; TsAIR0CabiA012006003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012006003.port.T); TsAIR0CabiA012006003.port.Q_flow = 0.0; TsAIR0CabiA002007003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002007003.port.T); TsAIR0CabiA002007003.port.Q_flow = 0.0; TsAIR0CabiA003007003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003007003.port.T); TsAIR0CabiA003007003.port.Q_flow = 0.0; TsAIR0CabiA004007003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004007003.port.T); TsAIR0CabiA004007003.port.Q_flow = 0.0; TsAIR0CabiA005007003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005007003.port.T); TsAIR0CabiA005007003.port.Q_flow = 0.0; TsAIR0CabiA006007003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006007003.port.T); TsAIR0CabiA006007003.port.Q_flow = 0.0; TsAIR0CabiA007007003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007007003.port.T); TsAIR0CabiA007007003.port.Q_flow = 0.0; TsAIR0CabiA008007003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008007003.port.T); TsAIR0CabiA008007003.port.Q_flow = 0.0; TsAIR0CabiA009007003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009007003.port.T); TsAIR0CabiA009007003.port.Q_flow = 0.0; TsAIR0CabiA010007003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010007003.port.T); TsAIR0CabiA010007003.port.Q_flow = 0.0; TsAIR0CabiA011007003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011007003.port.T); TsAIR0CabiA011007003.port.Q_flow = 0.0; TsAIR0CabiA012007003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012007003.port.T); TsAIR0CabiA012007003.port.Q_flow = 0.0; TsAIR0CabiA002008003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002008003.port.T); TsAIR0CabiA002008003.port.Q_flow = 0.0; TsAIR0CabiA003008003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003008003.port.T); TsAIR0CabiA003008003.port.Q_flow = 0.0; TsAIR0CabiA004008003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004008003.port.T); TsAIR0CabiA004008003.port.Q_flow = 0.0; TsAIR0CabiA005008003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005008003.port.T); TsAIR0CabiA005008003.port.Q_flow = 0.0; TsAIR0CabiA006008003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006008003.port.T); TsAIR0CabiA006008003.port.Q_flow = 0.0; TsAIR0CabiA007008003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007008003.port.T); TsAIR0CabiA007008003.port.Q_flow = 0.0; TsAIR0CabiA011008003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011008003.port.T); TsAIR0CabiA011008003.port.Q_flow = 0.0; TsAIR0CabiA012008003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012008003.port.T); TsAIR0CabiA012008003.port.Q_flow = 0.0; TsAIR0CabiA002009003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002009003.port.T); TsAIR0CabiA002009003.port.Q_flow = 0.0; TsAIR0CabiA003009003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003009003.port.T); TsAIR0CabiA003009003.port.Q_flow = 0.0; TsAIR0CabiA004009003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004009003.port.T); TsAIR0CabiA004009003.port.Q_flow = 0.0; TsAIR0CabiA005009003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005009003.port.T); TsAIR0CabiA005009003.port.Q_flow = 0.0; TsAIR0CabiA006009003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006009003.port.T); TsAIR0CabiA006009003.port.Q_flow = 0.0; TsAIR0CabiA007009003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007009003.port.T); TsAIR0CabiA007009003.port.Q_flow = 0.0; TsAIR0CabiA011009003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011009003.port.T); TsAIR0CabiA011009003.port.Q_flow = 0.0; TsAIR0CabiA012009003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012009003.port.T); TsAIR0CabiA012009003.port.Q_flow = 0.0; TsAIR0CabiA002010003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002010003.port.T); TsAIR0CabiA002010003.port.Q_flow = 0.0; TsAIR0CabiA003010003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003010003.port.T); TsAIR0CabiA003010003.port.Q_flow = 0.0; TsAIR0CabiA004010003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004010003.port.T); TsAIR0CabiA004010003.port.Q_flow = 0.0; TsAIR0CabiA005010003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005010003.port.T); TsAIR0CabiA005010003.port.Q_flow = 0.0; TsAIR0CabiA006010003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006010003.port.T); TsAIR0CabiA006010003.port.Q_flow = 0.0; TsAIR0CabiA007010003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007010003.port.T); TsAIR0CabiA007010003.port.Q_flow = 0.0; TsAIR0CabiA011010003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011010003.port.T); TsAIR0CabiA011010003.port.Q_flow = 0.0; TsAIR0CabiA012010003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012010003.port.T); TsAIR0CabiA012010003.port.Q_flow = 0.0; TsAIR0CabiA002011003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002011003.port.T); TsAIR0CabiA002011003.port.Q_flow = 0.0; TsAIR0CabiA003011003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003011003.port.T); TsAIR0CabiA003011003.port.Q_flow = 0.0; TsAIR0CabiA004011003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004011003.port.T); TsAIR0CabiA004011003.port.Q_flow = 0.0; TsAIR0CabiA005011003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005011003.port.T); TsAIR0CabiA005011003.port.Q_flow = 0.0; TsAIR0CabiA006011003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006011003.port.T); TsAIR0CabiA006011003.port.Q_flow = 0.0; TsAIR0CabiA007011003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007011003.port.T); TsAIR0CabiA007011003.port.Q_flow = 0.0; TsAIR0CabiA008011003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008011003.port.T); TsAIR0CabiA008011003.port.Q_flow = 0.0; TsAIR0CabiA009011003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009011003.port.T); TsAIR0CabiA009011003.port.Q_flow = 0.0; TsAIR0CabiA010011003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010011003.port.T); TsAIR0CabiA010011003.port.Q_flow = 0.0; TsAIR0CabiA011011003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011011003.port.T); TsAIR0CabiA011011003.port.Q_flow = 0.0; TsAIR0CabiA012011003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012011003.port.T); TsAIR0CabiA012011003.port.Q_flow = 0.0; TsAIR0CabiA002012003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002012003.port.T); TsAIR0CabiA002012003.port.Q_flow = 0.0; TsAIR0CabiA003012003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003012003.port.T); TsAIR0CabiA003012003.port.Q_flow = 0.0; TsAIR0CabiA004012003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004012003.port.T); TsAIR0CabiA004012003.port.Q_flow = 0.0; TsAIR0CabiA005012003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005012003.port.T); TsAIR0CabiA005012003.port.Q_flow = 0.0; TsAIR0CabiA006012003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006012003.port.T); TsAIR0CabiA006012003.port.Q_flow = 0.0; TsAIR0CabiA007012003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007012003.port.T); TsAIR0CabiA007012003.port.Q_flow = 0.0; TsAIR0CabiA008012003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008012003.port.T); TsAIR0CabiA008012003.port.Q_flow = 0.0; TsAIR0CabiA009012003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009012003.port.T); TsAIR0CabiA009012003.port.Q_flow = 0.0; TsAIR0CabiA010012003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010012003.port.T); TsAIR0CabiA010012003.port.Q_flow = 0.0; TsAIR0CabiA011012003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011012003.port.T); TsAIR0CabiA011012003.port.Q_flow = 0.0; TsAIR0CabiA012012003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012012003.port.T); TsAIR0CabiA012012003.port.Q_flow = 0.0; TsAIR0CabiA002013003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002013003.port.T); TsAIR0CabiA002013003.port.Q_flow = 0.0; TsAIR0CabiA003013003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003013003.port.T); TsAIR0CabiA003013003.port.Q_flow = 0.0; TsAIR0CabiA004013003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004013003.port.T); TsAIR0CabiA004013003.port.Q_flow = 0.0; TsAIR0CabiA005013003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005013003.port.T); TsAIR0CabiA005013003.port.Q_flow = 0.0; TsAIR0CabiA006013003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006013003.port.T); TsAIR0CabiA006013003.port.Q_flow = 0.0; TsAIR0CabiA007013003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007013003.port.T); TsAIR0CabiA007013003.port.Q_flow = 0.0; TsAIR0CabiA008013003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008013003.port.T); TsAIR0CabiA008013003.port.Q_flow = 0.0; TsAIR0CabiA009013003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009013003.port.T); TsAIR0CabiA009013003.port.Q_flow = 0.0; TsAIR0CabiA010013003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010013003.port.T); TsAIR0CabiA010013003.port.Q_flow = 0.0; TsAIR0CabiA011013003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011013003.port.T); TsAIR0CabiA011013003.port.Q_flow = 0.0; TsAIR0CabiA012013003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012013003.port.T); TsAIR0CabiA012013003.port.Q_flow = 0.0; TsAIR0CabiA002014003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002014003.port.T); TsAIR0CabiA002014003.port.Q_flow = 0.0; TsAIR0CabiA003014003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003014003.port.T); TsAIR0CabiA003014003.port.Q_flow = 0.0; TsAIR0CabiA004014003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004014003.port.T); TsAIR0CabiA004014003.port.Q_flow = 0.0; TsAIR0CabiA005014003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005014003.port.T); TsAIR0CabiA005014003.port.Q_flow = 0.0; TsAIR0CabiA006014003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006014003.port.T); TsAIR0CabiA006014003.port.Q_flow = 0.0; TsAIR0CabiA007014003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007014003.port.T); TsAIR0CabiA007014003.port.Q_flow = 0.0; TsAIR0CabiA008014003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008014003.port.T); TsAIR0CabiA008014003.port.Q_flow = 0.0; TsAIR0CabiA009014003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009014003.port.T); TsAIR0CabiA009014003.port.Q_flow = 0.0; TsAIR0CabiA010014003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010014003.port.T); TsAIR0CabiA010014003.port.Q_flow = 0.0; TsAIR0CabiA011014003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011014003.port.T); TsAIR0CabiA011014003.port.Q_flow = 0.0; TsAIR0CabiA012014003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012014003.port.T); TsAIR0CabiA012014003.port.Q_flow = 0.0; TsAIR0CabiA002015003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002015003.port.T); TsAIR0CabiA002015003.port.Q_flow = 0.0; TsAIR0CabiA003015003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003015003.port.T); TsAIR0CabiA003015003.port.Q_flow = 0.0; TsAIR0CabiA004015003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004015003.port.T); TsAIR0CabiA004015003.port.Q_flow = 0.0; TsAIR0CabiA005015003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005015003.port.T); TsAIR0CabiA005015003.port.Q_flow = 0.0; TsAIR0CabiA006015003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006015003.port.T); TsAIR0CabiA006015003.port.Q_flow = 0.0; TsAIR0CabiA007015003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007015003.port.T); TsAIR0CabiA007015003.port.Q_flow = 0.0; TsAIR0CabiA008015003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008015003.port.T); TsAIR0CabiA008015003.port.Q_flow = 0.0; TsAIR0CabiA009015003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009015003.port.T); TsAIR0CabiA009015003.port.Q_flow = 0.0; TsAIR0CabiA010015003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010015003.port.T); TsAIR0CabiA010015003.port.Q_flow = 0.0; TsAIR0CabiA011015003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011015003.port.T); TsAIR0CabiA011015003.port.Q_flow = 0.0; TsAIR0CabiA012015003.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012015003.port.T); TsAIR0CabiA012015003.port.Q_flow = 0.0; TsAIR0CabiA012005002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012005002.port.T); TsAIR0CabiA012005002.port.Q_flow = 0.0; TsAIR0CabiA002006002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002006002.port.T); TsAIR0CabiA002006002.port.Q_flow = 0.0; TsAIR0CabiA003006002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003006002.port.T); TsAIR0CabiA003006002.port.Q_flow = 0.0; TsAIR0CabiA012006002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012006002.port.T); TsAIR0CabiA012006002.port.Q_flow = 0.0; TsAIR0CabiA002007002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002007002.port.T); TsAIR0CabiA002007002.port.Q_flow = 0.0; TsAIR0CabiA003007002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003007002.port.T); TsAIR0CabiA003007002.port.Q_flow = 0.0; TsAIR0CabiA012007002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012007002.port.T); TsAIR0CabiA012007002.port.Q_flow = 0.0; TsAIR0CabiA002008002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002008002.port.T); TsAIR0CabiA002008002.port.Q_flow = 0.0; TsAIR0CabiA003008002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003008002.port.T); TsAIR0CabiA003008002.port.Q_flow = 0.0; TsAIR0CabiA012008002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012008002.port.T); TsAIR0CabiA012008002.port.Q_flow = 0.0; TsAIR0CabiA002009002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002009002.port.T); TsAIR0CabiA002009002.port.Q_flow = 0.0; TsAIR0CabiA003009002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003009002.port.T); TsAIR0CabiA003009002.port.Q_flow = 0.0; TsAIR0CabiA012009002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012009002.port.T); TsAIR0CabiA012009002.port.Q_flow = 0.0; TsAIR0CabiA002010002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002010002.port.T); TsAIR0CabiA002010002.port.Q_flow = 0.0; TsAIR0CabiA003010002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003010002.port.T); TsAIR0CabiA003010002.port.Q_flow = 0.0; TsAIR0CabiA012010002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012010002.port.T); TsAIR0CabiA012010002.port.Q_flow = 0.0; TsAIR0CabiA002011002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002011002.port.T); TsAIR0CabiA002011002.port.Q_flow = 0.0; TsAIR0CabiA003011002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003011002.port.T); TsAIR0CabiA003011002.port.Q_flow = 0.0; TsAIR0CabiA012011002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012011002.port.T); TsAIR0CabiA012011002.port.Q_flow = 0.0; TsAIR0CabiA002012002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002012002.port.T); TsAIR0CabiA002012002.port.Q_flow = 0.0; TsAIR0CabiA003012002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003012002.port.T); TsAIR0CabiA003012002.port.Q_flow = 0.0; TsAIR0CabiA012012002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012012002.port.T); TsAIR0CabiA012012002.port.Q_flow = 0.0; TsAIR0CabiA002013002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002013002.port.T); TsAIR0CabiA002013002.port.Q_flow = 0.0; TsAIR0CabiA003013002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003013002.port.T); TsAIR0CabiA003013002.port.Q_flow = 0.0; TsAIR0CabiA012013002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012013002.port.T); TsAIR0CabiA012013002.port.Q_flow = 0.0; TsAIR0CabiA002014002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002014002.port.T); TsAIR0CabiA002014002.port.Q_flow = 0.0; TsAIR0CabiA003014002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003014002.port.T); TsAIR0CabiA003014002.port.Q_flow = 0.0; TsAIR0CabiA004014002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004014002.port.T); TsAIR0CabiA004014002.port.Q_flow = 0.0; TsAIR0CabiA005014002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005014002.port.T); TsAIR0CabiA005014002.port.Q_flow = 0.0; TsAIR0CabiA006014002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006014002.port.T); TsAIR0CabiA006014002.port.Q_flow = 0.0; TsAIR0CabiA007014002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007014002.port.T); TsAIR0CabiA007014002.port.Q_flow = 0.0; TsAIR0CabiA008014002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008014002.port.T); TsAIR0CabiA008014002.port.Q_flow = 0.0; TsAIR0CabiA009014002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009014002.port.T); TsAIR0CabiA009014002.port.Q_flow = 0.0; TsAIR0CabiA010014002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010014002.port.T); TsAIR0CabiA010014002.port.Q_flow = 0.0; TsAIR0CabiA011014002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011014002.port.T); TsAIR0CabiA011014002.port.Q_flow = 0.0; TsAIR0CabiA012014002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012014002.port.T); TsAIR0CabiA012014002.port.Q_flow = 0.0; TsAIR0CabiA002015002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002015002.port.T); TsAIR0CabiA002015002.port.Q_flow = 0.0; TsAIR0CabiA003015002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003015002.port.T); TsAIR0CabiA003015002.port.Q_flow = 0.0; TsAIR0CabiA004015002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004015002.port.T); TsAIR0CabiA004015002.port.Q_flow = 0.0; TsAIR0CabiA005015002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005015002.port.T); TsAIR0CabiA005015002.port.Q_flow = 0.0; TsAIR0CabiA006015002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006015002.port.T); TsAIR0CabiA006015002.port.Q_flow = 0.0; TsAIR0CabiA007015002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007015002.port.T); TsAIR0CabiA007015002.port.Q_flow = 0.0; TsAIR0CabiA008015002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008015002.port.T); TsAIR0CabiA008015002.port.Q_flow = 0.0; TsAIR0CabiA009015002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009015002.port.T); TsAIR0CabiA009015002.port.Q_flow = 0.0; TsAIR0CabiA010015002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010015002.port.T); TsAIR0CabiA010015002.port.Q_flow = 0.0; TsAIR0CabiA011015002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011015002.port.T); TsAIR0CabiA011015002.port.Q_flow = 0.0; TsAIR0CabiA012015002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012015002.port.T); TsAIR0CabiA012015002.port.Q_flow = 0.0; TsAIR0CabiA002004002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002004002.port.T); TsAIR0CabiA002004002.port.Q_flow = 0.0; TsAIR0CabiA003004002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003004002.port.T); TsAIR0CabiA003004002.port.Q_flow = 0.0; TsAIR0CabiA012004002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012004002.port.T); TsAIR0CabiA012004002.port.Q_flow = 0.0; TsAIR0CabiA002005002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002005002.port.T); TsAIR0CabiA002005002.port.Q_flow = 0.0; TsAIR0CabiA003005002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003005002.port.T); TsAIR0CabiA003005002.port.Q_flow = 0.0; TsAIR0CabiA002003002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002003002.port.T); TsAIR0CabiA002003002.port.Q_flow = 0.0; TsAIR0CabiA003003002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003003002.port.T); TsAIR0CabiA003003002.port.Q_flow = 0.0; TsAIR0CabiA004003002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004003002.port.T); TsAIR0CabiA004003002.port.Q_flow = 0.0; TsAIR0CabiA005003002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005003002.port.T); TsAIR0CabiA005003002.port.Q_flow = 0.0; TsAIR0CabiA006003002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006003002.port.T); TsAIR0CabiA006003002.port.Q_flow = 0.0; TsAIR0CabiA007003002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007003002.port.T); TsAIR0CabiA007003002.port.Q_flow = 0.0; TsAIR0CabiA008003002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008003002.port.T); TsAIR0CabiA008003002.port.Q_flow = 0.0; TsAIR0CabiA009003002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009003002.port.T); TsAIR0CabiA009003002.port.Q_flow = 0.0; TsAIR0CabiA010003002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010003002.port.T); TsAIR0CabiA010003002.port.Q_flow = 0.0; TsAIR0CabiA011003002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011003002.port.T); TsAIR0CabiA011003002.port.Q_flow = 0.0; TsAIR0CabiA012003002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012003002.port.T); TsAIR0CabiA012003002.port.Q_flow = 0.0; TsAIR0CabiA002002002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA002002002.port.T); TsAIR0CabiA002002002.port.Q_flow = 0.0; TsAIR0CabiA003002002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA003002002.port.T); TsAIR0CabiA003002002.port.Q_flow = 0.0; TsAIR0CabiA004002002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA004002002.port.T); TsAIR0CabiA004002002.port.Q_flow = 0.0; TsAIR0CabiA005002002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA005002002.port.T); TsAIR0CabiA005002002.port.Q_flow = 0.0; TsAIR0CabiA006002002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA006002002.port.T); TsAIR0CabiA006002002.port.Q_flow = 0.0; TsAIR0CabiA007002002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA007002002.port.T); TsAIR0CabiA007002002.port.Q_flow = 0.0; TsAIR0CabiA008002002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA008002002.port.T); TsAIR0CabiA008002002.port.Q_flow = 0.0; TsAIR0CabiA009002002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA009002002.port.T); TsAIR0CabiA009002002.port.Q_flow = 0.0; TsAIR0CabiA010002002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA010002002.port.T); TsAIR0CabiA010002002.port.Q_flow = 0.0; TsAIR0CabiA011002002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA011002002.port.T); TsAIR0CabiA011002002.port.Q_flow = 0.0; TsAIR0CabiA012002002.T = Modelica.SIunits.Conversions.to_degC(TsAIR0CabiA012002002.port.T); TsAIR0CabiA012002002.port.Q_flow = 0.0; TsST0CabiA008008003.T = Modelica.SIunits.Conversions.to_degC(TsST0CabiA008008003.port.T); TsST0CabiA008008003.port.Q_flow = 0.0; TsST0CabiA009008003.T = Modelica.SIunits.Conversions.to_degC(TsST0CabiA009008003.port.T); TsST0CabiA009008003.port.Q_flow = 0.0; TsST0CabiA010008003.T = Modelica.SIunits.Conversions.to_degC(TsST0CabiA010008003.port.T); TsST0CabiA010008003.port.Q_flow = 0.0; TsST0CabiA008009003.T = Modelica.SIunits.Conversions.to_degC(TsST0CabiA008009003.port.T); TsST0CabiA008009003.port.Q_flow = 0.0; TsST0CabiA009009003.T = Modelica.SIunits.Conversions.to_degC(TsST0CabiA009009003.port.T); TsST0CabiA009009003.port.Q_flow = 0.0; TsST0CabiA010009003.T = Modelica.SIunits.Conversions.to_degC(TsST0CabiA010009003.port.T); TsST0CabiA010009003.port.Q_flow = 0.0; TsST0CabiA008010003.T = Modelica.SIunits.Conversions.to_degC(TsST0CabiA008010003.port.T); TsST0CabiA008010003.port.Q_flow = 0.0; TsST0CabiA009010003.T = Modelica.SIunits.Conversions.to_degC(TsST0CabiA009010003.port.T); TsST0CabiA009010003.port.Q_flow = 0.0; TsST0CabiA010010003.T = Modelica.SIunits.Conversions.to_degC(TsST0CabiA010010003.port.T); TsST0CabiA010010003.port.Q_flow = 0.0; TsIC30CabiA004004004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA004004004.port.T); TsIC30CabiA004004004.port.Q_flow = 0.0; TsIC30CabiA005004004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA005004004.port.T); TsIC30CabiA005004004.port.Q_flow = 0.0; TsIC30CabiA006004004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA006004004.port.T); TsIC30CabiA006004004.port.Q_flow = 0.0; TsIC30CabiA007004004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA007004004.port.T); TsIC30CabiA007004004.port.Q_flow = 0.0; TsIC30CabiA004005004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA004005004.port.T); TsIC30CabiA004005004.port.Q_flow = 0.0; TsIC30CabiA005005004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA005005004.port.T); TsIC30CabiA005005004.port.Q_flow = 0.0; TsIC30CabiA006005004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA006005004.port.T); TsIC30CabiA006005004.port.Q_flow = 0.0; TsIC30CabiA007005004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA007005004.port.T); TsIC30CabiA007005004.port.Q_flow = 0.0; TsIC30CabiA004006004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA004006004.port.T); TsIC30CabiA004006004.port.Q_flow = 0.0; TsIC30CabiA005006004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA005006004.port.T); TsIC30CabiA005006004.port.Q_flow = 0.0; TsIC30CabiA006006004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA006006004.port.T); TsIC30CabiA006006004.port.Q_flow = 0.0; TsIC30CabiA007006004.T = Modelica.SIunits.Conversions.to_degC(TsIC30CabiA007006004.port.T); TsIC30CabiA007006004.port.Q_flow = 0.0; TsIC20CabiA008008004.T = Modelica.SIunits.Conversions.to_degC(TsIC20CabiA008008004.port.T); TsIC20CabiA008008004.port.Q_flow = 0.0; TsIC20CabiA009008004.T = Modelica.SIunits.Conversions.to_degC(TsIC20CabiA009008004.port.T); TsIC20CabiA009008004.port.Q_flow = 0.0; TsIC20CabiA010008004.T = Modelica.SIunits.Conversions.to_degC(TsIC20CabiA010008004.port.T); TsIC20CabiA010008004.port.Q_flow = 0.0; TsIC20CabiA008009004.T = Modelica.SIunits.Conversions.to_degC(TsIC20CabiA008009004.port.T); TsIC20CabiA008009004.port.Q_flow = 0.0; TsIC20CabiA009009004.T = Modelica.SIunits.Conversions.to_degC(TsIC20CabiA009009004.port.T); TsIC20CabiA009009004.port.Q_flow = 0.0; TsIC20CabiA010009004.T = Modelica.SIunits.Conversions.to_degC(TsIC20CabiA010009004.port.T); TsIC20CabiA010009004.port.Q_flow = 0.0; TsIC20CabiA008010004.T = Modelica.SIunits.Conversions.to_degC(TsIC20CabiA008010004.port.T); TsIC20CabiA008010004.port.Q_flow = 0.0; TsIC20CabiA009010004.T = Modelica.SIunits.Conversions.to_degC(TsIC20CabiA009010004.port.T); TsIC20CabiA009010004.port.Q_flow = 0.0; TsIC20CabiA010010004.T = Modelica.SIunits.Conversions.to_degC(TsIC20CabiA010010004.port.T); TsIC20CabiA010010004.port.Q_flow = 0.0; TsIC60CabiA004011004.T = Modelica.SIunits.Conversions.to_degC(TsIC60CabiA004011004.port.T); TsIC60CabiA004011004.port.Q_flow = 0.0; TsIC60CabiA005011004.T = Modelica.SIunits.Conversions.to_degC(TsIC60CabiA005011004.port.T); TsIC60CabiA005011004.port.Q_flow = 0.0; TsIC60CabiA006011004.T = Modelica.SIunits.Conversions.to_degC(TsIC60CabiA006011004.port.T); TsIC60CabiA006011004.port.Q_flow = 0.0; TsIC60CabiA004012004.T = Modelica.SIunits.Conversions.to_degC(TsIC60CabiA004012004.port.T); TsIC60CabiA004012004.port.Q_flow = 0.0; TsIC60CabiA005012004.T = Modelica.SIunits.Conversions.to_degC(TsIC60CabiA005012004.port.T); TsIC60CabiA005012004.port.Q_flow = 0.0; TsIC60CabiA006012004.T = Modelica.SIunits.Conversions.to_degC(TsIC60CabiA006012004.port.T); TsIC60CabiA006012004.port.Q_flow = 0.0; TsIC60CabiA004013004.T = Modelica.SIunits.Conversions.to_degC(TsIC60CabiA004013004.port.T); TsIC60CabiA004013004.port.Q_flow = 0.0; TsIC60CabiA005013004.T = Modelica.SIunits.Conversions.to_degC(TsIC60CabiA005013004.port.T); TsIC60CabiA005013004.port.Q_flow = 0.0; TsIC60CabiA006013004.T = Modelica.SIunits.Conversions.to_degC(TsIC60CabiA006013004.port.T); TsIC60CabiA006013004.port.Q_flow = 0.0; TsPWB0CabiA003011005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003011005.port.T); TsPWB0CabiA003011005.port.Q_flow = 0.0; TsPWB0CabiA004011005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004011005.port.T); TsPWB0CabiA004011005.port.Q_flow = 0.0; TsPWB0CabiA005011005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005011005.port.T); TsPWB0CabiA005011005.port.Q_flow = 0.0; TsPWB0CabiA006011005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006011005.port.T); TsPWB0CabiA006011005.port.Q_flow = 0.0; TsPWB0CabiA007011005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007011005.port.T); TsPWB0CabiA007011005.port.Q_flow = 0.0; TsPWB0CabiA008011005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008011005.port.T); TsPWB0CabiA008011005.port.Q_flow = 0.0; TsPWB0CabiA009011005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009011005.port.T); TsPWB0CabiA009011005.port.Q_flow = 0.0; TsPWB0CabiA010011005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010011005.port.T); TsPWB0CabiA010011005.port.Q_flow = 0.0; TsPWB0CabiA011011005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011011005.port.T); TsPWB0CabiA011011005.port.Q_flow = 0.0; TsPWB0CabiA003012005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003012005.port.T); TsPWB0CabiA003012005.port.Q_flow = 0.0; TsPWB0CabiA004012005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004012005.port.T); TsPWB0CabiA004012005.port.Q_flow = 0.0; TsPWB0CabiA005012005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005012005.port.T); TsPWB0CabiA005012005.port.Q_flow = 0.0; TsPWB0CabiA006012005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006012005.port.T); TsPWB0CabiA006012005.port.Q_flow = 0.0; TsPWB0CabiA007012005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007012005.port.T); TsPWB0CabiA007012005.port.Q_flow = 0.0; TsPWB0CabiA008012005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008012005.port.T); TsPWB0CabiA008012005.port.Q_flow = 0.0; TsPWB0CabiA009012005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009012005.port.T); TsPWB0CabiA009012005.port.Q_flow = 0.0; TsPWB0CabiA010012005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010012005.port.T); TsPWB0CabiA010012005.port.Q_flow = 0.0; TsPWB0CabiA011012005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011012005.port.T); TsPWB0CabiA011012005.port.Q_flow = 0.0; TsPWB0CabiA003013005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003013005.port.T); TsPWB0CabiA003013005.port.Q_flow = 0.0; TsPWB0CabiA004013005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004013005.port.T); TsPWB0CabiA004013005.port.Q_flow = 0.0; TsPWB0CabiA005013005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005013005.port.T); TsPWB0CabiA005013005.port.Q_flow = 0.0; TsPWB0CabiA006013005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006013005.port.T); TsPWB0CabiA006013005.port.Q_flow = 0.0; TsPWB0CabiA007013005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007013005.port.T); TsPWB0CabiA007013005.port.Q_flow = 0.0; TsPWB0CabiA008013005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008013005.port.T); TsPWB0CabiA008013005.port.Q_flow = 0.0; TsPWB0CabiA009013005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009013005.port.T); TsPWB0CabiA009013005.port.Q_flow = 0.0; TsPWB0CabiA010013005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010013005.port.T); TsPWB0CabiA010013005.port.Q_flow = 0.0; TsPWB0CabiA011013005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011013005.port.T); TsPWB0CabiA011013005.port.Q_flow = 0.0; TsPWB0CabiA003014005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003014005.port.T); TsPWB0CabiA003014005.port.Q_flow = 0.0; TsPWB0CabiA004014005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004014005.port.T); TsPWB0CabiA004014005.port.Q_flow = 0.0; TsPWB0CabiA005014005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005014005.port.T); TsPWB0CabiA005014005.port.Q_flow = 0.0; TsPWB0CabiA006014005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006014005.port.T); TsPWB0CabiA006014005.port.Q_flow = 0.0; TsPWB0CabiA007014005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007014005.port.T); TsPWB0CabiA007014005.port.Q_flow = 0.0; TsPWB0CabiA008014005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008014005.port.T); TsPWB0CabiA008014005.port.Q_flow = 0.0; TsPWB0CabiA009014005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009014005.port.T); TsPWB0CabiA009014005.port.Q_flow = 0.0; TsPWB0CabiA010014005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010014005.port.T); TsPWB0CabiA010014005.port.Q_flow = 0.0; TsPWB0CabiA011014005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011014005.port.T); TsPWB0CabiA011014005.port.Q_flow = 0.0; TsPWB0CabiA003006005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003006005.port.T); TsPWB0CabiA003006005.port.Q_flow = 0.0; TsPWB0CabiA004006005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004006005.port.T); TsPWB0CabiA004006005.port.Q_flow = 0.0; TsPWB0CabiA005006005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005006005.port.T); TsPWB0CabiA005006005.port.Q_flow = 0.0; TsPWB0CabiA006006005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006006005.port.T); TsPWB0CabiA006006005.port.Q_flow = 0.0; TsPWB0CabiA007006005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007006005.port.T); TsPWB0CabiA007006005.port.Q_flow = 0.0; TsPWB0CabiA008006005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008006005.port.T); TsPWB0CabiA008006005.port.Q_flow = 0.0; TsPWB0CabiA009006005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009006005.port.T); TsPWB0CabiA009006005.port.Q_flow = 0.0; TsPWB0CabiA010006005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010006005.port.T); TsPWB0CabiA010006005.port.Q_flow = 0.0; TsPWB0CabiA011006005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011006005.port.T); TsPWB0CabiA011006005.port.Q_flow = 0.0; TsPWB0CabiA003007005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003007005.port.T); TsPWB0CabiA003007005.port.Q_flow = 0.0; TsPWB0CabiA004007005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004007005.port.T); TsPWB0CabiA004007005.port.Q_flow = 0.0; TsPWB0CabiA005007005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005007005.port.T); TsPWB0CabiA005007005.port.Q_flow = 0.0; TsPWB0CabiA006007005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006007005.port.T); TsPWB0CabiA006007005.port.Q_flow = 0.0; TsPWB0CabiA007007005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007007005.port.T); TsPWB0CabiA007007005.port.Q_flow = 0.0; TsPWB0CabiA008007005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008007005.port.T); TsPWB0CabiA008007005.port.Q_flow = 0.0; TsPWB0CabiA009007005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009007005.port.T); TsPWB0CabiA009007005.port.Q_flow = 0.0; TsPWB0CabiA010007005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010007005.port.T); TsPWB0CabiA010007005.port.Q_flow = 0.0; TsPWB0CabiA011007005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011007005.port.T); TsPWB0CabiA011007005.port.Q_flow = 0.0; TsPWB0CabiA003008005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003008005.port.T); TsPWB0CabiA003008005.port.Q_flow = 0.0; TsPWB0CabiA004008005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004008005.port.T); TsPWB0CabiA004008005.port.Q_flow = 0.0; TsPWB0CabiA005008005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005008005.port.T); TsPWB0CabiA005008005.port.Q_flow = 0.0; TsPWB0CabiA006008005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006008005.port.T); TsPWB0CabiA006008005.port.Q_flow = 0.0; TsPWB0CabiA007008005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007008005.port.T); TsPWB0CabiA007008005.port.Q_flow = 0.0; TsPWB0CabiA008008005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008008005.port.T); TsPWB0CabiA008008005.port.Q_flow = 0.0; TsPWB0CabiA009008005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009008005.port.T); TsPWB0CabiA009008005.port.Q_flow = 0.0; TsPWB0CabiA010008005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010008005.port.T); TsPWB0CabiA010008005.port.Q_flow = 0.0; TsPWB0CabiA011008005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011008005.port.T); TsPWB0CabiA011008005.port.Q_flow = 0.0; TsPWB0CabiA003009005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003009005.port.T); TsPWB0CabiA003009005.port.Q_flow = 0.0; TsPWB0CabiA004009005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004009005.port.T); TsPWB0CabiA004009005.port.Q_flow = 0.0; TsPWB0CabiA005009005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005009005.port.T); TsPWB0CabiA005009005.port.Q_flow = 0.0; TsPWB0CabiA006009005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006009005.port.T); TsPWB0CabiA006009005.port.Q_flow = 0.0; TsPWB0CabiA007009005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007009005.port.T); TsPWB0CabiA007009005.port.Q_flow = 0.0; TsPWB0CabiA008009005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008009005.port.T); TsPWB0CabiA008009005.port.Q_flow = 0.0; TsPWB0CabiA009009005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009009005.port.T); TsPWB0CabiA009009005.port.Q_flow = 0.0; TsPWB0CabiA010009005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010009005.port.T); TsPWB0CabiA010009005.port.Q_flow = 0.0; TsPWB0CabiA011009005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011009005.port.T); TsPWB0CabiA011009005.port.Q_flow = 0.0; TsPWB0CabiA003010005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003010005.port.T); TsPWB0CabiA003010005.port.Q_flow = 0.0; TsPWB0CabiA004010005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004010005.port.T); TsPWB0CabiA004010005.port.Q_flow = 0.0; TsPWB0CabiA005010005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005010005.port.T); TsPWB0CabiA005010005.port.Q_flow = 0.0; TsPWB0CabiA006010005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006010005.port.T); TsPWB0CabiA006010005.port.Q_flow = 0.0; TsPWB0CabiA007010005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007010005.port.T); TsPWB0CabiA007010005.port.Q_flow = 0.0; TsPWB0CabiA008010005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008010005.port.T); TsPWB0CabiA008010005.port.Q_flow = 0.0; TsPWB0CabiA009010005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009010005.port.T); TsPWB0CabiA009010005.port.Q_flow = 0.0; TsPWB0CabiA010010005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010010005.port.T); TsPWB0CabiA010010005.port.Q_flow = 0.0; TsPWB0CabiA011010005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011010005.port.T); TsPWB0CabiA011010005.port.Q_flow = 0.0; TsPWB0CabiA003003005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003003005.port.T); TsPWB0CabiA003003005.port.Q_flow = 0.0; TsPWB0CabiA004003005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004003005.port.T); TsPWB0CabiA004003005.port.Q_flow = 0.0; TsPWB0CabiA005003005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005003005.port.T); TsPWB0CabiA005003005.port.Q_flow = 0.0; TsPWB0CabiA006003005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006003005.port.T); TsPWB0CabiA006003005.port.Q_flow = 0.0; TsPWB0CabiA007003005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007003005.port.T); TsPWB0CabiA007003005.port.Q_flow = 0.0; TsPWB0CabiA008003005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008003005.port.T); TsPWB0CabiA008003005.port.Q_flow = 0.0; TsPWB0CabiA009003005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009003005.port.T); TsPWB0CabiA009003005.port.Q_flow = 0.0; TsPWB0CabiA010003005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010003005.port.T); TsPWB0CabiA010003005.port.Q_flow = 0.0; TsPWB0CabiA011003005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011003005.port.T); TsPWB0CabiA011003005.port.Q_flow = 0.0; TsPWB0CabiA003004005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003004005.port.T); TsPWB0CabiA003004005.port.Q_flow = 0.0; TsPWB0CabiA004004005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004004005.port.T); TsPWB0CabiA004004005.port.Q_flow = 0.0; TsPWB0CabiA005004005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005004005.port.T); TsPWB0CabiA005004005.port.Q_flow = 0.0; TsPWB0CabiA006004005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006004005.port.T); TsPWB0CabiA006004005.port.Q_flow = 0.0; TsPWB0CabiA007004005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007004005.port.T); TsPWB0CabiA007004005.port.Q_flow = 0.0; TsPWB0CabiA008004005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008004005.port.T); TsPWB0CabiA008004005.port.Q_flow = 0.0; TsPWB0CabiA009004005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009004005.port.T); TsPWB0CabiA009004005.port.Q_flow = 0.0; TsPWB0CabiA010004005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010004005.port.T); TsPWB0CabiA010004005.port.Q_flow = 0.0; TsPWB0CabiA011004005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011004005.port.T); TsPWB0CabiA011004005.port.Q_flow = 0.0; TsPWB0CabiA003005005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA003005005.port.T); TsPWB0CabiA003005005.port.Q_flow = 0.0; TsPWB0CabiA004005005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA004005005.port.T); TsPWB0CabiA004005005.port.Q_flow = 0.0; TsPWB0CabiA005005005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA005005005.port.T); TsPWB0CabiA005005005.port.Q_flow = 0.0; TsPWB0CabiA006005005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA006005005.port.T); TsPWB0CabiA006005005.port.Q_flow = 0.0; TsPWB0CabiA007005005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA007005005.port.T); TsPWB0CabiA007005005.port.Q_flow = 0.0; TsPWB0CabiA008005005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA008005005.port.T); TsPWB0CabiA008005005.port.Q_flow = 0.0; TsPWB0CabiA009005005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA009005005.port.T); TsPWB0CabiA009005005.port.Q_flow = 0.0; TsPWB0CabiA010005005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA010005005.port.T); TsPWB0CabiA010005005.port.Q_flow = 0.0; TsPWB0CabiA011005005.T = Modelica.SIunits.Conversions.to_degC(TsPWB0CabiA011005005.port.T); TsPWB0CabiA011005005.port.Q_flow = 0.0; TsIC50CabiA006004006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA006004006.port.T); TsIC50CabiA006004006.port.Q_flow = 0.0; TsIC50CabiA007004006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA007004006.port.T); TsIC50CabiA007004006.port.Q_flow = 0.0; TsIC50CabiA008004006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA008004006.port.T); TsIC50CabiA008004006.port.Q_flow = 0.0; TsIC50CabiA009004006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA009004006.port.T); TsIC50CabiA009004006.port.Q_flow = 0.0; TsIC50CabiA006005006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA006005006.port.T); TsIC50CabiA006005006.port.Q_flow = 0.0; TsIC50CabiA007005006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA007005006.port.T); TsIC50CabiA007005006.port.Q_flow = 0.0; TsIC50CabiA008005006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA008005006.port.T); TsIC50CabiA008005006.port.Q_flow = 0.0; TsIC50CabiA009005006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA009005006.port.T); TsIC50CabiA009005006.port.Q_flow = 0.0; TsIC50CabiA006006006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA006006006.port.T); TsIC50CabiA006006006.port.Q_flow = 0.0; TsIC50CabiA007006006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA007006006.port.T); TsIC50CabiA007006006.port.Q_flow = 0.0; TsIC50CabiA008006006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA008006006.port.T); TsIC50CabiA008006006.port.Q_flow = 0.0; TsIC50CabiA009006006.T = Modelica.SIunits.Conversions.to_degC(TsIC50CabiA009006006.port.T); TsIC50CabiA009006006.port.Q_flow = 0.0; TsIC40CabiA008009006.T = Modelica.SIunits.Conversions.to_degC(TsIC40CabiA008009006.port.T); TsIC40CabiA008009006.port.Q_flow = 0.0; TsIC40CabiA009009006.T = Modelica.SIunits.Conversions.to_degC(TsIC40CabiA009009006.port.T); TsIC40CabiA009009006.port.Q_flow = 0.0; TsIC40CabiA010009006.T = Modelica.SIunits.Conversions.to_degC(TsIC40CabiA010009006.port.T); TsIC40CabiA010009006.port.Q_flow = 0.0; TsIC40CabiA008010006.T = Modelica.SIunits.Conversions.to_degC(TsIC40CabiA008010006.port.T); TsIC40CabiA008010006.port.Q_flow = 0.0; TsIC40CabiA009010006.T = Modelica.SIunits.Conversions.to_degC(TsIC40CabiA009010006.port.T); TsIC40CabiA009010006.port.Q_flow = 0.0; TsIC40CabiA010010006.T = Modelica.SIunits.Conversions.to_degC(TsIC40CabiA010010006.port.T); TsIC40CabiA010010006.port.Q_flow = 0.0; TsIC40CabiA008011006.T = Modelica.SIunits.Conversions.to_degC(TsIC40CabiA008011006.port.T); TsIC40CabiA008011006.port.Q_flow = 0.0; TsIC40CabiA009011006.T = Modelica.SIunits.Conversions.to_degC(TsIC40CabiA009011006.port.T); TsIC40CabiA009011006.port.Q_flow = 0.0; TsIC40CabiA010011006.T = Modelica.SIunits.Conversions.to_degC(TsIC40CabiA010011006.port.T); TsIC40CabiA010011006.port.Q_flow = 0.0; TsIC10CabiA004011006.T = Modelica.SIunits.Conversions.to_degC(TsIC10CabiA004011006.port.T); TsIC10CabiA004011006.port.Q_flow = 0.0; TsIC10CabiA005011006.T = Modelica.SIunits.Conversions.to_degC(TsIC10CabiA005011006.port.T); TsIC10CabiA005011006.port.Q_flow = 0.0; TsIC10CabiA006011006.T = Modelica.SIunits.Conversions.to_degC(TsIC10CabiA006011006.port.T); TsIC10CabiA006011006.port.Q_flow = 0.0; TsIC10CabiA004012006.T = Modelica.SIunits.Conversions.to_degC(TsIC10CabiA004012006.port.T); TsIC10CabiA004012006.port.Q_flow = 0.0; TsIC10CabiA005012006.T = Modelica.SIunits.Conversions.to_degC(TsIC10CabiA005012006.port.T); TsIC10CabiA005012006.port.Q_flow = 0.0; TsIC10CabiA006012006.T = Modelica.SIunits.Conversions.to_degC(TsIC10CabiA006012006.port.T); TsIC10CabiA006012006.port.Q_flow = 0.0; TsIC10CabiA004013006.T = Modelica.SIunits.Conversions.to_degC(TsIC10CabiA004013006.port.T); TsIC10CabiA004013006.port.Q_flow = 0.0; TsIC10CabiA005013006.T = Modelica.SIunits.Conversions.to_degC(TsIC10CabiA005013006.port.T); TsIC10CabiA005013006.port.Q_flow = 0.0; TsIC10CabiA006013006.T = Modelica.SIunits.Conversions.to_degC(TsIC10CabiA006013006.port.T); TsIC10CabiA006013006.port.Q_flow = 0.0; HFIC609.port.Q_flow + (TsIC60CabiA006013004.port.Q_flow + (TC_1525_1526.port_b.Q_flow + (TC_1523_1526.port_b.Q_flow + (TC_1385_1526.port_b.Q_flow + (TC_1251_1526.port_b.Q_flow + (TC_1241_1526.port_b.Q_flow + (IC60CabiA006013004.port.Q_flow + TC_1526_1548.port_a.Q_flow))))))) = 0.0; HFIC609.port.T = IC60CabiA006013004.port.T; HFIC609.port.T = TC_1241_1526.port_b.T; HFIC609.port.T = TC_1251_1526.port_b.T; HFIC609.port.T = TC_1385_1526.port_b.T; HFIC609.port.T = TC_1523_1526.port_b.T; HFIC609.port.T = TC_1525_1526.port_b.T; HFIC609.port.T = TC_1526_1548.port_a.T; HFIC609.port.T = TsIC60CabiA006013004.port.T; HFIC608.port.Q_flow + (TsIC60CabiA005013004.port.Q_flow + (TC_1524_1525.port_b.Q_flow + (TC_1522_1525.port_b.Q_flow + (TC_1384_1525.port_b.Q_flow + (TC_1250_1525.port_b.Q_flow + (IC60CabiA005013004.port.Q_flow + (TC_1525_1526.port_a.Q_flow + TC_1525_1547.port_a.Q_flow))))))) = 0.0; HFIC608.port.T = IC60CabiA005013004.port.T; HFIC608.port.T = TC_1250_1525.port_b.T; HFIC608.port.T = TC_1384_1525.port_b.T; HFIC608.port.T = TC_1522_1525.port_b.T; HFIC608.port.T = TC_1524_1525.port_b.T; HFIC608.port.T = TC_1525_1526.port_a.T; HFIC608.port.T = TC_1525_1547.port_a.T; HFIC608.port.T = TsIC60CabiA005013004.port.T; HFIC607.port.Q_flow + (TsIC60CabiA004013004.port.Q_flow + (TC_1521_1524.port_b.Q_flow + (TC_1383_1524.port_b.Q_flow + (TC_1249_1524.port_b.Q_flow + (TC_1240_1524.port_b.Q_flow + (IC60CabiA004013004.port.Q_flow + (TC_1524_1525.port_a.Q_flow + TC_1524_1546.port_a.Q_flow))))))) = 0.0; HFIC607.port.T = IC60CabiA004013004.port.T; HFIC607.port.T = TC_1240_1524.port_b.T; HFIC607.port.T = TC_1249_1524.port_b.T; HFIC607.port.T = TC_1383_1524.port_b.T; HFIC607.port.T = TC_1521_1524.port_b.T; HFIC607.port.T = TC_1524_1525.port_a.T; HFIC607.port.T = TC_1524_1546.port_a.T; HFIC607.port.T = TsIC60CabiA004013004.port.T; HFIC606.port.Q_flow + (TsIC60CabiA006012004.port.Q_flow + (TC_1522_1523.port_b.Q_flow + (TC_1520_1523.port_b.Q_flow + (TC_1374_1523.port_b.Q_flow + (TC_1233_1523.port_b.Q_flow + (IC60CabiA006012004.port.Q_flow + (TC_1523_1526.port_a.Q_flow + TC_1523_1539.port_a.Q_flow))))))) = 0.0; HFIC606.port.T = IC60CabiA006012004.port.T; HFIC606.port.T = TC_1233_1523.port_b.T; HFIC606.port.T = TC_1374_1523.port_b.T; HFIC606.port.T = TC_1520_1523.port_b.T; HFIC606.port.T = TC_1522_1523.port_b.T; HFIC606.port.T = TC_1523_1526.port_a.T; HFIC606.port.T = TC_1523_1539.port_a.T; HFIC606.port.T = TsIC60CabiA006012004.port.T; HFIC605.port.Q_flow + (TsIC60CabiA005012004.port.Q_flow + (TC_1521_1522.port_b.Q_flow + (TC_1519_1522.port_b.Q_flow + (TC_1373_1522.port_b.Q_flow + (IC60CabiA005012004.port.Q_flow + (TC_1522_1523.port_a.Q_flow + (TC_1522_1525.port_a.Q_flow + TC_1522_1538.port_a.Q_flow))))))) = 0.0; HFIC605.port.T = IC60CabiA005012004.port.T; HFIC605.port.T = TC_1373_1522.port_b.T; HFIC605.port.T = TC_1519_1522.port_b.T; HFIC605.port.T = TC_1521_1522.port_b.T; HFIC605.port.T = TC_1522_1523.port_a.T; HFIC605.port.T = TC_1522_1525.port_a.T; HFIC605.port.T = TC_1522_1538.port_a.T; HFIC605.port.T = TsIC60CabiA005012004.port.T; HFIC604.port.Q_flow + (TsIC60CabiA004012004.port.Q_flow + (TC_1518_1521.port_b.Q_flow + (TC_1372_1521.port_b.Q_flow + (TC_1232_1521.port_b.Q_flow + (IC60CabiA004012004.port.Q_flow + (TC_1521_1522.port_a.Q_flow + (TC_1521_1524.port_a.Q_flow + TC_1521_1537.port_a.Q_flow))))))) = 0.0; HFIC604.port.T = IC60CabiA004012004.port.T; HFIC604.port.T = TC_1232_1521.port_b.T; HFIC604.port.T = TC_1372_1521.port_b.T; HFIC604.port.T = TC_1518_1521.port_b.T; HFIC604.port.T = TC_1521_1522.port_a.T; HFIC604.port.T = TC_1521_1524.port_a.T; HFIC604.port.T = TC_1521_1537.port_a.T; HFIC604.port.T = TsIC60CabiA004012004.port.T; HFIC603.port.Q_flow + (TsIC60CabiA006011004.port.Q_flow + (TC_1519_1520.port_b.Q_flow + (TC_1363_1520.port_b.Q_flow + (TC_1225_1520.port_b.Q_flow + (TC_1219_1520.port_b.Q_flow + (IC60CabiA006011004.port.Q_flow + (TC_1520_1523.port_a.Q_flow + TC_1520_1530.port_a.Q_flow))))))) = 0.0; HFIC603.port.T = IC60CabiA006011004.port.T; HFIC603.port.T = TC_1219_1520.port_b.T; HFIC603.port.T = TC_1225_1520.port_b.T; HFIC603.port.T = TC_1363_1520.port_b.T; HFIC603.port.T = TC_1519_1520.port_b.T; HFIC603.port.T = TC_1520_1523.port_a.T; HFIC603.port.T = TC_1520_1530.port_a.T; HFIC603.port.T = TsIC60CabiA006011004.port.T; HFIC602.port.Q_flow + (TsIC60CabiA005011004.port.Q_flow + (TC_1518_1519.port_b.Q_flow + (TC_1362_1519.port_b.Q_flow + (TC_1218_1519.port_b.Q_flow + (IC60CabiA005011004.port.Q_flow + (TC_1519_1520.port_a.Q_flow + (TC_1519_1522.port_a.Q_flow + TC_1519_1529.port_a.Q_flow))))))) = 0.0; HFIC602.port.T = IC60CabiA005011004.port.T; HFIC602.port.T = TC_1218_1519.port_b.T; HFIC602.port.T = TC_1362_1519.port_b.T; HFIC602.port.T = TC_1518_1519.port_b.T; HFIC602.port.T = TC_1519_1520.port_a.T; HFIC602.port.T = TC_1519_1522.port_a.T; HFIC602.port.T = TC_1519_1529.port_a.T; HFIC602.port.T = TsIC60CabiA005011004.port.T; HFIC601.port.Q_flow + (TsIC60CabiA004011004.port.Q_flow + (TC_1361_1518.port_b.Q_flow + (TC_1224_1518.port_b.Q_flow + (TC_1217_1518.port_b.Q_flow + (IC60CabiA004011004.port.Q_flow + (TC_1518_1519.port_a.Q_flow + (TC_1518_1521.port_a.Q_flow + TC_1518_1528.port_a.Q_flow))))))) = 0.0; HFIC601.port.T = IC60CabiA004011004.port.T; HFIC601.port.T = TC_1217_1518.port_b.T; HFIC601.port.T = TC_1224_1518.port_b.T; HFIC601.port.T = TC_1361_1518.port_b.T; HFIC601.port.T = TC_1518_1519.port_a.T; HFIC601.port.T = TC_1518_1521.port_a.T; HFIC601.port.T = TC_1518_1528.port_a.T; HFIC601.port.T = TsIC60CabiA004011004.port.T; HFIC512.port.Q_flow + (TsIC50CabiA009006006.port.Q_flow + (TC_1645_1646.port_b.Q_flow + (TC_1642_1646.port_b.Q_flow + (TC_1569_1646.port_b.Q_flow + (TC_1045_1646.port_b.Q_flow + (TC_1035_1646.port_b.Q_flow + (TC_971_1646.port_b.Q_flow + IC50CabiA009006006.port.Q_flow))))))) = 0.0; HFIC512.port.T = IC50CabiA009006006.port.T; HFIC512.port.T = TC_1035_1646.port_b.T; HFIC512.port.T = TC_1045_1646.port_b.T; HFIC512.port.T = TC_1569_1646.port_b.T; HFIC512.port.T = TC_1642_1646.port_b.T; HFIC512.port.T = TC_1645_1646.port_b.T; HFIC512.port.T = TC_971_1646.port_b.T; HFIC512.port.T = TsIC50CabiA009006006.port.T; HFIC511.port.Q_flow + (TsIC50CabiA008006006.port.Q_flow + (TC_1644_1645.port_b.Q_flow + (TC_1641_1645.port_b.Q_flow + (TC_1568_1645.port_b.Q_flow + (TC_1044_1645.port_b.Q_flow + (TC_970_1645.port_b.Q_flow + (IC50CabiA008006006.port.Q_flow + TC_1645_1646.port_a.Q_flow))))))) = 0.0; HFIC511.port.T = IC50CabiA008006006.port.T; HFIC511.port.T = TC_1044_1645.port_b.T; HFIC511.port.T = TC_1568_1645.port_b.T; HFIC511.port.T = TC_1641_1645.port_b.T; HFIC511.port.T = TC_1644_1645.port_b.T; HFIC511.port.T = TC_1645_1646.port_a.T; HFIC511.port.T = TC_970_1645.port_b.T; HFIC511.port.T = TsIC50CabiA008006006.port.T; HFIC510.port.Q_flow + (TsIC50CabiA007006006.port.Q_flow + (TC_1643_1644.port_b.Q_flow + (TC_1640_1644.port_b.Q_flow + (TC_1567_1644.port_b.Q_flow + (TC_1043_1644.port_b.Q_flow + (TC_969_1644.port_b.Q_flow + (IC50CabiA007006006.port.Q_flow + TC_1644_1645.port_a.Q_flow))))))) = 0.0; HFIC510.port.T = IC50CabiA007006006.port.T; HFIC510.port.T = TC_1043_1644.port_b.T; HFIC510.port.T = TC_1567_1644.port_b.T; HFIC510.port.T = TC_1640_1644.port_b.T; HFIC510.port.T = TC_1643_1644.port_b.T; HFIC510.port.T = TC_1644_1645.port_a.T; HFIC510.port.T = TC_969_1644.port_b.T; HFIC510.port.T = TsIC50CabiA007006006.port.T; HFIC509.port.Q_flow + (TsIC50CabiA006006006.port.Q_flow + (TC_1639_1643.port_b.Q_flow + (TC_1566_1643.port_b.Q_flow + (TC_1042_1643.port_b.Q_flow + (TC_1034_1643.port_b.Q_flow + (TC_968_1643.port_b.Q_flow + (IC50CabiA006006006.port.Q_flow + TC_1643_1644.port_a.Q_flow))))))) = 0.0; HFIC509.port.T = IC50CabiA006006006.port.T; HFIC509.port.T = TC_1034_1643.port_b.T; HFIC509.port.T = TC_1042_1643.port_b.T; HFIC509.port.T = TC_1566_1643.port_b.T; HFIC509.port.T = TC_1639_1643.port_b.T; HFIC509.port.T = TC_1643_1644.port_a.T; HFIC509.port.T = TC_968_1643.port_b.T; HFIC509.port.T = TsIC50CabiA006006006.port.T; HFIC508.port.Q_flow + (TsIC50CabiA009005006.port.Q_flow + (TC_1641_1642.port_b.Q_flow + (TC_1638_1642.port_b.Q_flow + (TC_1632_1642.port_b.Q_flow + (TC_1028_1642.port_b.Q_flow + (TC_960_1642.port_b.Q_flow + (IC50CabiA009005006.port.Q_flow + TC_1642_1646.port_a.Q_flow))))))) = 0.0; HFIC508.port.T = IC50CabiA009005006.port.T; HFIC508.port.T = TC_1028_1642.port_b.T; HFIC508.port.T = TC_1632_1642.port_b.T; HFIC508.port.T = TC_1638_1642.port_b.T; HFIC508.port.T = TC_1641_1642.port_b.T; HFIC508.port.T = TC_1642_1646.port_a.T; HFIC508.port.T = TC_960_1642.port_b.T; HFIC508.port.T = TsIC50CabiA009005006.port.T; HFIC507.port.Q_flow + (TsIC50CabiA008005006.port.Q_flow + (TC_1640_1641.port_b.Q_flow + (TC_1637_1641.port_b.Q_flow + (TC_1631_1641.port_b.Q_flow + (TC_959_1641.port_b.Q_flow + (IC50CabiA008005006.port.Q_flow + (TC_1641_1642.port_a.Q_flow + TC_1641_1645.port_a.Q_flow))))))) = 0.0; HFIC507.port.T = IC50CabiA008005006.port.T; HFIC507.port.T = TC_1631_1641.port_b.T; HFIC507.port.T = TC_1637_1641.port_b.T; HFIC507.port.T = TC_1640_1641.port_b.T; HFIC507.port.T = TC_1641_1642.port_a.T; HFIC507.port.T = TC_1641_1645.port_a.T; HFIC507.port.T = TC_959_1641.port_b.T; HFIC507.port.T = TsIC50CabiA008005006.port.T; HFIC506.port.Q_flow + (TsIC50CabiA007005006.port.Q_flow + (TC_1639_1640.port_b.Q_flow + (TC_1636_1640.port_b.Q_flow + (TC_1630_1640.port_b.Q_flow + (TC_958_1640.port_b.Q_flow + (IC50CabiA007005006.port.Q_flow + (TC_1640_1641.port_a.Q_flow + TC_1640_1644.port_a.Q_flow))))))) = 0.0; HFIC506.port.T = IC50CabiA007005006.port.T; HFIC506.port.T = TC_1630_1640.port_b.T; HFIC506.port.T = TC_1636_1640.port_b.T; HFIC506.port.T = TC_1639_1640.port_b.T; HFIC506.port.T = TC_1640_1641.port_a.T; HFIC506.port.T = TC_1640_1644.port_a.T; HFIC506.port.T = TC_958_1640.port_b.T; HFIC506.port.T = TsIC50CabiA007005006.port.T; HFIC505.port.Q_flow + (TsIC50CabiA006005006.port.Q_flow + (TC_1635_1639.port_b.Q_flow + (TC_1629_1639.port_b.Q_flow + (TC_1098_1639.port_b.Q_flow + (TC_957_1639.port_b.Q_flow + (IC50CabiA006005006.port.Q_flow + (TC_1639_1640.port_a.Q_flow + TC_1639_1643.port_a.Q_flow))))))) = 0.0; HFIC505.port.T = IC50CabiA006005006.port.T; HFIC505.port.T = TC_1098_1639.port_b.T; HFIC505.port.T = TC_1629_1639.port_b.T; HFIC505.port.T = TC_1635_1639.port_b.T; HFIC505.port.T = TC_1639_1640.port_a.T; HFIC505.port.T = TC_1639_1643.port_a.T; HFIC505.port.T = TC_957_1639.port_b.T; HFIC505.port.T = TsIC50CabiA006005006.port.T; HFIC504.port.Q_flow + (TsIC50CabiA009004006.port.Q_flow + (TC_1637_1638.port_b.Q_flow + (TC_1623_1638.port_b.Q_flow + (TC_1092_1638.port_b.Q_flow + (TC_1084_1638.port_b.Q_flow + (TC_949_1638.port_b.Q_flow + (IC50CabiA009004006.port.Q_flow + TC_1638_1642.port_a.Q_flow))))))) = 0.0; HFIC504.port.T = IC50CabiA009004006.port.T; HFIC504.port.T = TC_1084_1638.port_b.T; HFIC504.port.T = TC_1092_1638.port_b.T; HFIC504.port.T = TC_1623_1638.port_b.T; HFIC504.port.T = TC_1637_1638.port_b.T; HFIC504.port.T = TC_1638_1642.port_a.T; HFIC504.port.T = TC_949_1638.port_b.T; HFIC504.port.T = TsIC50CabiA009004006.port.T; HFIC503.port.Q_flow + (TsIC50CabiA008004006.port.Q_flow + (TC_1636_1637.port_b.Q_flow + (TC_1622_1637.port_b.Q_flow + (TC_1083_1637.port_b.Q_flow + (TC_948_1637.port_b.Q_flow + (IC50CabiA008004006.port.Q_flow + (TC_1637_1638.port_a.Q_flow + TC_1637_1641.port_a.Q_flow))))))) = 0.0; HFIC503.port.T = IC50CabiA008004006.port.T; HFIC503.port.T = TC_1083_1637.port_b.T; HFIC503.port.T = TC_1622_1637.port_b.T; HFIC503.port.T = TC_1636_1637.port_b.T; HFIC503.port.T = TC_1637_1638.port_a.T; HFIC503.port.T = TC_1637_1641.port_a.T; HFIC503.port.T = TC_948_1637.port_b.T; HFIC503.port.T = TsIC50CabiA008004006.port.T; HFIC502.port.Q_flow + (TsIC50CabiA007004006.port.Q_flow + (TC_1635_1636.port_b.Q_flow + (TC_1621_1636.port_b.Q_flow + (TC_1082_1636.port_b.Q_flow + (TC_947_1636.port_b.Q_flow + (IC50CabiA007004006.port.Q_flow + (TC_1636_1637.port_a.Q_flow + TC_1636_1640.port_a.Q_flow))))))) = 0.0; HFIC502.port.T = IC50CabiA007004006.port.T; HFIC502.port.T = TC_1082_1636.port_b.T; HFIC502.port.T = TC_1621_1636.port_b.T; HFIC502.port.T = TC_1635_1636.port_b.T; HFIC502.port.T = TC_1636_1637.port_a.T; HFIC502.port.T = TC_1636_1640.port_a.T; HFIC502.port.T = TC_947_1636.port_b.T; HFIC502.port.T = TsIC50CabiA007004006.port.T; HFIC501.port.Q_flow + (TsIC50CabiA006004006.port.Q_flow + (TC_1620_1635.port_b.Q_flow + (TC_1091_1635.port_b.Q_flow + (TC_1081_1635.port_b.Q_flow + (TC_946_1635.port_b.Q_flow + (IC50CabiA006004006.port.Q_flow + (TC_1635_1636.port_a.Q_flow + TC_1635_1639.port_a.Q_flow))))))) = 0.0; HFIC501.port.T = IC50CabiA006004006.port.T; HFIC501.port.T = TC_1081_1635.port_b.T; HFIC501.port.T = TC_1091_1635.port_b.T; HFIC501.port.T = TC_1620_1635.port_b.T; HFIC501.port.T = TC_1635_1636.port_a.T; HFIC501.port.T = TC_1635_1639.port_a.T; HFIC501.port.T = TC_946_1635.port_b.T; HFIC501.port.T = TsIC50CabiA006004006.port.T; HFIC409.port.Q_flow + (TsIC40CabiA010011006.port.Q_flow + (TC_1654_1655.port_b.Q_flow + (TC_1652_1655.port_b.Q_flow + (TC_1534_1655.port_b.Q_flow + (TC_995_1655.port_b.Q_flow + (TC_988_1655.port_b.Q_flow + (TC_895_1655.port_b.Q_flow + IC40CabiA010011006.port.Q_flow))))))) = 0.0; HFIC409.port.T = IC40CabiA010011006.port.T; HFIC409.port.T = TC_1534_1655.port_b.T; HFIC409.port.T = TC_1652_1655.port_b.T; HFIC409.port.T = TC_1654_1655.port_b.T; HFIC409.port.T = TC_895_1655.port_b.T; HFIC409.port.T = TC_988_1655.port_b.T; HFIC409.port.T = TC_995_1655.port_b.T; HFIC409.port.T = TsIC40CabiA010011006.port.T; HFIC408.port.Q_flow + (TsIC40CabiA009011006.port.Q_flow + (TC_1653_1654.port_b.Q_flow + (TC_1651_1654.port_b.Q_flow + (TC_1533_1654.port_b.Q_flow + (TC_994_1654.port_b.Q_flow + (TC_894_1654.port_b.Q_flow + (IC40CabiA009011006.port.Q_flow + TC_1654_1655.port_a.Q_flow))))))) = 0.0; HFIC408.port.T = IC40CabiA009011006.port.T; HFIC408.port.T = TC_1533_1654.port_b.T; HFIC408.port.T = TC_1651_1654.port_b.T; HFIC408.port.T = TC_1653_1654.port_b.T; HFIC408.port.T = TC_1654_1655.port_a.T; HFIC408.port.T = TC_894_1654.port_b.T; HFIC408.port.T = TC_994_1654.port_b.T; HFIC408.port.T = TsIC40CabiA009011006.port.T; HFIC407.port.Q_flow + (TsIC40CabiA008011006.port.Q_flow + (TC_1650_1653.port_b.Q_flow + (TC_1532_1653.port_b.Q_flow + (TC_993_1653.port_b.Q_flow + (TC_987_1653.port_b.Q_flow + (TC_893_1653.port_b.Q_flow + (IC40CabiA008011006.port.Q_flow + TC_1653_1654.port_a.Q_flow))))))) = 0.0; HFIC407.port.T = IC40CabiA008011006.port.T; HFIC407.port.T = TC_1532_1653.port_b.T; HFIC407.port.T = TC_1650_1653.port_b.T; HFIC407.port.T = TC_1653_1654.port_a.T; HFIC407.port.T = TC_893_1653.port_b.T; HFIC407.port.T = TC_987_1653.port_b.T; HFIC407.port.T = TC_993_1653.port_b.T; HFIC407.port.T = TsIC40CabiA008011006.port.T; HFIC406.port.Q_flow + (TsIC40CabiA010010006.port.Q_flow + (TC_1651_1652.port_b.Q_flow + (TC_1649_1652.port_b.Q_flow + (TC_1606_1652.port_b.Q_flow + (TC_983_1652.port_b.Q_flow + (TC_884_1652.port_b.Q_flow + (IC40CabiA010010006.port.Q_flow + TC_1652_1655.port_a.Q_flow))))))) = 0.0; HFIC406.port.T = IC40CabiA010010006.port.T; HFIC406.port.T = TC_1606_1652.port_b.T; HFIC406.port.T = TC_1649_1652.port_b.T; HFIC406.port.T = TC_1651_1652.port_b.T; HFIC406.port.T = TC_1652_1655.port_a.T; HFIC406.port.T = TC_884_1652.port_b.T; HFIC406.port.T = TC_983_1652.port_b.T; HFIC406.port.T = TsIC40CabiA010010006.port.T; HFIC405.port.Q_flow + (TsIC40CabiA009010006.port.Q_flow + (TC_1650_1651.port_b.Q_flow + (TC_1648_1651.port_b.Q_flow + (TC_1605_1651.port_b.Q_flow + (TC_883_1651.port_b.Q_flow + (IC40CabiA009010006.port.Q_flow + (TC_1651_1652.port_a.Q_flow + TC_1651_1654.port_a.Q_flow))))))) = 0.0; HFIC405.port.T = IC40CabiA009010006.port.T; HFIC405.port.T = TC_1605_1651.port_b.T; HFIC405.port.T = TC_1648_1651.port_b.T; HFIC405.port.T = TC_1650_1651.port_b.T; HFIC405.port.T = TC_1651_1652.port_a.T; HFIC405.port.T = TC_1651_1654.port_a.T; HFIC405.port.T = TC_883_1651.port_b.T; HFIC405.port.T = TsIC40CabiA009010006.port.T; HFIC404.port.Q_flow + (TsIC40CabiA008010006.port.Q_flow + (TC_1647_1650.port_b.Q_flow + (TC_1604_1650.port_b.Q_flow + (TC_982_1650.port_b.Q_flow + (TC_882_1650.port_b.Q_flow + (IC40CabiA008010006.port.Q_flow + (TC_1650_1651.port_a.Q_flow + TC_1650_1653.port_a.Q_flow))))))) = 0.0; HFIC404.port.T = IC40CabiA008010006.port.T; HFIC404.port.T = TC_1604_1650.port_b.T; HFIC404.port.T = TC_1647_1650.port_b.T; HFIC404.port.T = TC_1650_1651.port_a.T; HFIC404.port.T = TC_1650_1653.port_a.T; HFIC404.port.T = TC_882_1650.port_b.T; HFIC404.port.T = TC_982_1650.port_b.T; HFIC404.port.T = TsIC40CabiA008010006.port.T; HFIC403.port.Q_flow + (TsIC40CabiA010009006.port.Q_flow + (TC_1648_1649.port_b.Q_flow + (TC_1597_1649.port_b.Q_flow + (TC_1057_1649.port_b.Q_flow + (TC_975_1649.port_b.Q_flow + (TC_873_1649.port_b.Q_flow + (IC40CabiA010009006.port.Q_flow + TC_1649_1652.port_a.Q_flow))))))) = 0.0; HFIC403.port.T = IC40CabiA010009006.port.T; HFIC403.port.T = TC_1057_1649.port_b.T; HFIC403.port.T = TC_1597_1649.port_b.T; HFIC403.port.T = TC_1648_1649.port_b.T; HFIC403.port.T = TC_1649_1652.port_a.T; HFIC403.port.T = TC_873_1649.port_b.T; HFIC403.port.T = TC_975_1649.port_b.T; HFIC403.port.T = TsIC40CabiA010009006.port.T; HFIC402.port.Q_flow + (TsIC40CabiA009009006.port.Q_flow + (TC_1647_1648.port_b.Q_flow + (TC_1596_1648.port_b.Q_flow + (TC_1056_1648.port_b.Q_flow + (TC_872_1648.port_b.Q_flow + (IC40CabiA009009006.port.Q_flow + (TC_1648_1649.port_a.Q_flow + TC_1648_1651.port_a.Q_flow))))))) = 0.0; HFIC402.port.T = IC40CabiA009009006.port.T; HFIC402.port.T = TC_1056_1648.port_b.T; HFIC402.port.T = TC_1596_1648.port_b.T; HFIC402.port.T = TC_1647_1648.port_b.T; HFIC402.port.T = TC_1648_1649.port_a.T; HFIC402.port.T = TC_1648_1651.port_a.T; HFIC402.port.T = TC_872_1648.port_b.T; HFIC402.port.T = TsIC40CabiA009009006.port.T; HFIC401.port.Q_flow + (TsIC40CabiA008009006.port.Q_flow + (TC_1595_1647.port_b.Q_flow + (TC_1065_1647.port_b.Q_flow + (TC_1055_1647.port_b.Q_flow + (TC_871_1647.port_b.Q_flow + (IC40CabiA008009006.port.Q_flow + (TC_1647_1648.port_a.Q_flow + TC_1647_1650.port_a.Q_flow))))))) = 0.0; HFIC401.port.T = IC40CabiA008009006.port.T; HFIC401.port.T = TC_1055_1647.port_b.T; HFIC401.port.T = TC_1065_1647.port_b.T; HFIC401.port.T = TC_1595_1647.port_b.T; HFIC401.port.T = TC_1647_1648.port_a.T; HFIC401.port.T = TC_1647_1650.port_a.T; HFIC401.port.T = TC_871_1647.port_b.T; HFIC401.port.T = TsIC40CabiA008009006.port.T; HFIC312.port.Q_flow + (TsIC30CabiA007006004.port.Q_flow + (TC_1507_1508.port_b.Q_flow + (TC_1504_1508.port_b.Q_flow + (TC_1318_1508.port_b.Q_flow + (TC_1193_1508.port_b.Q_flow + (TC_1183_1508.port_b.Q_flow + (IC30CabiA007006004.port.Q_flow + TC_1508_1567.port_a.Q_flow))))))) = 0.0; HFIC312.port.T = IC30CabiA007006004.port.T; HFIC312.port.T = TC_1183_1508.port_b.T; HFIC312.port.T = TC_1193_1508.port_b.T; HFIC312.port.T = TC_1318_1508.port_b.T; HFIC312.port.T = TC_1504_1508.port_b.T; HFIC312.port.T = TC_1507_1508.port_b.T; HFIC312.port.T = TC_1508_1567.port_a.T; HFIC312.port.T = TsIC30CabiA007006004.port.T; HFIC311.port.Q_flow + (TsIC30CabiA006006004.port.Q_flow + (TC_1506_1507.port_b.Q_flow + (TC_1503_1507.port_b.Q_flow + (TC_1317_1507.port_b.Q_flow + (TC_1192_1507.port_b.Q_flow + (IC30CabiA006006004.port.Q_flow + (TC_1507_1508.port_a.Q_flow + TC_1507_1566.port_a.Q_flow))))))) = 0.0; HFIC311.port.T = IC30CabiA006006004.port.T; HFIC311.port.T = TC_1192_1507.port_b.T; HFIC311.port.T = TC_1317_1507.port_b.T; HFIC311.port.T = TC_1503_1507.port_b.T; HFIC311.port.T = TC_1506_1507.port_b.T; HFIC311.port.T = TC_1507_1508.port_a.T; HFIC311.port.T = TC_1507_1566.port_a.T; HFIC311.port.T = TsIC30CabiA006006004.port.T; HFIC310.port.Q_flow + (TsIC30CabiA005006004.port.Q_flow + (TC_1505_1506.port_b.Q_flow + (TC_1502_1506.port_b.Q_flow + (TC_1316_1506.port_b.Q_flow + (TC_1191_1506.port_b.Q_flow + (IC30CabiA005006004.port.Q_flow + (TC_1506_1507.port_a.Q_flow + TC_1506_1565.port_a.Q_flow))))))) = 0.0; HFIC310.port.T = IC30CabiA005006004.port.T; HFIC310.port.T = TC_1191_1506.port_b.T; HFIC310.port.T = TC_1316_1506.port_b.T; HFIC310.port.T = TC_1502_1506.port_b.T; HFIC310.port.T = TC_1505_1506.port_b.T; HFIC310.port.T = TC_1506_1507.port_a.T; HFIC310.port.T = TC_1506_1565.port_a.T; HFIC310.port.T = TsIC30CabiA005006004.port.T; HFIC309.port.Q_flow + (TsIC30CabiA004006004.port.Q_flow + (TC_1501_1505.port_b.Q_flow + (TC_1315_1505.port_b.Q_flow + (TC_1190_1505.port_b.Q_flow + (TC_1182_1505.port_b.Q_flow + (IC30CabiA004006004.port.Q_flow + (TC_1505_1506.port_a.Q_flow + TC_1505_1564.port_a.Q_flow))))))) = 0.0; HFIC309.port.T = IC30CabiA004006004.port.T; HFIC309.port.T = TC_1182_1505.port_b.T; HFIC309.port.T = TC_1190_1505.port_b.T; HFIC309.port.T = TC_1315_1505.port_b.T; HFIC309.port.T = TC_1501_1505.port_b.T; HFIC309.port.T = TC_1505_1506.port_a.T; HFIC309.port.T = TC_1505_1564.port_a.T; HFIC309.port.T = TsIC30CabiA004006004.port.T; HFIC308.port.Q_flow + (TsIC30CabiA007005004.port.Q_flow + (TC_1503_1504.port_b.Q_flow + (TC_1500_1504.port_b.Q_flow + (TC_1307_1504.port_b.Q_flow + (TC_1176_1504.port_b.Q_flow + (IC30CabiA007005004.port.Q_flow + (TC_1504_1508.port_a.Q_flow + TC_1504_1630.port_a.Q_flow))))))) = 0.0; HFIC308.port.T = IC30CabiA007005004.port.T; HFIC308.port.T = TC_1176_1504.port_b.T; HFIC308.port.T = TC_1307_1504.port_b.T; HFIC308.port.T = TC_1500_1504.port_b.T; HFIC308.port.T = TC_1503_1504.port_b.T; HFIC308.port.T = TC_1504_1508.port_a.T; HFIC308.port.T = TC_1504_1630.port_a.T; HFIC308.port.T = TsIC30CabiA007005004.port.T; HFIC307.port.Q_flow + (TsIC30CabiA006005004.port.Q_flow + (TC_1502_1503.port_b.Q_flow + (TC_1499_1503.port_b.Q_flow + (TC_1306_1503.port_b.Q_flow + (IC30CabiA006005004.port.Q_flow + (TC_1503_1504.port_a.Q_flow + (TC_1503_1507.port_a.Q_flow + TC_1503_1629.port_a.Q_flow))))))) = 0.0; HFIC307.port.T = IC30CabiA006005004.port.T; HFIC307.port.T = TC_1306_1503.port_b.T; HFIC307.port.T = TC_1499_1503.port_b.T; HFIC307.port.T = TC_1502_1503.port_b.T; HFIC307.port.T = TC_1503_1504.port_a.T; HFIC307.port.T = TC_1503_1507.port_a.T; HFIC307.port.T = TC_1503_1629.port_a.T; HFIC307.port.T = TsIC30CabiA006005004.port.T; HFIC306.port.Q_flow + (TsIC30CabiA005005004.port.Q_flow + (TC_1501_1502.port_b.Q_flow + (TC_1498_1502.port_b.Q_flow + (TC_1305_1502.port_b.Q_flow + (IC30CabiA005005004.port.Q_flow + (TC_1502_1503.port_a.Q_flow + (TC_1502_1506.port_a.Q_flow + TC_1502_1628.port_a.Q_flow))))))) = 0.0; HFIC306.port.T = IC30CabiA005005004.port.T; HFIC306.port.T = TC_1305_1502.port_b.T; HFIC306.port.T = TC_1498_1502.port_b.T; HFIC306.port.T = TC_1501_1502.port_b.T; HFIC306.port.T = TC_1502_1503.port_a.T; HFIC306.port.T = TC_1502_1506.port_a.T; HFIC306.port.T = TC_1502_1628.port_a.T; HFIC306.port.T = TsIC30CabiA005005004.port.T; HFIC305.port.Q_flow + (TsIC30CabiA004005004.port.Q_flow + (TC_1497_1501.port_b.Q_flow + (TC_1304_1501.port_b.Q_flow + (TC_1175_1501.port_b.Q_flow + (IC30CabiA004005004.port.Q_flow + (TC_1501_1502.port_a.Q_flow + (TC_1501_1505.port_a.Q_flow + TC_1501_1627.port_a.Q_flow))))))) = 0.0; HFIC305.port.T = IC30CabiA004005004.port.T; HFIC305.port.T = TC_1175_1501.port_b.T; HFIC305.port.T = TC_1304_1501.port_b.T; HFIC305.port.T = TC_1497_1501.port_b.T; HFIC305.port.T = TC_1501_1502.port_a.T; HFIC305.port.T = TC_1501_1505.port_a.T; HFIC305.port.T = TC_1501_1627.port_a.T; HFIC305.port.T = TsIC30CabiA004005004.port.T; HFIC304.port.Q_flow + (TsIC30CabiA007004004.port.Q_flow + (TC_1499_1500.port_b.Q_flow + (TC_1296_1500.port_b.Q_flow + (TC_1169_1500.port_b.Q_flow + (TC_1161_1500.port_b.Q_flow + (IC30CabiA007004004.port.Q_flow + (TC_1500_1504.port_a.Q_flow + TC_1500_1621.port_a.Q_flow))))))) = 0.0; HFIC304.port.T = IC30CabiA007004004.port.T; HFIC304.port.T = TC_1161_1500.port_b.T; HFIC304.port.T = TC_1169_1500.port_b.T; HFIC304.port.T = TC_1296_1500.port_b.T; HFIC304.port.T = TC_1499_1500.port_b.T; HFIC304.port.T = TC_1500_1504.port_a.T; HFIC304.port.T = TC_1500_1621.port_a.T; HFIC304.port.T = TsIC30CabiA007004004.port.T; HFIC303.port.Q_flow + (TsIC30CabiA006004004.port.Q_flow + (TC_1498_1499.port_b.Q_flow + (TC_1295_1499.port_b.Q_flow + (TC_1160_1499.port_b.Q_flow + (IC30CabiA006004004.port.Q_flow + (TC_1499_1500.port_a.Q_flow + (TC_1499_1503.port_a.Q_flow + TC_1499_1620.port_a.Q_flow))))))) = 0.0; HFIC303.port.T = IC30CabiA006004004.port.T; HFIC303.port.T = TC_1160_1499.port_b.T; HFIC303.port.T = TC_1295_1499.port_b.T; HFIC303.port.T = TC_1498_1499.port_b.T; HFIC303.port.T = TC_1499_1500.port_a.T; HFIC303.port.T = TC_1499_1503.port_a.T; HFIC303.port.T = TC_1499_1620.port_a.T; HFIC303.port.T = TsIC30CabiA006004004.port.T; HFIC302.port.Q_flow + (TsIC30CabiA005004004.port.Q_flow + (TC_1497_1498.port_b.Q_flow + (TC_1294_1498.port_b.Q_flow + (TC_1159_1498.port_b.Q_flow + (IC30CabiA005004004.port.Q_flow + (TC_1498_1499.port_a.Q_flow + (TC_1498_1502.port_a.Q_flow + TC_1498_1619.port_a.Q_flow))))))) = 0.0; HFIC302.port.T = IC30CabiA005004004.port.T; HFIC302.port.T = TC_1159_1498.port_b.T; HFIC302.port.T = TC_1294_1498.port_b.T; HFIC302.port.T = TC_1497_1498.port_b.T; HFIC302.port.T = TC_1498_1499.port_a.T; HFIC302.port.T = TC_1498_1502.port_a.T; HFIC302.port.T = TC_1498_1619.port_a.T; HFIC302.port.T = TsIC30CabiA005004004.port.T; HFIC301.port.Q_flow + (TsIC30CabiA004004004.port.Q_flow + (TC_1293_1497.port_b.Q_flow + (TC_1168_1497.port_b.Q_flow + (TC_1158_1497.port_b.Q_flow + (IC30CabiA004004004.port.Q_flow + (TC_1497_1498.port_a.Q_flow + (TC_1497_1501.port_a.Q_flow + TC_1497_1618.port_a.Q_flow))))))) = 0.0; HFIC301.port.T = IC30CabiA004004004.port.T; HFIC301.port.T = TC_1158_1497.port_b.T; HFIC301.port.T = TC_1168_1497.port_b.T; HFIC301.port.T = TC_1293_1497.port_b.T; HFIC301.port.T = TC_1497_1498.port_a.T; HFIC301.port.T = TC_1497_1501.port_a.T; HFIC301.port.T = TC_1497_1618.port_a.T; HFIC301.port.T = TsIC30CabiA004004004.port.T; HFIC209.port.Q_flow + (TsIC20CabiA010010004.port.Q_flow + (TC_1516_1517.port_b.Q_flow + (TC_1514_1517.port_b.Q_flow + (TC_1496_1517.port_b.Q_flow + (TC_1228_1517.port_b.Q_flow + (TC_1221_1517.port_b.Q_flow + (IC20CabiA010010004.port.Q_flow + TC_1517_1606.port_a.Q_flow))))))) = 0.0; HFIC209.port.T = IC20CabiA010010004.port.T; HFIC209.port.T = TC_1221_1517.port_b.T; HFIC209.port.T = TC_1228_1517.port_b.T; HFIC209.port.T = TC_1496_1517.port_b.T; HFIC209.port.T = TC_1514_1517.port_b.T; HFIC209.port.T = TC_1516_1517.port_b.T; HFIC209.port.T = TC_1517_1606.port_a.T; HFIC209.port.T = TsIC20CabiA010010004.port.T; HFIC208.port.Q_flow + (TsIC20CabiA009010004.port.Q_flow + (TC_1515_1516.port_b.Q_flow + (TC_1513_1516.port_b.Q_flow + (TC_1495_1516.port_b.Q_flow + (TC_1227_1516.port_b.Q_flow + (IC20CabiA009010004.port.Q_flow + (TC_1516_1517.port_a.Q_flow + TC_1516_1605.port_a.Q_flow))))))) = 0.0; HFIC208.port.T = IC20CabiA009010004.port.T; HFIC208.port.T = TC_1227_1516.port_b.T; HFIC208.port.T = TC_1495_1516.port_b.T; HFIC208.port.T = TC_1513_1516.port_b.T; HFIC208.port.T = TC_1515_1516.port_b.T; HFIC208.port.T = TC_1516_1517.port_a.T; HFIC208.port.T = TC_1516_1605.port_a.T; HFIC208.port.T = TsIC20CabiA009010004.port.T; HFIC207.port.Q_flow + (TsIC20CabiA008010004.port.Q_flow + (TC_1512_1515.port_b.Q_flow + (TC_1494_1515.port_b.Q_flow + (TC_1226_1515.port_b.Q_flow + (TC_1220_1515.port_b.Q_flow + (IC20CabiA008010004.port.Q_flow + (TC_1515_1516.port_a.Q_flow + TC_1515_1604.port_a.Q_flow))))))) = 0.0; HFIC207.port.T = IC20CabiA008010004.port.T; HFIC207.port.T = TC_1220_1515.port_b.T; HFIC207.port.T = TC_1226_1515.port_b.T; HFIC207.port.T = TC_1494_1515.port_b.T; HFIC207.port.T = TC_1512_1515.port_b.T; HFIC207.port.T = TC_1515_1516.port_a.T; HFIC207.port.T = TC_1515_1604.port_a.T; HFIC207.port.T = TsIC20CabiA008010004.port.T; HFIC206.port.Q_flow + (TsIC20CabiA010009004.port.Q_flow + (TC_1513_1514.port_b.Q_flow + (TC_1511_1514.port_b.Q_flow + (TC_1493_1514.port_b.Q_flow + (TC_1213_1514.port_b.Q_flow + (IC20CabiA010009004.port.Q_flow + (TC_1514_1517.port_a.Q_flow + TC_1514_1597.port_a.Q_flow))))))) = 0.0; HFIC206.port.T = IC20CabiA010009004.port.T; HFIC206.port.T = TC_1213_1514.port_b.T; HFIC206.port.T = TC_1493_1514.port_b.T; HFIC206.port.T = TC_1511_1514.port_b.T; HFIC206.port.T = TC_1513_1514.port_b.T; HFIC206.port.T = TC_1514_1517.port_a.T; HFIC206.port.T = TC_1514_1597.port_a.T; HFIC206.port.T = TsIC20CabiA010009004.port.T; HFIC205.port.Q_flow + (TsIC20CabiA009009004.port.Q_flow + (TC_1512_1513.port_b.Q_flow + (TC_1510_1513.port_b.Q_flow + (TC_1492_1513.port_b.Q_flow + (IC20CabiA009009004.port.Q_flow + (TC_1513_1514.port_a.Q_flow + (TC_1513_1516.port_a.Q_flow + TC_1513_1596.port_a.Q_flow))))))) = 0.0; HFIC205.port.T = IC20CabiA009009004.port.T; HFIC205.port.T = TC_1492_1513.port_b.T; HFIC205.port.T = TC_1510_1513.port_b.T; HFIC205.port.T = TC_1512_1513.port_b.T; HFIC205.port.T = TC_1513_1514.port_a.T; HFIC205.port.T = TC_1513_1516.port_a.T; HFIC205.port.T = TC_1513_1596.port_a.T; HFIC205.port.T = TsIC20CabiA009009004.port.T; HFIC204.port.Q_flow + (TsIC20CabiA008009004.port.Q_flow + (TC_1509_1512.port_b.Q_flow + (TC_1491_1512.port_b.Q_flow + (TC_1212_1512.port_b.Q_flow + (IC20CabiA008009004.port.Q_flow + (TC_1512_1513.port_a.Q_flow + (TC_1512_1515.port_a.Q_flow + TC_1512_1595.port_a.Q_flow))))))) = 0.0; HFIC204.port.T = IC20CabiA008009004.port.T; HFIC204.port.T = TC_1212_1512.port_b.T; HFIC204.port.T = TC_1491_1512.port_b.T; HFIC204.port.T = TC_1509_1512.port_b.T; HFIC204.port.T = TC_1512_1513.port_a.T; HFIC204.port.T = TC_1512_1515.port_a.T; HFIC204.port.T = TC_1512_1595.port_a.T; HFIC204.port.T = TsIC20CabiA008009004.port.T; HFIC203.port.Q_flow + (TsIC20CabiA010008004.port.Q_flow + (TC_1510_1511.port_b.Q_flow + (TC_1490_1511.port_b.Q_flow + (TC_1205_1511.port_b.Q_flow + (TC_1196_1511.port_b.Q_flow + (IC20CabiA010008004.port.Q_flow + (TC_1511_1514.port_a.Q_flow + TC_1511_1588.port_a.Q_flow))))))) = 0.0; HFIC203.port.T = IC20CabiA010008004.port.T; HFIC203.port.T = TC_1196_1511.port_b.T; HFIC203.port.T = TC_1205_1511.port_b.T; HFIC203.port.T = TC_1490_1511.port_b.T; HFIC203.port.T = TC_1510_1511.port_b.T; HFIC203.port.T = TC_1511_1514.port_a.T; HFIC203.port.T = TC_1511_1588.port_a.T; HFIC203.port.T = TsIC20CabiA010008004.port.T; HFIC202.port.Q_flow + (TsIC20CabiA009008004.port.Q_flow + (TC_1509_1510.port_b.Q_flow + (TC_1489_1510.port_b.Q_flow + (TC_1195_1510.port_b.Q_flow + (IC20CabiA009008004.port.Q_flow + (TC_1510_1511.port_a.Q_flow + (TC_1510_1513.port_a.Q_flow + TC_1510_1587.port_a.Q_flow))))))) = 0.0; HFIC202.port.T = IC20CabiA009008004.port.T; HFIC202.port.T = TC_1195_1510.port_b.T; HFIC202.port.T = TC_1489_1510.port_b.T; HFIC202.port.T = TC_1509_1510.port_b.T; HFIC202.port.T = TC_1510_1511.port_a.T; HFIC202.port.T = TC_1510_1513.port_a.T; HFIC202.port.T = TC_1510_1587.port_a.T; HFIC202.port.T = TsIC20CabiA009008004.port.T; HFIC201.port.Q_flow + (TsIC20CabiA008008004.port.Q_flow + (TC_1488_1509.port_b.Q_flow + (TC_1204_1509.port_b.Q_flow + (TC_1194_1509.port_b.Q_flow + (IC20CabiA008008004.port.Q_flow + (TC_1509_1510.port_a.Q_flow + (TC_1509_1512.port_a.Q_flow + TC_1509_1586.port_a.Q_flow))))))) = 0.0; HFIC201.port.T = IC20CabiA008008004.port.T; HFIC201.port.T = TC_1194_1509.port_b.T; HFIC201.port.T = TC_1204_1509.port_b.T; HFIC201.port.T = TC_1488_1509.port_b.T; HFIC201.port.T = TC_1509_1510.port_a.T; HFIC201.port.T = TC_1509_1512.port_a.T; HFIC201.port.T = TC_1509_1586.port_a.T; HFIC201.port.T = TsIC20CabiA008008004.port.T; HFIC109.port.Q_flow + (TsIC10CabiA006013006.port.Q_flow + (TC_1663_1664.port_b.Q_flow + (TC_1661_1664.port_b.Q_flow + (TC_1548_1664.port_b.Q_flow + (TC_1010_1664.port_b.Q_flow + (TC_1000_1664.port_b.Q_flow + (TC_913_1664.port_b.Q_flow + IC10CabiA006013006.port.Q_flow))))))) = 0.0; HFIC109.port.T = IC10CabiA006013006.port.T; HFIC109.port.T = TC_1000_1664.port_b.T; HFIC109.port.T = TC_1010_1664.port_b.T; HFIC109.port.T = TC_1548_1664.port_b.T; HFIC109.port.T = TC_1661_1664.port_b.T; HFIC109.port.T = TC_1663_1664.port_b.T; HFIC109.port.T = TC_913_1664.port_b.T; HFIC109.port.T = TsIC10CabiA006013006.port.T; HFIC108.port.Q_flow + (TsIC10CabiA005013006.port.Q_flow + (TC_1662_1663.port_b.Q_flow + (TC_1660_1663.port_b.Q_flow + (TC_1547_1663.port_b.Q_flow + (TC_1009_1663.port_b.Q_flow + (TC_912_1663.port_b.Q_flow + (IC10CabiA005013006.port.Q_flow + TC_1663_1664.port_a.Q_flow))))))) = 0.0; HFIC108.port.T = IC10CabiA005013006.port.T; HFIC108.port.T = TC_1009_1663.port_b.T; HFIC108.port.T = TC_1547_1663.port_b.T; HFIC108.port.T = TC_1660_1663.port_b.T; HFIC108.port.T = TC_1662_1663.port_b.T; HFIC108.port.T = TC_1663_1664.port_a.T; HFIC108.port.T = TC_912_1663.port_b.T; HFIC108.port.T = TsIC10CabiA005013006.port.T; HFIC107.port.Q_flow + (TsIC10CabiA004013006.port.Q_flow + (TC_1659_1662.port_b.Q_flow + (TC_1546_1662.port_b.Q_flow + (TC_1008_1662.port_b.Q_flow + (TC_999_1662.port_b.Q_flow + (TC_911_1662.port_b.Q_flow + (IC10CabiA004013006.port.Q_flow + TC_1662_1663.port_a.Q_flow))))))) = 0.0; HFIC107.port.T = IC10CabiA004013006.port.T; HFIC107.port.T = TC_1008_1662.port_b.T; HFIC107.port.T = TC_1546_1662.port_b.T; HFIC107.port.T = TC_1659_1662.port_b.T; HFIC107.port.T = TC_1662_1663.port_a.T; HFIC107.port.T = TC_911_1662.port_b.T; HFIC107.port.T = TC_999_1662.port_b.T; HFIC107.port.T = TsIC10CabiA004013006.port.T; HFIC106.port.Q_flow + (TsIC10CabiA006012006.port.Q_flow + (TC_1660_1661.port_b.Q_flow + (TC_1658_1661.port_b.Q_flow + (TC_1539_1661.port_b.Q_flow + (TC_992_1661.port_b.Q_flow + (TC_902_1661.port_b.Q_flow + (IC10CabiA006012006.port.Q_flow + TC_1661_1664.port_a.Q_flow))))))) = 0.0; HFIC106.port.T = IC10CabiA006012006.port.T; HFIC106.port.T = TC_1539_1661.port_b.T; HFIC106.port.T = TC_1658_1661.port_b.T; HFIC106.port.T = TC_1660_1661.port_b.T; HFIC106.port.T = TC_1661_1664.port_a.T; HFIC106.port.T = TC_902_1661.port_b.T; HFIC106.port.T = TC_992_1661.port_b.T; HFIC106.port.T = TsIC10CabiA006012006.port.T; HFIC105.port.Q_flow + (TsIC10CabiA005012006.port.Q_flow + (TC_1659_1660.port_b.Q_flow + (TC_1657_1660.port_b.Q_flow + (TC_1538_1660.port_b.Q_flow + (TC_901_1660.port_b.Q_flow + (IC10CabiA005012006.port.Q_flow + (TC_1660_1661.port_a.Q_flow + TC_1660_1663.port_a.Q_flow))))))) = 0.0; HFIC105.port.T = IC10CabiA005012006.port.T; HFIC105.port.T = TC_1538_1660.port_b.T; HFIC105.port.T = TC_1657_1660.port_b.T; HFIC105.port.T = TC_1659_1660.port_b.T; HFIC105.port.T = TC_1660_1661.port_a.T; HFIC105.port.T = TC_1660_1663.port_a.T; HFIC105.port.T = TC_901_1660.port_b.T; HFIC105.port.T = TsIC10CabiA005012006.port.T; HFIC104.port.Q_flow + (TsIC10CabiA004012006.port.Q_flow + (TC_1656_1659.port_b.Q_flow + (TC_1537_1659.port_b.Q_flow + (TC_991_1659.port_b.Q_flow + (TC_900_1659.port_b.Q_flow + (IC10CabiA004012006.port.Q_flow + (TC_1659_1660.port_a.Q_flow + TC_1659_1662.port_a.Q_flow))))))) = 0.0; HFIC104.port.T = IC10CabiA004012006.port.T; HFIC104.port.T = TC_1537_1659.port_b.T; HFIC104.port.T = TC_1656_1659.port_b.T; HFIC104.port.T = TC_1659_1660.port_a.T; HFIC104.port.T = TC_1659_1662.port_a.T; HFIC104.port.T = TC_900_1659.port_b.T; HFIC104.port.T = TC_991_1659.port_b.T; HFIC104.port.T = TsIC10CabiA004012006.port.T; HFIC103.port.Q_flow + (TsIC10CabiA006011006.port.Q_flow + (TC_1657_1658.port_b.Q_flow + (TC_1530_1658.port_b.Q_flow + (TC_987_1658.port_b.Q_flow + (TC_981_1658.port_b.Q_flow + (TC_891_1658.port_b.Q_flow + (IC10CabiA006011006.port.Q_flow + TC_1658_1661.port_a.Q_flow))))))) = 0.0; HFIC103.port.T = IC10CabiA006011006.port.T; HFIC103.port.T = TC_1530_1658.port_b.T; HFIC103.port.T = TC_1657_1658.port_b.T; HFIC103.port.T = TC_1658_1661.port_a.T; HFIC103.port.T = TC_891_1658.port_b.T; HFIC103.port.T = TC_981_1658.port_b.T; HFIC103.port.T = TC_987_1658.port_b.T; HFIC103.port.T = TsIC10CabiA006011006.port.T; HFIC102.port.Q_flow + (TsIC10CabiA005011006.port.Q_flow + (TC_1656_1657.port_b.Q_flow + (TC_1529_1657.port_b.Q_flow + (TC_980_1657.port_b.Q_flow + (TC_890_1657.port_b.Q_flow + (IC10CabiA005011006.port.Q_flow + (TC_1657_1658.port_a.Q_flow + TC_1657_1660.port_a.Q_flow))))))) = 0.0; HFIC102.port.T = IC10CabiA005011006.port.T; HFIC102.port.T = TC_1529_1657.port_b.T; HFIC102.port.T = TC_1656_1657.port_b.T; HFIC102.port.T = TC_1657_1658.port_a.T; HFIC102.port.T = TC_1657_1660.port_a.T; HFIC102.port.T = TC_890_1657.port_b.T; HFIC102.port.T = TC_980_1657.port_b.T; HFIC102.port.T = TsIC10CabiA005011006.port.T; HFIC101.port.Q_flow + (TsIC10CabiA004011006.port.Q_flow + (TC_1528_1656.port_b.Q_flow + (TC_986_1656.port_b.Q_flow + (TC_979_1656.port_b.Q_flow + (TC_889_1656.port_b.Q_flow + (IC10CabiA004011006.port.Q_flow + (TC_1656_1657.port_a.Q_flow + TC_1656_1659.port_a.Q_flow))))))) = 0.0; HFIC101.port.T = IC10CabiA004011006.port.T; HFIC101.port.T = TC_1528_1656.port_b.T; HFIC101.port.T = TC_1656_1657.port_a.T; HFIC101.port.T = TC_1656_1659.port_a.T; HFIC101.port.T = TC_889_1656.port_b.T; HFIC101.port.T = TC_979_1656.port_b.T; HFIC101.port.T = TC_986_1656.port_b.T; HFIC101.port.T = TsIC10CabiA004011006.port.T; TsPWB0CabiA011005005.port.Q_flow + (TC_1633_1634.port_b.Q_flow + (TC_1625_1634.port_b.Q_flow + (TC_1571_1634.port_b.Q_flow + (TC_1179_1634.port_b.Q_flow + (TC_1115_1634.port_b.Q_flow + (TC_1029_1634.port_b.Q_flow + PWB0CabiA011005005.port.Q_flow)))))) = 0.0; PWB0CabiA011005005.port.T = TC_1029_1634.port_b.T; PWB0CabiA011005005.port.T = TC_1115_1634.port_b.T; PWB0CabiA011005005.port.T = TC_1179_1634.port_b.T; PWB0CabiA011005005.port.T = TC_1571_1634.port_b.T; PWB0CabiA011005005.port.T = TC_1625_1634.port_b.T; PWB0CabiA011005005.port.T = TC_1633_1634.port_b.T; PWB0CabiA011005005.port.T = TsPWB0CabiA011005005.port.T; TsPWB0CabiA010005005.port.Q_flow + (TC_1632_1633.port_b.Q_flow + (TC_1624_1633.port_b.Q_flow + (TC_1570_1633.port_b.Q_flow + (TC_1178_1633.port_b.Q_flow + (TC_1028_1633.port_b.Q_flow + (PWB0CabiA010005005.port.Q_flow + TC_1633_1634.port_a.Q_flow)))))) = 0.0; PWB0CabiA010005005.port.T = TC_1028_1633.port_b.T; PWB0CabiA010005005.port.T = TC_1178_1633.port_b.T; PWB0CabiA010005005.port.T = TC_1570_1633.port_b.T; PWB0CabiA010005005.port.T = TC_1624_1633.port_b.T; PWB0CabiA010005005.port.T = TC_1632_1633.port_b.T; PWB0CabiA010005005.port.T = TC_1633_1634.port_a.T; PWB0CabiA010005005.port.T = TsPWB0CabiA010005005.port.T; TsPWB0CabiA009005005.port.Q_flow + (TC_1631_1632.port_b.Q_flow + (TC_1623_1632.port_b.Q_flow + (TC_1569_1632.port_b.Q_flow + (TC_1177_1632.port_b.Q_flow + (PWB0CabiA009005005.port.Q_flow + (TC_1632_1633.port_a.Q_flow + TC_1632_1642.port_a.Q_flow)))))) = 0.0; PWB0CabiA009005005.port.T = TC_1177_1632.port_b.T; PWB0CabiA009005005.port.T = TC_1569_1632.port_b.T; PWB0CabiA009005005.port.T = TC_1623_1632.port_b.T; PWB0CabiA009005005.port.T = TC_1631_1632.port_b.T; PWB0CabiA009005005.port.T = TC_1632_1633.port_a.T; PWB0CabiA009005005.port.T = TC_1632_1642.port_a.T; PWB0CabiA009005005.port.T = TsPWB0CabiA009005005.port.T; TsPWB0CabiA008005005.port.Q_flow + (TC_1630_1631.port_b.Q_flow + (TC_1622_1631.port_b.Q_flow + (TC_1568_1631.port_b.Q_flow + (TC_1176_1631.port_b.Q_flow + (PWB0CabiA008005005.port.Q_flow + (TC_1631_1632.port_a.Q_flow + TC_1631_1641.port_a.Q_flow)))))) = 0.0; PWB0CabiA008005005.port.T = TC_1176_1631.port_b.T; PWB0CabiA008005005.port.T = TC_1568_1631.port_b.T; PWB0CabiA008005005.port.T = TC_1622_1631.port_b.T; PWB0CabiA008005005.port.T = TC_1630_1631.port_b.T; PWB0CabiA008005005.port.T = TC_1631_1632.port_a.T; PWB0CabiA008005005.port.T = TC_1631_1641.port_a.T; PWB0CabiA008005005.port.T = TsPWB0CabiA008005005.port.T; TsPWB0CabiA007005005.port.Q_flow + (TC_1629_1630.port_b.Q_flow + (TC_1621_1630.port_b.Q_flow + (TC_1567_1630.port_b.Q_flow + (TC_1504_1630.port_b.Q_flow + (PWB0CabiA007005005.port.Q_flow + (TC_1630_1631.port_a.Q_flow + TC_1630_1640.port_a.Q_flow)))))) = 0.0; PWB0CabiA007005005.port.T = TC_1504_1630.port_b.T; PWB0CabiA007005005.port.T = TC_1567_1630.port_b.T; PWB0CabiA007005005.port.T = TC_1621_1630.port_b.T; PWB0CabiA007005005.port.T = TC_1629_1630.port_b.T; PWB0CabiA007005005.port.T = TC_1630_1631.port_a.T; PWB0CabiA007005005.port.T = TC_1630_1640.port_a.T; PWB0CabiA007005005.port.T = TsPWB0CabiA007005005.port.T; TsPWB0CabiA006005005.port.Q_flow + (TC_1628_1629.port_b.Q_flow + (TC_1620_1629.port_b.Q_flow + (TC_1566_1629.port_b.Q_flow + (TC_1503_1629.port_b.Q_flow + (PWB0CabiA006005005.port.Q_flow + (TC_1629_1630.port_a.Q_flow + TC_1629_1639.port_a.Q_flow)))))) = 0.0; PWB0CabiA006005005.port.T = TC_1503_1629.port_b.T; PWB0CabiA006005005.port.T = TC_1566_1629.port_b.T; PWB0CabiA006005005.port.T = TC_1620_1629.port_b.T; PWB0CabiA006005005.port.T = TC_1628_1629.port_b.T; PWB0CabiA006005005.port.T = TC_1629_1630.port_a.T; PWB0CabiA006005005.port.T = TC_1629_1639.port_a.T; PWB0CabiA006005005.port.T = TsPWB0CabiA006005005.port.T; TsPWB0CabiA005005005.port.Q_flow + (TC_1627_1628.port_b.Q_flow + (TC_1619_1628.port_b.Q_flow + (TC_1565_1628.port_b.Q_flow + (TC_1502_1628.port_b.Q_flow + (TC_1098_1628.port_b.Q_flow + (PWB0CabiA005005005.port.Q_flow + TC_1628_1629.port_a.Q_flow)))))) = 0.0; PWB0CabiA005005005.port.T = TC_1098_1628.port_b.T; PWB0CabiA005005005.port.T = TC_1502_1628.port_b.T; PWB0CabiA005005005.port.T = TC_1565_1628.port_b.T; PWB0CabiA005005005.port.T = TC_1619_1628.port_b.T; PWB0CabiA005005005.port.T = TC_1627_1628.port_b.T; PWB0CabiA005005005.port.T = TC_1628_1629.port_a.T; PWB0CabiA005005005.port.T = TsPWB0CabiA005005005.port.T; TsPWB0CabiA004005005.port.Q_flow + (TC_1626_1627.port_b.Q_flow + (TC_1618_1627.port_b.Q_flow + (TC_1564_1627.port_b.Q_flow + (TC_1501_1627.port_b.Q_flow + (TC_1097_1627.port_b.Q_flow + (PWB0CabiA004005005.port.Q_flow + TC_1627_1628.port_a.Q_flow)))))) = 0.0; PWB0CabiA004005005.port.T = TC_1097_1627.port_b.T; PWB0CabiA004005005.port.T = TC_1501_1627.port_b.T; PWB0CabiA004005005.port.T = TC_1564_1627.port_b.T; PWB0CabiA004005005.port.T = TC_1618_1627.port_b.T; PWB0CabiA004005005.port.T = TC_1626_1627.port_b.T; PWB0CabiA004005005.port.T = TC_1627_1628.port_a.T; PWB0CabiA004005005.port.T = TsPWB0CabiA004005005.port.T; TsPWB0CabiA003005005.port.Q_flow + (TC_1617_1626.port_b.Q_flow + (TC_1563_1626.port_b.Q_flow + (TC_1175_1626.port_b.Q_flow + (TC_1114_1626.port_b.Q_flow + (TC_1096_1626.port_b.Q_flow + (PWB0CabiA003005005.port.Q_flow + TC_1626_1627.port_a.Q_flow)))))) = 0.0; PWB0CabiA003005005.port.T = TC_1096_1626.port_b.T; PWB0CabiA003005005.port.T = TC_1114_1626.port_b.T; PWB0CabiA003005005.port.T = TC_1175_1626.port_b.T; PWB0CabiA003005005.port.T = TC_1563_1626.port_b.T; PWB0CabiA003005005.port.T = TC_1617_1626.port_b.T; PWB0CabiA003005005.port.T = TC_1626_1627.port_a.T; PWB0CabiA003005005.port.T = TsPWB0CabiA003005005.port.T; TsPWB0CabiA011004005.port.Q_flow + (TC_1624_1625.port_b.Q_flow + (TC_1616_1625.port_b.Q_flow + (TC_1172_1625.port_b.Q_flow + (TC_1113_1625.port_b.Q_flow + (TC_1093_1625.port_b.Q_flow + (PWB0CabiA011004005.port.Q_flow + TC_1625_1634.port_a.Q_flow)))))) = 0.0; PWB0CabiA011004005.port.T = TC_1093_1625.port_b.T; PWB0CabiA011004005.port.T = TC_1113_1625.port_b.T; PWB0CabiA011004005.port.T = TC_1172_1625.port_b.T; PWB0CabiA011004005.port.T = TC_1616_1625.port_b.T; PWB0CabiA011004005.port.T = TC_1624_1625.port_b.T; PWB0CabiA011004005.port.T = TC_1625_1634.port_a.T; PWB0CabiA011004005.port.T = TsPWB0CabiA011004005.port.T; TsPWB0CabiA010004005.port.Q_flow + (TC_1623_1624.port_b.Q_flow + (TC_1615_1624.port_b.Q_flow + (TC_1171_1624.port_b.Q_flow + (TC_1092_1624.port_b.Q_flow + (PWB0CabiA010004005.port.Q_flow + (TC_1624_1625.port_a.Q_flow + TC_1624_1633.port_a.Q_flow)))))) = 0.0; PWB0CabiA010004005.port.T = TC_1092_1624.port_b.T; PWB0CabiA010004005.port.T = TC_1171_1624.port_b.T; PWB0CabiA010004005.port.T = TC_1615_1624.port_b.T; PWB0CabiA010004005.port.T = TC_1623_1624.port_b.T; PWB0CabiA010004005.port.T = TC_1624_1625.port_a.T; PWB0CabiA010004005.port.T = TC_1624_1633.port_a.T; PWB0CabiA010004005.port.T = TsPWB0CabiA010004005.port.T; TsPWB0CabiA009004005.port.Q_flow + (TC_1622_1623.port_b.Q_flow + (TC_1614_1623.port_b.Q_flow + (TC_1170_1623.port_b.Q_flow + (PWB0CabiA009004005.port.Q_flow + (TC_1623_1624.port_a.Q_flow + (TC_1623_1632.port_a.Q_flow + TC_1623_1638.port_a.Q_flow)))))) = 0.0; PWB0CabiA009004005.port.T = TC_1170_1623.port_b.T; PWB0CabiA009004005.port.T = TC_1614_1623.port_b.T; PWB0CabiA009004005.port.T = TC_1622_1623.port_b.T; PWB0CabiA009004005.port.T = TC_1623_1624.port_a.T; PWB0CabiA009004005.port.T = TC_1623_1632.port_a.T; PWB0CabiA009004005.port.T = TC_1623_1638.port_a.T; PWB0CabiA009004005.port.T = TsPWB0CabiA009004005.port.T; TsPWB0CabiA008004005.port.Q_flow + (TC_1621_1622.port_b.Q_flow + (TC_1613_1622.port_b.Q_flow + (TC_1169_1622.port_b.Q_flow + (PWB0CabiA008004005.port.Q_flow + (TC_1622_1623.port_a.Q_flow + (TC_1622_1631.port_a.Q_flow + TC_1622_1637.port_a.Q_flow)))))) = 0.0; PWB0CabiA008004005.port.T = TC_1169_1622.port_b.T; PWB0CabiA008004005.port.T = TC_1613_1622.port_b.T; PWB0CabiA008004005.port.T = TC_1621_1622.port_b.T; PWB0CabiA008004005.port.T = TC_1622_1623.port_a.T; PWB0CabiA008004005.port.T = TC_1622_1631.port_a.T; PWB0CabiA008004005.port.T = TC_1622_1637.port_a.T; PWB0CabiA008004005.port.T = TsPWB0CabiA008004005.port.T; TsPWB0CabiA007004005.port.Q_flow + (TC_1620_1621.port_b.Q_flow + (TC_1612_1621.port_b.Q_flow + (TC_1500_1621.port_b.Q_flow + (PWB0CabiA007004005.port.Q_flow + (TC_1621_1622.port_a.Q_flow + (TC_1621_1630.port_a.Q_flow + TC_1621_1636.port_a.Q_flow)))))) = 0.0; PWB0CabiA007004005.port.T = TC_1500_1621.port_b.T; PWB0CabiA007004005.port.T = TC_1612_1621.port_b.T; PWB0CabiA007004005.port.T = TC_1620_1621.port_b.T; PWB0CabiA007004005.port.T = TC_1621_1622.port_a.T; PWB0CabiA007004005.port.T = TC_1621_1630.port_a.T; PWB0CabiA007004005.port.T = TC_1621_1636.port_a.T; PWB0CabiA007004005.port.T = TsPWB0CabiA007004005.port.T; TsPWB0CabiA006004005.port.Q_flow + (TC_1619_1620.port_b.Q_flow + (TC_1611_1620.port_b.Q_flow + (TC_1499_1620.port_b.Q_flow + (PWB0CabiA006004005.port.Q_flow + (TC_1620_1621.port_a.Q_flow + (TC_1620_1629.port_a.Q_flow + TC_1620_1635.port_a.Q_flow)))))) = 0.0; PWB0CabiA006004005.port.T = TC_1499_1620.port_b.T; PWB0CabiA006004005.port.T = TC_1611_1620.port_b.T; PWB0CabiA006004005.port.T = TC_1619_1620.port_b.T; PWB0CabiA006004005.port.T = TC_1620_1621.port_a.T; PWB0CabiA006004005.port.T = TC_1620_1629.port_a.T; PWB0CabiA006004005.port.T = TC_1620_1635.port_a.T; PWB0CabiA006004005.port.T = TsPWB0CabiA006004005.port.T; TsPWB0CabiA005004005.port.Q_flow + (TC_1618_1619.port_b.Q_flow + (TC_1610_1619.port_b.Q_flow + (TC_1498_1619.port_b.Q_flow + (TC_1091_1619.port_b.Q_flow + (PWB0CabiA005004005.port.Q_flow + (TC_1619_1620.port_a.Q_flow + TC_1619_1628.port_a.Q_flow)))))) = 0.0; PWB0CabiA005004005.port.T = TC_1091_1619.port_b.T; PWB0CabiA005004005.port.T = TC_1498_1619.port_b.T; PWB0CabiA005004005.port.T = TC_1610_1619.port_b.T; PWB0CabiA005004005.port.T = TC_1618_1619.port_b.T; PWB0CabiA005004005.port.T = TC_1619_1620.port_a.T; PWB0CabiA005004005.port.T = TC_1619_1628.port_a.T; PWB0CabiA005004005.port.T = TsPWB0CabiA005004005.port.T; TsPWB0CabiA004004005.port.Q_flow + (TC_1617_1618.port_b.Q_flow + (TC_1609_1618.port_b.Q_flow + (TC_1497_1618.port_b.Q_flow + (TC_1090_1618.port_b.Q_flow + (PWB0CabiA004004005.port.Q_flow + (TC_1618_1619.port_a.Q_flow + TC_1618_1627.port_a.Q_flow)))))) = 0.0; PWB0CabiA004004005.port.T = TC_1090_1618.port_b.T; PWB0CabiA004004005.port.T = TC_1497_1618.port_b.T; PWB0CabiA004004005.port.T = TC_1609_1618.port_b.T; PWB0CabiA004004005.port.T = TC_1617_1618.port_b.T; PWB0CabiA004004005.port.T = TC_1618_1619.port_a.T; PWB0CabiA004004005.port.T = TC_1618_1627.port_a.T; PWB0CabiA004004005.port.T = TsPWB0CabiA004004005.port.T; TsPWB0CabiA003004005.port.Q_flow + (TC_1608_1617.port_b.Q_flow + (TC_1168_1617.port_b.Q_flow + (TC_1112_1617.port_b.Q_flow + (TC_1089_1617.port_b.Q_flow + (PWB0CabiA003004005.port.Q_flow + (TC_1617_1618.port_a.Q_flow + TC_1617_1626.port_a.Q_flow)))))) = 0.0; PWB0CabiA003004005.port.T = TC_1089_1617.port_b.T; PWB0CabiA003004005.port.T = TC_1112_1617.port_b.T; PWB0CabiA003004005.port.T = TC_1168_1617.port_b.T; PWB0CabiA003004005.port.T = TC_1608_1617.port_b.T; PWB0CabiA003004005.port.T = TC_1617_1618.port_a.T; PWB0CabiA003004005.port.T = TC_1617_1626.port_a.T; PWB0CabiA003004005.port.T = TsPWB0CabiA003004005.port.T; TsPWB0CabiA011003005.port.Q_flow + (TC_1615_1616.port_b.Q_flow + (TC_1165_1616.port_b.Q_flow + (TC_1111_1616.port_b.Q_flow + (TC_1108_1616.port_b.Q_flow + (TC_1086_1616.port_b.Q_flow + (PWB0CabiA011003005.port.Q_flow + TC_1616_1625.port_a.Q_flow)))))) = 0.0; PWB0CabiA011003005.port.T = TC_1086_1616.port_b.T; PWB0CabiA011003005.port.T = TC_1108_1616.port_b.T; PWB0CabiA011003005.port.T = TC_1111_1616.port_b.T; PWB0CabiA011003005.port.T = TC_1165_1616.port_b.T; PWB0CabiA011003005.port.T = TC_1615_1616.port_b.T; PWB0CabiA011003005.port.T = TC_1616_1625.port_a.T; PWB0CabiA011003005.port.T = TsPWB0CabiA011003005.port.T; TsPWB0CabiA010003005.port.Q_flow + (TC_1614_1615.port_b.Q_flow + (TC_1164_1615.port_b.Q_flow + (TC_1107_1615.port_b.Q_flow + (TC_1085_1615.port_b.Q_flow + (PWB0CabiA010003005.port.Q_flow + (TC_1615_1616.port_a.Q_flow + TC_1615_1624.port_a.Q_flow)))))) = 0.0; PWB0CabiA010003005.port.T = TC_1085_1615.port_b.T; PWB0CabiA010003005.port.T = TC_1107_1615.port_b.T; PWB0CabiA010003005.port.T = TC_1164_1615.port_b.T; PWB0CabiA010003005.port.T = TC_1614_1615.port_b.T; PWB0CabiA010003005.port.T = TC_1615_1616.port_a.T; PWB0CabiA010003005.port.T = TC_1615_1624.port_a.T; PWB0CabiA010003005.port.T = TsPWB0CabiA010003005.port.T; TsPWB0CabiA009003005.port.Q_flow + (TC_1613_1614.port_b.Q_flow + (TC_1163_1614.port_b.Q_flow + (TC_1106_1614.port_b.Q_flow + (TC_1084_1614.port_b.Q_flow + (PWB0CabiA009003005.port.Q_flow + (TC_1614_1615.port_a.Q_flow + TC_1614_1623.port_a.Q_flow)))))) = 0.0; PWB0CabiA009003005.port.T = TC_1084_1614.port_b.T; PWB0CabiA009003005.port.T = TC_1106_1614.port_b.T; PWB0CabiA009003005.port.T = TC_1163_1614.port_b.T; PWB0CabiA009003005.port.T = TC_1613_1614.port_b.T; PWB0CabiA009003005.port.T = TC_1614_1615.port_a.T; PWB0CabiA009003005.port.T = TC_1614_1623.port_a.T; PWB0CabiA009003005.port.T = TsPWB0CabiA009003005.port.T; TsPWB0CabiA008003005.port.Q_flow + (TC_1612_1613.port_b.Q_flow + (TC_1162_1613.port_b.Q_flow + (TC_1105_1613.port_b.Q_flow + (TC_1083_1613.port_b.Q_flow + (PWB0CabiA008003005.port.Q_flow + (TC_1613_1614.port_a.Q_flow + TC_1613_1622.port_a.Q_flow)))))) = 0.0; PWB0CabiA008003005.port.T = TC_1083_1613.port_b.T; PWB0CabiA008003005.port.T = TC_1105_1613.port_b.T; PWB0CabiA008003005.port.T = TC_1162_1613.port_b.T; PWB0CabiA008003005.port.T = TC_1612_1613.port_b.T; PWB0CabiA008003005.port.T = TC_1613_1614.port_a.T; PWB0CabiA008003005.port.T = TC_1613_1622.port_a.T; PWB0CabiA008003005.port.T = TsPWB0CabiA008003005.port.T; TsPWB0CabiA007003005.port.Q_flow + (TC_1611_1612.port_b.Q_flow + (TC_1161_1612.port_b.Q_flow + (TC_1104_1612.port_b.Q_flow + (TC_1082_1612.port_b.Q_flow + (PWB0CabiA007003005.port.Q_flow + (TC_1612_1613.port_a.Q_flow + TC_1612_1621.port_a.Q_flow)))))) = 0.0; PWB0CabiA007003005.port.T = TC_1082_1612.port_b.T; PWB0CabiA007003005.port.T = TC_1104_1612.port_b.T; PWB0CabiA007003005.port.T = TC_1161_1612.port_b.T; PWB0CabiA007003005.port.T = TC_1611_1612.port_b.T; PWB0CabiA007003005.port.T = TC_1612_1613.port_a.T; PWB0CabiA007003005.port.T = TC_1612_1621.port_a.T; PWB0CabiA007003005.port.T = TsPWB0CabiA007003005.port.T; TsPWB0CabiA006003005.port.Q_flow + (TC_1610_1611.port_b.Q_flow + (TC_1160_1611.port_b.Q_flow + (TC_1103_1611.port_b.Q_flow + (TC_1081_1611.port_b.Q_flow + (PWB0CabiA006003005.port.Q_flow + (TC_1611_1612.port_a.Q_flow + TC_1611_1620.port_a.Q_flow)))))) = 0.0; PWB0CabiA006003005.port.T = TC_1081_1611.port_b.T; PWB0CabiA006003005.port.T = TC_1103_1611.port_b.T; PWB0CabiA006003005.port.T = TC_1160_1611.port_b.T; PWB0CabiA006003005.port.T = TC_1610_1611.port_b.T; PWB0CabiA006003005.port.T = TC_1611_1612.port_a.T; PWB0CabiA006003005.port.T = TC_1611_1620.port_a.T; PWB0CabiA006003005.port.T = TsPWB0CabiA006003005.port.T; TsPWB0CabiA005003005.port.Q_flow + (TC_1609_1610.port_b.Q_flow + (TC_1159_1610.port_b.Q_flow + (TC_1102_1610.port_b.Q_flow + (TC_1080_1610.port_b.Q_flow + (PWB0CabiA005003005.port.Q_flow + (TC_1610_1611.port_a.Q_flow + TC_1610_1619.port_a.Q_flow)))))) = 0.0; PWB0CabiA005003005.port.T = TC_1080_1610.port_b.T; PWB0CabiA005003005.port.T = TC_1102_1610.port_b.T; PWB0CabiA005003005.port.T = TC_1159_1610.port_b.T; PWB0CabiA005003005.port.T = TC_1609_1610.port_b.T; PWB0CabiA005003005.port.T = TC_1610_1611.port_a.T; PWB0CabiA005003005.port.T = TC_1610_1619.port_a.T; PWB0CabiA005003005.port.T = TsPWB0CabiA005003005.port.T; TsPWB0CabiA004003005.port.Q_flow + (TC_1608_1609.port_b.Q_flow + (TC_1158_1609.port_b.Q_flow + (TC_1101_1609.port_b.Q_flow + (TC_1079_1609.port_b.Q_flow + (PWB0CabiA004003005.port.Q_flow + (TC_1609_1610.port_a.Q_flow + TC_1609_1618.port_a.Q_flow)))))) = 0.0; PWB0CabiA004003005.port.T = TC_1079_1609.port_b.T; PWB0CabiA004003005.port.T = TC_1101_1609.port_b.T; PWB0CabiA004003005.port.T = TC_1158_1609.port_b.T; PWB0CabiA004003005.port.T = TC_1608_1609.port_b.T; PWB0CabiA004003005.port.T = TC_1609_1610.port_a.T; PWB0CabiA004003005.port.T = TC_1609_1618.port_a.T; PWB0CabiA004003005.port.T = TsPWB0CabiA004003005.port.T; TsPWB0CabiA003003005.port.Q_flow + (TC_1157_1608.port_b.Q_flow + (TC_1110_1608.port_b.Q_flow + (TC_1100_1608.port_b.Q_flow + (TC_1078_1608.port_b.Q_flow + (PWB0CabiA003003005.port.Q_flow + (TC_1608_1609.port_a.Q_flow + TC_1608_1617.port_a.Q_flow)))))) = 0.0; PWB0CabiA003003005.port.T = TC_1078_1608.port_b.T; PWB0CabiA003003005.port.T = TC_1100_1608.port_b.T; PWB0CabiA003003005.port.T = TC_1110_1608.port_b.T; PWB0CabiA003003005.port.T = TC_1157_1608.port_b.T; PWB0CabiA003003005.port.T = TC_1608_1609.port_a.T; PWB0CabiA003003005.port.T = TC_1608_1617.port_a.T; PWB0CabiA003003005.port.T = TsPWB0CabiA003003005.port.T; TsPWB0CabiA011010005.port.Q_flow + (TC_1606_1607.port_b.Q_flow + (TC_1598_1607.port_b.Q_flow + (TC_1535_1607.port_b.Q_flow + (TC_1221_1607.port_b.Q_flow + (TC_1125_1607.port_b.Q_flow + (TC_983_1607.port_b.Q_flow + PWB0CabiA011010005.port.Q_flow)))))) = 0.0; PWB0CabiA011010005.port.T = TC_1125_1607.port_b.T; PWB0CabiA011010005.port.T = TC_1221_1607.port_b.T; PWB0CabiA011010005.port.T = TC_1535_1607.port_b.T; PWB0CabiA011010005.port.T = TC_1598_1607.port_b.T; PWB0CabiA011010005.port.T = TC_1606_1607.port_b.T; PWB0CabiA011010005.port.T = TC_983_1607.port_b.T; PWB0CabiA011010005.port.T = TsPWB0CabiA011010005.port.T; TsPWB0CabiA010010005.port.Q_flow + (TC_1605_1606.port_b.Q_flow + (TC_1597_1606.port_b.Q_flow + (TC_1534_1606.port_b.Q_flow + (TC_1517_1606.port_b.Q_flow + (PWB0CabiA010010005.port.Q_flow + (TC_1606_1607.port_a.Q_flow + TC_1606_1652.port_a.Q_flow)))))) = 0.0; PWB0CabiA010010005.port.T = TC_1517_1606.port_b.T; PWB0CabiA010010005.port.T = TC_1534_1606.port_b.T; PWB0CabiA010010005.port.T = TC_1597_1606.port_b.T; PWB0CabiA010010005.port.T = TC_1605_1606.port_b.T; PWB0CabiA010010005.port.T = TC_1606_1607.port_a.T; PWB0CabiA010010005.port.T = TC_1606_1652.port_a.T; PWB0CabiA010010005.port.T = TsPWB0CabiA010010005.port.T; TsPWB0CabiA009010005.port.Q_flow + (TC_1604_1605.port_b.Q_flow + (TC_1596_1605.port_b.Q_flow + (TC_1533_1605.port_b.Q_flow + (TC_1516_1605.port_b.Q_flow + (PWB0CabiA009010005.port.Q_flow + (TC_1605_1606.port_a.Q_flow + TC_1605_1651.port_a.Q_flow)))))) = 0.0; PWB0CabiA009010005.port.T = TC_1516_1605.port_b.T; PWB0CabiA009010005.port.T = TC_1533_1605.port_b.T; PWB0CabiA009010005.port.T = TC_1596_1605.port_b.T; PWB0CabiA009010005.port.T = TC_1604_1605.port_b.T; PWB0CabiA009010005.port.T = TC_1605_1606.port_a.T; PWB0CabiA009010005.port.T = TC_1605_1651.port_a.T; PWB0CabiA009010005.port.T = TsPWB0CabiA009010005.port.T; TsPWB0CabiA008010005.port.Q_flow + (TC_1603_1604.port_b.Q_flow + (TC_1595_1604.port_b.Q_flow + (TC_1532_1604.port_b.Q_flow + (TC_1515_1604.port_b.Q_flow + (PWB0CabiA008010005.port.Q_flow + (TC_1604_1605.port_a.Q_flow + TC_1604_1650.port_a.Q_flow)))))) = 0.0; PWB0CabiA008010005.port.T = TC_1515_1604.port_b.T; PWB0CabiA008010005.port.T = TC_1532_1604.port_b.T; PWB0CabiA008010005.port.T = TC_1595_1604.port_b.T; PWB0CabiA008010005.port.T = TC_1603_1604.port_b.T; PWB0CabiA008010005.port.T = TC_1604_1605.port_a.T; PWB0CabiA008010005.port.T = TC_1604_1650.port_a.T; PWB0CabiA008010005.port.T = TsPWB0CabiA008010005.port.T; TsPWB0CabiA007010005.port.Q_flow + (TC_1602_1603.port_b.Q_flow + (TC_1594_1603.port_b.Q_flow + (TC_1531_1603.port_b.Q_flow + (TC_1220_1603.port_b.Q_flow + (TC_982_1603.port_b.Q_flow + (PWB0CabiA007010005.port.Q_flow + TC_1603_1604.port_a.Q_flow)))))) = 0.0; PWB0CabiA007010005.port.T = TC_1220_1603.port_b.T; PWB0CabiA007010005.port.T = TC_1531_1603.port_b.T; PWB0CabiA007010005.port.T = TC_1594_1603.port_b.T; PWB0CabiA007010005.port.T = TC_1602_1603.port_b.T; PWB0CabiA007010005.port.T = TC_1603_1604.port_a.T; PWB0CabiA007010005.port.T = TC_982_1603.port_b.T; PWB0CabiA007010005.port.T = TsPWB0CabiA007010005.port.T; TsPWB0CabiA006010005.port.Q_flow + (TC_1601_1602.port_b.Q_flow + (TC_1593_1602.port_b.Q_flow + (TC_1530_1602.port_b.Q_flow + (TC_1219_1602.port_b.Q_flow + (TC_981_1602.port_b.Q_flow + (PWB0CabiA006010005.port.Q_flow + TC_1602_1603.port_a.Q_flow)))))) = 0.0; PWB0CabiA006010005.port.T = TC_1219_1602.port_b.T; PWB0CabiA006010005.port.T = TC_1530_1602.port_b.T; PWB0CabiA006010005.port.T = TC_1593_1602.port_b.T; PWB0CabiA006010005.port.T = TC_1601_1602.port_b.T; PWB0CabiA006010005.port.T = TC_1602_1603.port_a.T; PWB0CabiA006010005.port.T = TC_981_1602.port_b.T; PWB0CabiA006010005.port.T = TsPWB0CabiA006010005.port.T; TsPWB0CabiA005010005.port.Q_flow + (TC_1600_1601.port_b.Q_flow + (TC_1592_1601.port_b.Q_flow + (TC_1529_1601.port_b.Q_flow + (TC_1218_1601.port_b.Q_flow + (TC_980_1601.port_b.Q_flow + (PWB0CabiA005010005.port.Q_flow + TC_1601_1602.port_a.Q_flow)))))) = 0.0; PWB0CabiA005010005.port.T = TC_1218_1601.port_b.T; PWB0CabiA005010005.port.T = TC_1529_1601.port_b.T; PWB0CabiA005010005.port.T = TC_1592_1601.port_b.T; PWB0CabiA005010005.port.T = TC_1600_1601.port_b.T; PWB0CabiA005010005.port.T = TC_1601_1602.port_a.T; PWB0CabiA005010005.port.T = TC_980_1601.port_b.T; PWB0CabiA005010005.port.T = TsPWB0CabiA005010005.port.T; TsPWB0CabiA004010005.port.Q_flow + (TC_1599_1600.port_b.Q_flow + (TC_1591_1600.port_b.Q_flow + (TC_1528_1600.port_b.Q_flow + (TC_1217_1600.port_b.Q_flow + (TC_979_1600.port_b.Q_flow + (PWB0CabiA004010005.port.Q_flow + TC_1600_1601.port_a.Q_flow)))))) = 0.0; PWB0CabiA004010005.port.T = TC_1217_1600.port_b.T; PWB0CabiA004010005.port.T = TC_1528_1600.port_b.T; PWB0CabiA004010005.port.T = TC_1591_1600.port_b.T; PWB0CabiA004010005.port.T = TC_1599_1600.port_b.T; PWB0CabiA004010005.port.T = TC_1600_1601.port_a.T; PWB0CabiA004010005.port.T = TC_979_1600.port_b.T; PWB0CabiA004010005.port.T = TsPWB0CabiA004010005.port.T; TsPWB0CabiA003010005.port.Q_flow + (TC_1590_1599.port_b.Q_flow + (TC_1527_1599.port_b.Q_flow + (TC_1216_1599.port_b.Q_flow + (TC_1124_1599.port_b.Q_flow + (TC_978_1599.port_b.Q_flow + (PWB0CabiA003010005.port.Q_flow + TC_1599_1600.port_a.Q_flow)))))) = 0.0; PWB0CabiA003010005.port.T = TC_1124_1599.port_b.T; PWB0CabiA003010005.port.T = TC_1216_1599.port_b.T; PWB0CabiA003010005.port.T = TC_1527_1599.port_b.T; PWB0CabiA003010005.port.T = TC_1590_1599.port_b.T; PWB0CabiA003010005.port.T = TC_1599_1600.port_a.T; PWB0CabiA003010005.port.T = TC_978_1599.port_b.T; PWB0CabiA003010005.port.T = TsPWB0CabiA003010005.port.T; TsPWB0CabiA011009005.port.Q_flow + (TC_1597_1598.port_b.Q_flow + (TC_1589_1598.port_b.Q_flow + (TC_1213_1598.port_b.Q_flow + (TC_1123_1598.port_b.Q_flow + (TC_975_1598.port_b.Q_flow + (PWB0CabiA011009005.port.Q_flow + TC_1598_1607.port_a.Q_flow)))))) = 0.0; PWB0CabiA011009005.port.T = TC_1123_1598.port_b.T; PWB0CabiA011009005.port.T = TC_1213_1598.port_b.T; PWB0CabiA011009005.port.T = TC_1589_1598.port_b.T; PWB0CabiA011009005.port.T = TC_1597_1598.port_b.T; PWB0CabiA011009005.port.T = TC_1598_1607.port_a.T; PWB0CabiA011009005.port.T = TC_975_1598.port_b.T; PWB0CabiA011009005.port.T = TsPWB0CabiA011009005.port.T; TsPWB0CabiA010009005.port.Q_flow + (TC_1596_1597.port_b.Q_flow + (TC_1588_1597.port_b.Q_flow + (TC_1514_1597.port_b.Q_flow + (PWB0CabiA010009005.port.Q_flow + (TC_1597_1598.port_a.Q_flow + (TC_1597_1606.port_a.Q_flow + TC_1597_1649.port_a.Q_flow)))))) = 0.0; PWB0CabiA010009005.port.T = TC_1514_1597.port_b.T; PWB0CabiA010009005.port.T = TC_1588_1597.port_b.T; PWB0CabiA010009005.port.T = TC_1596_1597.port_b.T; PWB0CabiA010009005.port.T = TC_1597_1598.port_a.T; PWB0CabiA010009005.port.T = TC_1597_1606.port_a.T; PWB0CabiA010009005.port.T = TC_1597_1649.port_a.T; PWB0CabiA010009005.port.T = TsPWB0CabiA010009005.port.T; TsPWB0CabiA009009005.port.Q_flow + (TC_1595_1596.port_b.Q_flow + (TC_1587_1596.port_b.Q_flow + (TC_1513_1596.port_b.Q_flow + (PWB0CabiA009009005.port.Q_flow + (TC_1596_1597.port_a.Q_flow + (TC_1596_1605.port_a.Q_flow + TC_1596_1648.port_a.Q_flow)))))) = 0.0; PWB0CabiA009009005.port.T = TC_1513_1596.port_b.T; PWB0CabiA009009005.port.T = TC_1587_1596.port_b.T; PWB0CabiA009009005.port.T = TC_1595_1596.port_b.T; PWB0CabiA009009005.port.T = TC_1596_1597.port_a.T; PWB0CabiA009009005.port.T = TC_1596_1605.port_a.T; PWB0CabiA009009005.port.T = TC_1596_1648.port_a.T; PWB0CabiA009009005.port.T = TsPWB0CabiA009009005.port.T; TsPWB0CabiA008009005.port.Q_flow + (TC_1594_1595.port_b.Q_flow + (TC_1586_1595.port_b.Q_flow + (TC_1512_1595.port_b.Q_flow + (PWB0CabiA008009005.port.Q_flow + (TC_1595_1596.port_a.Q_flow + (TC_1595_1604.port_a.Q_flow + TC_1595_1647.port_a.Q_flow)))))) = 0.0; PWB0CabiA008009005.port.T = TC_1512_1595.port_b.T; PWB0CabiA008009005.port.T = TC_1586_1595.port_b.T; PWB0CabiA008009005.port.T = TC_1594_1595.port_b.T; PWB0CabiA008009005.port.T = TC_1595_1596.port_a.T; PWB0CabiA008009005.port.T = TC_1595_1604.port_a.T; PWB0CabiA008009005.port.T = TC_1595_1647.port_a.T; PWB0CabiA008009005.port.T = TsPWB0CabiA008009005.port.T; TsPWB0CabiA007009005.port.Q_flow + (TC_1593_1594.port_b.Q_flow + (TC_1585_1594.port_b.Q_flow + (TC_1212_1594.port_b.Q_flow + (TC_1065_1594.port_b.Q_flow + (PWB0CabiA007009005.port.Q_flow + (TC_1594_1595.port_a.Q_flow + TC_1594_1603.port_a.Q_flow)))))) = 0.0; PWB0CabiA007009005.port.T = TC_1065_1594.port_b.T; PWB0CabiA007009005.port.T = TC_1212_1594.port_b.T; PWB0CabiA007009005.port.T = TC_1585_1594.port_b.T; PWB0CabiA007009005.port.T = TC_1593_1594.port_b.T; PWB0CabiA007009005.port.T = TC_1594_1595.port_a.T; PWB0CabiA007009005.port.T = TC_1594_1603.port_a.T; PWB0CabiA007009005.port.T = TsPWB0CabiA007009005.port.T; TsPWB0CabiA006009005.port.Q_flow + (TC_1592_1593.port_b.Q_flow + (TC_1584_1593.port_b.Q_flow + (TC_1211_1593.port_b.Q_flow + (TC_1064_1593.port_b.Q_flow + (PWB0CabiA006009005.port.Q_flow + (TC_1593_1594.port_a.Q_flow + TC_1593_1602.port_a.Q_flow)))))) = 0.0; PWB0CabiA006009005.port.T = TC_1064_1593.port_b.T; PWB0CabiA006009005.port.T = TC_1211_1593.port_b.T; PWB0CabiA006009005.port.T = TC_1584_1593.port_b.T; PWB0CabiA006009005.port.T = TC_1592_1593.port_b.T; PWB0CabiA006009005.port.T = TC_1593_1594.port_a.T; PWB0CabiA006009005.port.T = TC_1593_1602.port_a.T; PWB0CabiA006009005.port.T = TsPWB0CabiA006009005.port.T; TsPWB0CabiA005009005.port.Q_flow + (TC_1591_1592.port_b.Q_flow + (TC_1583_1592.port_b.Q_flow + (TC_1210_1592.port_b.Q_flow + (TC_1063_1592.port_b.Q_flow + (PWB0CabiA005009005.port.Q_flow + (TC_1592_1593.port_a.Q_flow + TC_1592_1601.port_a.Q_flow)))))) = 0.0; PWB0CabiA005009005.port.T = TC_1063_1592.port_b.T; PWB0CabiA005009005.port.T = TC_1210_1592.port_b.T; PWB0CabiA005009005.port.T = TC_1583_1592.port_b.T; PWB0CabiA005009005.port.T = TC_1591_1592.port_b.T; PWB0CabiA005009005.port.T = TC_1592_1593.port_a.T; PWB0CabiA005009005.port.T = TC_1592_1601.port_a.T; PWB0CabiA005009005.port.T = TsPWB0CabiA005009005.port.T; TsPWB0CabiA004009005.port.Q_flow + (TC_1590_1591.port_b.Q_flow + (TC_1582_1591.port_b.Q_flow + (TC_1209_1591.port_b.Q_flow + (TC_1062_1591.port_b.Q_flow + (PWB0CabiA004009005.port.Q_flow + (TC_1591_1592.port_a.Q_flow + TC_1591_1600.port_a.Q_flow)))))) = 0.0; PWB0CabiA004009005.port.T = TC_1062_1591.port_b.T; PWB0CabiA004009005.port.T = TC_1209_1591.port_b.T; PWB0CabiA004009005.port.T = TC_1582_1591.port_b.T; PWB0CabiA004009005.port.T = TC_1590_1591.port_b.T; PWB0CabiA004009005.port.T = TC_1591_1592.port_a.T; PWB0CabiA004009005.port.T = TC_1591_1600.port_a.T; PWB0CabiA004009005.port.T = TsPWB0CabiA004009005.port.T; TsPWB0CabiA003009005.port.Q_flow + (TC_1581_1590.port_b.Q_flow + (TC_1208_1590.port_b.Q_flow + (TC_1122_1590.port_b.Q_flow + (TC_1061_1590.port_b.Q_flow + (PWB0CabiA003009005.port.Q_flow + (TC_1590_1591.port_a.Q_flow + TC_1590_1599.port_a.Q_flow)))))) = 0.0; PWB0CabiA003009005.port.T = TC_1061_1590.port_b.T; PWB0CabiA003009005.port.T = TC_1122_1590.port_b.T; PWB0CabiA003009005.port.T = TC_1208_1590.port_b.T; PWB0CabiA003009005.port.T = TC_1581_1590.port_b.T; PWB0CabiA003009005.port.T = TC_1590_1591.port_a.T; PWB0CabiA003009005.port.T = TC_1590_1599.port_a.T; PWB0CabiA003009005.port.T = TsPWB0CabiA003009005.port.T; TsPWB0CabiA011008005.port.Q_flow + (TC_1588_1589.port_b.Q_flow + (TC_1580_1589.port_b.Q_flow + (TC_1205_1589.port_b.Q_flow + (TC_1121_1589.port_b.Q_flow + (TC_1058_1589.port_b.Q_flow + (PWB0CabiA011008005.port.Q_flow + TC_1589_1598.port_a.Q_flow)))))) = 0.0; PWB0CabiA011008005.port.T = TC_1058_1589.port_b.T; PWB0CabiA011008005.port.T = TC_1121_1589.port_b.T; PWB0CabiA011008005.port.T = TC_1205_1589.port_b.T; PWB0CabiA011008005.port.T = TC_1580_1589.port_b.T; PWB0CabiA011008005.port.T = TC_1588_1589.port_b.T; PWB0CabiA011008005.port.T = TC_1589_1598.port_a.T; PWB0CabiA011008005.port.T = TsPWB0CabiA011008005.port.T; TsPWB0CabiA010008005.port.Q_flow + (TC_1587_1588.port_b.Q_flow + (TC_1579_1588.port_b.Q_flow + (TC_1511_1588.port_b.Q_flow + (TC_1057_1588.port_b.Q_flow + (PWB0CabiA010008005.port.Q_flow + (TC_1588_1589.port_a.Q_flow + TC_1588_1597.port_a.Q_flow)))))) = 0.0; PWB0CabiA010008005.port.T = TC_1057_1588.port_b.T; PWB0CabiA010008005.port.T = TC_1511_1588.port_b.T; PWB0CabiA010008005.port.T = TC_1579_1588.port_b.T; PWB0CabiA010008005.port.T = TC_1587_1588.port_b.T; PWB0CabiA010008005.port.T = TC_1588_1589.port_a.T; PWB0CabiA010008005.port.T = TC_1588_1597.port_a.T; PWB0CabiA010008005.port.T = TsPWB0CabiA010008005.port.T; TsPWB0CabiA009008005.port.Q_flow + (TC_1586_1587.port_b.Q_flow + (TC_1578_1587.port_b.Q_flow + (TC_1510_1587.port_b.Q_flow + (TC_1056_1587.port_b.Q_flow + (PWB0CabiA009008005.port.Q_flow + (TC_1587_1588.port_a.Q_flow + TC_1587_1596.port_a.Q_flow)))))) = 0.0; PWB0CabiA009008005.port.T = TC_1056_1587.port_b.T; PWB0CabiA009008005.port.T = TC_1510_1587.port_b.T; PWB0CabiA009008005.port.T = TC_1578_1587.port_b.T; PWB0CabiA009008005.port.T = TC_1586_1587.port_b.T; PWB0CabiA009008005.port.T = TC_1587_1588.port_a.T; PWB0CabiA009008005.port.T = TC_1587_1596.port_a.T; PWB0CabiA009008005.port.T = TsPWB0CabiA009008005.port.T; TsPWB0CabiA008008005.port.Q_flow + (TC_1585_1586.port_b.Q_flow + (TC_1577_1586.port_b.Q_flow + (TC_1509_1586.port_b.Q_flow + (TC_1055_1586.port_b.Q_flow + (PWB0CabiA008008005.port.Q_flow + (TC_1586_1587.port_a.Q_flow + TC_1586_1595.port_a.Q_flow)))))) = 0.0; PWB0CabiA008008005.port.T = TC_1055_1586.port_b.T; PWB0CabiA008008005.port.T = TC_1509_1586.port_b.T; PWB0CabiA008008005.port.T = TC_1577_1586.port_b.T; PWB0CabiA008008005.port.T = TC_1585_1586.port_b.T; PWB0CabiA008008005.port.T = TC_1586_1587.port_a.T; PWB0CabiA008008005.port.T = TC_1586_1595.port_a.T; PWB0CabiA008008005.port.T = TsPWB0CabiA008008005.port.T; TsPWB0CabiA007008005.port.Q_flow + (TC_1584_1585.port_b.Q_flow + (TC_1576_1585.port_b.Q_flow + (TC_1204_1585.port_b.Q_flow + (TC_1054_1585.port_b.Q_flow + (PWB0CabiA007008005.port.Q_flow + (TC_1585_1586.port_a.Q_flow + TC_1585_1594.port_a.Q_flow)))))) = 0.0; PWB0CabiA007008005.port.T = TC_1054_1585.port_b.T; PWB0CabiA007008005.port.T = TC_1204_1585.port_b.T; PWB0CabiA007008005.port.T = TC_1576_1585.port_b.T; PWB0CabiA007008005.port.T = TC_1584_1585.port_b.T; PWB0CabiA007008005.port.T = TC_1585_1586.port_a.T; PWB0CabiA007008005.port.T = TC_1585_1594.port_a.T; PWB0CabiA007008005.port.T = TsPWB0CabiA007008005.port.T; TsPWB0CabiA006008005.port.Q_flow + (TC_1583_1584.port_b.Q_flow + (TC_1575_1584.port_b.Q_flow + (TC_1203_1584.port_b.Q_flow + (TC_1053_1584.port_b.Q_flow + (PWB0CabiA006008005.port.Q_flow + (TC_1584_1585.port_a.Q_flow + TC_1584_1593.port_a.Q_flow)))))) = 0.0; PWB0CabiA006008005.port.T = TC_1053_1584.port_b.T; PWB0CabiA006008005.port.T = TC_1203_1584.port_b.T; PWB0CabiA006008005.port.T = TC_1575_1584.port_b.T; PWB0CabiA006008005.port.T = TC_1583_1584.port_b.T; PWB0CabiA006008005.port.T = TC_1584_1585.port_a.T; PWB0CabiA006008005.port.T = TC_1584_1593.port_a.T; PWB0CabiA006008005.port.T = TsPWB0CabiA006008005.port.T; TsPWB0CabiA005008005.port.Q_flow + (TC_1582_1583.port_b.Q_flow + (TC_1574_1583.port_b.Q_flow + (TC_1202_1583.port_b.Q_flow + (TC_1052_1583.port_b.Q_flow + (PWB0CabiA005008005.port.Q_flow + (TC_1583_1584.port_a.Q_flow + TC_1583_1592.port_a.Q_flow)))))) = 0.0; PWB0CabiA005008005.port.T = TC_1052_1583.port_b.T; PWB0CabiA005008005.port.T = TC_1202_1583.port_b.T; PWB0CabiA005008005.port.T = TC_1574_1583.port_b.T; PWB0CabiA005008005.port.T = TC_1582_1583.port_b.T; PWB0CabiA005008005.port.T = TC_1583_1584.port_a.T; PWB0CabiA005008005.port.T = TC_1583_1592.port_a.T; PWB0CabiA005008005.port.T = TsPWB0CabiA005008005.port.T; TsPWB0CabiA004008005.port.Q_flow + (TC_1581_1582.port_b.Q_flow + (TC_1573_1582.port_b.Q_flow + (TC_1201_1582.port_b.Q_flow + (TC_1051_1582.port_b.Q_flow + (PWB0CabiA004008005.port.Q_flow + (TC_1582_1583.port_a.Q_flow + TC_1582_1591.port_a.Q_flow)))))) = 0.0; PWB0CabiA004008005.port.T = TC_1051_1582.port_b.T; PWB0CabiA004008005.port.T = TC_1201_1582.port_b.T; PWB0CabiA004008005.port.T = TC_1573_1582.port_b.T; PWB0CabiA004008005.port.T = TC_1581_1582.port_b.T; PWB0CabiA004008005.port.T = TC_1582_1583.port_a.T; PWB0CabiA004008005.port.T = TC_1582_1591.port_a.T; PWB0CabiA004008005.port.T = TsPWB0CabiA004008005.port.T; TsPWB0CabiA003008005.port.Q_flow + (TC_1572_1581.port_b.Q_flow + (TC_1200_1581.port_b.Q_flow + (TC_1120_1581.port_b.Q_flow + (TC_1050_1581.port_b.Q_flow + (PWB0CabiA003008005.port.Q_flow + (TC_1581_1582.port_a.Q_flow + TC_1581_1590.port_a.Q_flow)))))) = 0.0; PWB0CabiA003008005.port.T = TC_1050_1581.port_b.T; PWB0CabiA003008005.port.T = TC_1120_1581.port_b.T; PWB0CabiA003008005.port.T = TC_1200_1581.port_b.T; PWB0CabiA003008005.port.T = TC_1572_1581.port_b.T; PWB0CabiA003008005.port.T = TC_1581_1582.port_a.T; PWB0CabiA003008005.port.T = TC_1581_1590.port_a.T; PWB0CabiA003008005.port.T = TsPWB0CabiA003008005.port.T; TsPWB0CabiA011007005.port.Q_flow + (TC_1579_1580.port_b.Q_flow + (TC_1571_1580.port_b.Q_flow + (TC_1197_1580.port_b.Q_flow + (TC_1119_1580.port_b.Q_flow + (TC_1047_1580.port_b.Q_flow + (PWB0CabiA011007005.port.Q_flow + TC_1580_1589.port_a.Q_flow)))))) = 0.0; PWB0CabiA011007005.port.T = TC_1047_1580.port_b.T; PWB0CabiA011007005.port.T = TC_1119_1580.port_b.T; PWB0CabiA011007005.port.T = TC_1197_1580.port_b.T; PWB0CabiA011007005.port.T = TC_1571_1580.port_b.T; PWB0CabiA011007005.port.T = TC_1579_1580.port_b.T; PWB0CabiA011007005.port.T = TC_1580_1589.port_a.T; PWB0CabiA011007005.port.T = TsPWB0CabiA011007005.port.T; TsPWB0CabiA010007005.port.Q_flow + (TC_1578_1579.port_b.Q_flow + (TC_1570_1579.port_b.Q_flow + (TC_1196_1579.port_b.Q_flow + (TC_1046_1579.port_b.Q_flow + (PWB0CabiA010007005.port.Q_flow + (TC_1579_1580.port_a.Q_flow + TC_1579_1588.port_a.Q_flow)))))) = 0.0; PWB0CabiA010007005.port.T = TC_1046_1579.port_b.T; PWB0CabiA010007005.port.T = TC_1196_1579.port_b.T; PWB0CabiA010007005.port.T = TC_1570_1579.port_b.T; PWB0CabiA010007005.port.T = TC_1578_1579.port_b.T; PWB0CabiA010007005.port.T = TC_1579_1580.port_a.T; PWB0CabiA010007005.port.T = TC_1579_1588.port_a.T; PWB0CabiA010007005.port.T = TsPWB0CabiA010007005.port.T; TsPWB0CabiA009007005.port.Q_flow + (TC_1577_1578.port_b.Q_flow + (TC_1569_1578.port_b.Q_flow + (TC_1195_1578.port_b.Q_flow + (TC_1045_1578.port_b.Q_flow + (PWB0CabiA009007005.port.Q_flow + (TC_1578_1579.port_a.Q_flow + TC_1578_1587.port_a.Q_flow)))))) = 0.0; PWB0CabiA009007005.port.T = TC_1045_1578.port_b.T; PWB0CabiA009007005.port.T = TC_1195_1578.port_b.T; PWB0CabiA009007005.port.T = TC_1569_1578.port_b.T; PWB0CabiA009007005.port.T = TC_1577_1578.port_b.T; PWB0CabiA009007005.port.T = TC_1578_1579.port_a.T; PWB0CabiA009007005.port.T = TC_1578_1587.port_a.T; PWB0CabiA009007005.port.T = TsPWB0CabiA009007005.port.T; TsPWB0CabiA008007005.port.Q_flow + (TC_1576_1577.port_b.Q_flow + (TC_1568_1577.port_b.Q_flow + (TC_1194_1577.port_b.Q_flow + (TC_1044_1577.port_b.Q_flow + (PWB0CabiA008007005.port.Q_flow + (TC_1577_1578.port_a.Q_flow + TC_1577_1586.port_a.Q_flow)))))) = 0.0; PWB0CabiA008007005.port.T = TC_1044_1577.port_b.T; PWB0CabiA008007005.port.T = TC_1194_1577.port_b.T; PWB0CabiA008007005.port.T = TC_1568_1577.port_b.T; PWB0CabiA008007005.port.T = TC_1576_1577.port_b.T; PWB0CabiA008007005.port.T = TC_1577_1578.port_a.T; PWB0CabiA008007005.port.T = TC_1577_1586.port_a.T; PWB0CabiA008007005.port.T = TsPWB0CabiA008007005.port.T; TsPWB0CabiA007007005.port.Q_flow + (TC_1575_1576.port_b.Q_flow + (TC_1567_1576.port_b.Q_flow + (TC_1193_1576.port_b.Q_flow + (TC_1043_1576.port_b.Q_flow + (PWB0CabiA007007005.port.Q_flow + (TC_1576_1577.port_a.Q_flow + TC_1576_1585.port_a.Q_flow)))))) = 0.0; PWB0CabiA007007005.port.T = TC_1043_1576.port_b.T; PWB0CabiA007007005.port.T = TC_1193_1576.port_b.T; PWB0CabiA007007005.port.T = TC_1567_1576.port_b.T; PWB0CabiA007007005.port.T = TC_1575_1576.port_b.T; PWB0CabiA007007005.port.T = TC_1576_1577.port_a.T; PWB0CabiA007007005.port.T = TC_1576_1585.port_a.T; PWB0CabiA007007005.port.T = TsPWB0CabiA007007005.port.T; TsPWB0CabiA006007005.port.Q_flow + (TC_1574_1575.port_b.Q_flow + (TC_1566_1575.port_b.Q_flow + (TC_1192_1575.port_b.Q_flow + (TC_1042_1575.port_b.Q_flow + (PWB0CabiA006007005.port.Q_flow + (TC_1575_1576.port_a.Q_flow + TC_1575_1584.port_a.Q_flow)))))) = 0.0; PWB0CabiA006007005.port.T = TC_1042_1575.port_b.T; PWB0CabiA006007005.port.T = TC_1192_1575.port_b.T; PWB0CabiA006007005.port.T = TC_1566_1575.port_b.T; PWB0CabiA006007005.port.T = TC_1574_1575.port_b.T; PWB0CabiA006007005.port.T = TC_1575_1576.port_a.T; PWB0CabiA006007005.port.T = TC_1575_1584.port_a.T; PWB0CabiA006007005.port.T = TsPWB0CabiA006007005.port.T; TsPWB0CabiA005007005.port.Q_flow + (TC_1573_1574.port_b.Q_flow + (TC_1565_1574.port_b.Q_flow + (TC_1191_1574.port_b.Q_flow + (TC_1041_1574.port_b.Q_flow + (PWB0CabiA005007005.port.Q_flow + (TC_1574_1575.port_a.Q_flow + TC_1574_1583.port_a.Q_flow)))))) = 0.0; PWB0CabiA005007005.port.T = TC_1041_1574.port_b.T; PWB0CabiA005007005.port.T = TC_1191_1574.port_b.T; PWB0CabiA005007005.port.T = TC_1565_1574.port_b.T; PWB0CabiA005007005.port.T = TC_1573_1574.port_b.T; PWB0CabiA005007005.port.T = TC_1574_1575.port_a.T; PWB0CabiA005007005.port.T = TC_1574_1583.port_a.T; PWB0CabiA005007005.port.T = TsPWB0CabiA005007005.port.T; TsPWB0CabiA004007005.port.Q_flow + (TC_1572_1573.port_b.Q_flow + (TC_1564_1573.port_b.Q_flow + (TC_1190_1573.port_b.Q_flow + (TC_1040_1573.port_b.Q_flow + (PWB0CabiA004007005.port.Q_flow + (TC_1573_1574.port_a.Q_flow + TC_1573_1582.port_a.Q_flow)))))) = 0.0; PWB0CabiA004007005.port.T = TC_1040_1573.port_b.T; PWB0CabiA004007005.port.T = TC_1190_1573.port_b.T; PWB0CabiA004007005.port.T = TC_1564_1573.port_b.T; PWB0CabiA004007005.port.T = TC_1572_1573.port_b.T; PWB0CabiA004007005.port.T = TC_1573_1574.port_a.T; PWB0CabiA004007005.port.T = TC_1573_1582.port_a.T; PWB0CabiA004007005.port.T = TsPWB0CabiA004007005.port.T; TsPWB0CabiA003007005.port.Q_flow + (TC_1563_1572.port_b.Q_flow + (TC_1189_1572.port_b.Q_flow + (TC_1118_1572.port_b.Q_flow + (TC_1039_1572.port_b.Q_flow + (PWB0CabiA003007005.port.Q_flow + (TC_1572_1573.port_a.Q_flow + TC_1572_1581.port_a.Q_flow)))))) = 0.0; PWB0CabiA003007005.port.T = TC_1039_1572.port_b.T; PWB0CabiA003007005.port.T = TC_1118_1572.port_b.T; PWB0CabiA003007005.port.T = TC_1189_1572.port_b.T; PWB0CabiA003007005.port.T = TC_1563_1572.port_b.T; PWB0CabiA003007005.port.T = TC_1572_1573.port_a.T; PWB0CabiA003007005.port.T = TC_1572_1581.port_a.T; PWB0CabiA003007005.port.T = TsPWB0CabiA003007005.port.T; TsPWB0CabiA011006005.port.Q_flow + (TC_1570_1571.port_b.Q_flow + (TC_1186_1571.port_b.Q_flow + (TC_1117_1571.port_b.Q_flow + (TC_1036_1571.port_b.Q_flow + (PWB0CabiA011006005.port.Q_flow + (TC_1571_1580.port_a.Q_flow + TC_1571_1634.port_a.Q_flow)))))) = 0.0; PWB0CabiA011006005.port.T = TC_1036_1571.port_b.T; PWB0CabiA011006005.port.T = TC_1117_1571.port_b.T; PWB0CabiA011006005.port.T = TC_1186_1571.port_b.T; PWB0CabiA011006005.port.T = TC_1570_1571.port_b.T; PWB0CabiA011006005.port.T = TC_1571_1580.port_a.T; PWB0CabiA011006005.port.T = TC_1571_1634.port_a.T; PWB0CabiA011006005.port.T = TsPWB0CabiA011006005.port.T; TsPWB0CabiA010006005.port.Q_flow + (TC_1569_1570.port_b.Q_flow + (TC_1185_1570.port_b.Q_flow + (TC_1035_1570.port_b.Q_flow + (PWB0CabiA010006005.port.Q_flow + (TC_1570_1571.port_a.Q_flow + (TC_1570_1579.port_a.Q_flow + TC_1570_1633.port_a.Q_flow)))))) = 0.0; PWB0CabiA010006005.port.T = TC_1035_1570.port_b.T; PWB0CabiA010006005.port.T = TC_1185_1570.port_b.T; PWB0CabiA010006005.port.T = TC_1569_1570.port_b.T; PWB0CabiA010006005.port.T = TC_1570_1571.port_a.T; PWB0CabiA010006005.port.T = TC_1570_1579.port_a.T; PWB0CabiA010006005.port.T = TC_1570_1633.port_a.T; PWB0CabiA010006005.port.T = TsPWB0CabiA010006005.port.T; TsPWB0CabiA009006005.port.Q_flow + (TC_1568_1569.port_b.Q_flow + (TC_1184_1569.port_b.Q_flow + (PWB0CabiA009006005.port.Q_flow + (TC_1569_1570.port_a.Q_flow + (TC_1569_1578.port_a.Q_flow + (TC_1569_1632.port_a.Q_flow + TC_1569_1646.port_a.Q_flow)))))) = 0.0; PWB0CabiA009006005.port.T = TC_1184_1569.port_b.T; PWB0CabiA009006005.port.T = TC_1568_1569.port_b.T; PWB0CabiA009006005.port.T = TC_1569_1570.port_a.T; PWB0CabiA009006005.port.T = TC_1569_1578.port_a.T; PWB0CabiA009006005.port.T = TC_1569_1632.port_a.T; PWB0CabiA009006005.port.T = TC_1569_1646.port_a.T; PWB0CabiA009006005.port.T = TsPWB0CabiA009006005.port.T; TsPWB0CabiA008006005.port.Q_flow + (TC_1567_1568.port_b.Q_flow + (TC_1183_1568.port_b.Q_flow + (PWB0CabiA008006005.port.Q_flow + (TC_1568_1569.port_a.Q_flow + (TC_1568_1577.port_a.Q_flow + (TC_1568_1631.port_a.Q_flow + TC_1568_1645.port_a.Q_flow)))))) = 0.0; PWB0CabiA008006005.port.T = TC_1183_1568.port_b.T; PWB0CabiA008006005.port.T = TC_1567_1568.port_b.T; PWB0CabiA008006005.port.T = TC_1568_1569.port_a.T; PWB0CabiA008006005.port.T = TC_1568_1577.port_a.T; PWB0CabiA008006005.port.T = TC_1568_1631.port_a.T; PWB0CabiA008006005.port.T = TC_1568_1645.port_a.T; PWB0CabiA008006005.port.T = TsPWB0CabiA008006005.port.T; TsPWB0CabiA007006005.port.Q_flow + (TC_1566_1567.port_b.Q_flow + (TC_1508_1567.port_b.Q_flow + (PWB0CabiA007006005.port.Q_flow + (TC_1567_1568.port_a.Q_flow + (TC_1567_1576.port_a.Q_flow + (TC_1567_1630.port_a.Q_flow + TC_1567_1644.port_a.Q_flow)))))) = 0.0; PWB0CabiA007006005.port.T = TC_1508_1567.port_b.T; PWB0CabiA007006005.port.T = TC_1566_1567.port_b.T; PWB0CabiA007006005.port.T = TC_1567_1568.port_a.T; PWB0CabiA007006005.port.T = TC_1567_1576.port_a.T; PWB0CabiA007006005.port.T = TC_1567_1630.port_a.T; PWB0CabiA007006005.port.T = TC_1567_1644.port_a.T; PWB0CabiA007006005.port.T = TsPWB0CabiA007006005.port.T; TsPWB0CabiA006006005.port.Q_flow + (TC_1565_1566.port_b.Q_flow + (TC_1507_1566.port_b.Q_flow + (PWB0CabiA006006005.port.Q_flow + (TC_1566_1567.port_a.Q_flow + (TC_1566_1575.port_a.Q_flow + (TC_1566_1629.port_a.Q_flow + TC_1566_1643.port_a.Q_flow)))))) = 0.0; PWB0CabiA006006005.port.T = TC_1507_1566.port_b.T; PWB0CabiA006006005.port.T = TC_1565_1566.port_b.T; PWB0CabiA006006005.port.T = TC_1566_1567.port_a.T; PWB0CabiA006006005.port.T = TC_1566_1575.port_a.T; PWB0CabiA006006005.port.T = TC_1566_1629.port_a.T; PWB0CabiA006006005.port.T = TC_1566_1643.port_a.T; PWB0CabiA006006005.port.T = TsPWB0CabiA006006005.port.T; TsPWB0CabiA005006005.port.Q_flow + (TC_1564_1565.port_b.Q_flow + (TC_1506_1565.port_b.Q_flow + (TC_1034_1565.port_b.Q_flow + (PWB0CabiA005006005.port.Q_flow + (TC_1565_1566.port_a.Q_flow + (TC_1565_1574.port_a.Q_flow + TC_1565_1628.port_a.Q_flow)))))) = 0.0; PWB0CabiA005006005.port.T = TC_1034_1565.port_b.T; PWB0CabiA005006005.port.T = TC_1506_1565.port_b.T; PWB0CabiA005006005.port.T = TC_1564_1565.port_b.T; PWB0CabiA005006005.port.T = TC_1565_1566.port_a.T; PWB0CabiA005006005.port.T = TC_1565_1574.port_a.T; PWB0CabiA005006005.port.T = TC_1565_1628.port_a.T; PWB0CabiA005006005.port.T = TsPWB0CabiA005006005.port.T; TsPWB0CabiA004006005.port.Q_flow + (TC_1563_1564.port_b.Q_flow + (TC_1505_1564.port_b.Q_flow + (TC_1033_1564.port_b.Q_flow + (PWB0CabiA004006005.port.Q_flow + (TC_1564_1565.port_a.Q_flow + (TC_1564_1573.port_a.Q_flow + TC_1564_1627.port_a.Q_flow)))))) = 0.0; PWB0CabiA004006005.port.T = TC_1033_1564.port_b.T; PWB0CabiA004006005.port.T = TC_1505_1564.port_b.T; PWB0CabiA004006005.port.T = TC_1563_1564.port_b.T; PWB0CabiA004006005.port.T = TC_1564_1565.port_a.T; PWB0CabiA004006005.port.T = TC_1564_1573.port_a.T; PWB0CabiA004006005.port.T = TC_1564_1627.port_a.T; PWB0CabiA004006005.port.T = TsPWB0CabiA004006005.port.T; TsPWB0CabiA003006005.port.Q_flow + (TC_1182_1563.port_b.Q_flow + (TC_1116_1563.port_b.Q_flow + (TC_1032_1563.port_b.Q_flow + (PWB0CabiA003006005.port.Q_flow + (TC_1563_1564.port_a.Q_flow + (TC_1563_1572.port_a.Q_flow + TC_1563_1626.port_a.Q_flow)))))) = 0.0; PWB0CabiA003006005.port.T = TC_1032_1563.port_b.T; PWB0CabiA003006005.port.T = TC_1116_1563.port_b.T; PWB0CabiA003006005.port.T = TC_1182_1563.port_b.T; PWB0CabiA003006005.port.T = TC_1563_1564.port_a.T; PWB0CabiA003006005.port.T = TC_1563_1572.port_a.T; PWB0CabiA003006005.port.T = TC_1563_1626.port_a.T; PWB0CabiA003006005.port.T = TsPWB0CabiA003006005.port.T; TsPWB0CabiA011014005.port.Q_flow + (TC_1561_1562.port_b.Q_flow + (TC_1553_1562.port_b.Q_flow + (TC_1256_1562.port_b.Q_flow + (TC_1143_1562.port_b.Q_flow + (TC_1133_1562.port_b.Q_flow + (TC_1015_1562.port_b.Q_flow + PWB0CabiA011014005.port.Q_flow)))))) = 0.0; PWB0CabiA011014005.port.T = TC_1015_1562.port_b.T; PWB0CabiA011014005.port.T = TC_1133_1562.port_b.T; PWB0CabiA011014005.port.T = TC_1143_1562.port_b.T; PWB0CabiA011014005.port.T = TC_1256_1562.port_b.T; PWB0CabiA011014005.port.T = TC_1553_1562.port_b.T; PWB0CabiA011014005.port.T = TC_1561_1562.port_b.T; PWB0CabiA011014005.port.T = TsPWB0CabiA011014005.port.T; TsPWB0CabiA010014005.port.Q_flow + (TC_1560_1561.port_b.Q_flow + (TC_1552_1561.port_b.Q_flow + (TC_1255_1561.port_b.Q_flow + (TC_1142_1561.port_b.Q_flow + (TC_1014_1561.port_b.Q_flow + (PWB0CabiA010014005.port.Q_flow + TC_1561_1562.port_a.Q_flow)))))) = 0.0; PWB0CabiA010014005.port.T = TC_1014_1561.port_b.T; PWB0CabiA010014005.port.T = TC_1142_1561.port_b.T; PWB0CabiA010014005.port.T = TC_1255_1561.port_b.T; PWB0CabiA010014005.port.T = TC_1552_1561.port_b.T; PWB0CabiA010014005.port.T = TC_1560_1561.port_b.T; PWB0CabiA010014005.port.T = TC_1561_1562.port_a.T; PWB0CabiA010014005.port.T = TsPWB0CabiA010014005.port.T; TsPWB0CabiA009014005.port.Q_flow + (TC_1559_1560.port_b.Q_flow + (TC_1551_1560.port_b.Q_flow + (TC_1254_1560.port_b.Q_flow + (TC_1141_1560.port_b.Q_flow + (TC_1013_1560.port_b.Q_flow + (PWB0CabiA009014005.port.Q_flow + TC_1560_1561.port_a.Q_flow)))))) = 0.0; PWB0CabiA009014005.port.T = TC_1013_1560.port_b.T; PWB0CabiA009014005.port.T = TC_1141_1560.port_b.T; PWB0CabiA009014005.port.T = TC_1254_1560.port_b.T; PWB0CabiA009014005.port.T = TC_1551_1560.port_b.T; PWB0CabiA009014005.port.T = TC_1559_1560.port_b.T; PWB0CabiA009014005.port.T = TC_1560_1561.port_a.T; PWB0CabiA009014005.port.T = TsPWB0CabiA009014005.port.T; TsPWB0CabiA008014005.port.Q_flow + (TC_1558_1559.port_b.Q_flow + (TC_1550_1559.port_b.Q_flow + (TC_1253_1559.port_b.Q_flow + (TC_1140_1559.port_b.Q_flow + (TC_1012_1559.port_b.Q_flow + (PWB0CabiA008014005.port.Q_flow + TC_1559_1560.port_a.Q_flow)))))) = 0.0; PWB0CabiA008014005.port.T = TC_1012_1559.port_b.T; PWB0CabiA008014005.port.T = TC_1140_1559.port_b.T; PWB0CabiA008014005.port.T = TC_1253_1559.port_b.T; PWB0CabiA008014005.port.T = TC_1550_1559.port_b.T; PWB0CabiA008014005.port.T = TC_1558_1559.port_b.T; PWB0CabiA008014005.port.T = TC_1559_1560.port_a.T; PWB0CabiA008014005.port.T = TsPWB0CabiA008014005.port.T; TsPWB0CabiA007014005.port.Q_flow + (TC_1557_1558.port_b.Q_flow + (TC_1549_1558.port_b.Q_flow + (TC_1252_1558.port_b.Q_flow + (TC_1139_1558.port_b.Q_flow + (TC_1011_1558.port_b.Q_flow + (PWB0CabiA007014005.port.Q_flow + TC_1558_1559.port_a.Q_flow)))))) = 0.0; PWB0CabiA007014005.port.T = TC_1011_1558.port_b.T; PWB0CabiA007014005.port.T = TC_1139_1558.port_b.T; PWB0CabiA007014005.port.T = TC_1252_1558.port_b.T; PWB0CabiA007014005.port.T = TC_1549_1558.port_b.T; PWB0CabiA007014005.port.T = TC_1557_1558.port_b.T; PWB0CabiA007014005.port.T = TC_1558_1559.port_a.T; PWB0CabiA007014005.port.T = TsPWB0CabiA007014005.port.T; TsPWB0CabiA006014005.port.Q_flow + (TC_1556_1557.port_b.Q_flow + (TC_1548_1557.port_b.Q_flow + (TC_1251_1557.port_b.Q_flow + (TC_1138_1557.port_b.Q_flow + (TC_1010_1557.port_b.Q_flow + (PWB0CabiA006014005.port.Q_flow + TC_1557_1558.port_a.Q_flow)))))) = 0.0; PWB0CabiA006014005.port.T = TC_1010_1557.port_b.T; PWB0CabiA006014005.port.T = TC_1138_1557.port_b.T; PWB0CabiA006014005.port.T = TC_1251_1557.port_b.T; PWB0CabiA006014005.port.T = TC_1548_1557.port_b.T; PWB0CabiA006014005.port.T = TC_1556_1557.port_b.T; PWB0CabiA006014005.port.T = TC_1557_1558.port_a.T; PWB0CabiA006014005.port.T = TsPWB0CabiA006014005.port.T; TsPWB0CabiA005014005.port.Q_flow + (TC_1555_1556.port_b.Q_flow + (TC_1547_1556.port_b.Q_flow + (TC_1250_1556.port_b.Q_flow + (TC_1137_1556.port_b.Q_flow + (TC_1009_1556.port_b.Q_flow + (PWB0CabiA005014005.port.Q_flow + TC_1556_1557.port_a.Q_flow)))))) = 0.0; PWB0CabiA005014005.port.T = TC_1009_1556.port_b.T; PWB0CabiA005014005.port.T = TC_1137_1556.port_b.T; PWB0CabiA005014005.port.T = TC_1250_1556.port_b.T; PWB0CabiA005014005.port.T = TC_1547_1556.port_b.T; PWB0CabiA005014005.port.T = TC_1555_1556.port_b.T; PWB0CabiA005014005.port.T = TC_1556_1557.port_a.T; PWB0CabiA005014005.port.T = TsPWB0CabiA005014005.port.T; TsPWB0CabiA004014005.port.Q_flow + (TC_1554_1555.port_b.Q_flow + (TC_1546_1555.port_b.Q_flow + (TC_1249_1555.port_b.Q_flow + (TC_1136_1555.port_b.Q_flow + (TC_1008_1555.port_b.Q_flow + (PWB0CabiA004014005.port.Q_flow + TC_1555_1556.port_a.Q_flow)))))) = 0.0; PWB0CabiA004014005.port.T = TC_1008_1555.port_b.T; PWB0CabiA004014005.port.T = TC_1136_1555.port_b.T; PWB0CabiA004014005.port.T = TC_1249_1555.port_b.T; PWB0CabiA004014005.port.T = TC_1546_1555.port_b.T; PWB0CabiA004014005.port.T = TC_1554_1555.port_b.T; PWB0CabiA004014005.port.T = TC_1555_1556.port_a.T; PWB0CabiA004014005.port.T = TsPWB0CabiA004014005.port.T; TsPWB0CabiA003014005.port.Q_flow + (TC_1545_1554.port_b.Q_flow + (TC_1248_1554.port_b.Q_flow + (TC_1135_1554.port_b.Q_flow + (TC_1132_1554.port_b.Q_flow + (TC_1007_1554.port_b.Q_flow + (PWB0CabiA003014005.port.Q_flow + TC_1554_1555.port_a.Q_flow)))))) = 0.0; PWB0CabiA003014005.port.T = TC_1007_1554.port_b.T; PWB0CabiA003014005.port.T = TC_1132_1554.port_b.T; PWB0CabiA003014005.port.T = TC_1135_1554.port_b.T; PWB0CabiA003014005.port.T = TC_1248_1554.port_b.T; PWB0CabiA003014005.port.T = TC_1545_1554.port_b.T; PWB0CabiA003014005.port.T = TC_1554_1555.port_a.T; PWB0CabiA003014005.port.T = TsPWB0CabiA003014005.port.T; TsPWB0CabiA011013005.port.Q_flow + (TC_1552_1553.port_b.Q_flow + (TC_1544_1553.port_b.Q_flow + (TC_1245_1553.port_b.Q_flow + (TC_1131_1553.port_b.Q_flow + (TC_1004_1553.port_b.Q_flow + (PWB0CabiA011013005.port.Q_flow + TC_1553_1562.port_a.Q_flow)))))) = 0.0; PWB0CabiA011013005.port.T = TC_1004_1553.port_b.T; PWB0CabiA011013005.port.T = TC_1131_1553.port_b.T; PWB0CabiA011013005.port.T = TC_1245_1553.port_b.T; PWB0CabiA011013005.port.T = TC_1544_1553.port_b.T; PWB0CabiA011013005.port.T = TC_1552_1553.port_b.T; PWB0CabiA011013005.port.T = TC_1553_1562.port_a.T; PWB0CabiA011013005.port.T = TsPWB0CabiA011013005.port.T; TsPWB0CabiA010013005.port.Q_flow + (TC_1551_1552.port_b.Q_flow + (TC_1543_1552.port_b.Q_flow + (TC_1244_1552.port_b.Q_flow + (TC_1003_1552.port_b.Q_flow + (PWB0CabiA010013005.port.Q_flow + (TC_1552_1553.port_a.Q_flow + TC_1552_1561.port_a.Q_flow)))))) = 0.0; PWB0CabiA010013005.port.T = TC_1003_1552.port_b.T; PWB0CabiA010013005.port.T = TC_1244_1552.port_b.T; PWB0CabiA010013005.port.T = TC_1543_1552.port_b.T; PWB0CabiA010013005.port.T = TC_1551_1552.port_b.T; PWB0CabiA010013005.port.T = TC_1552_1553.port_a.T; PWB0CabiA010013005.port.T = TC_1552_1561.port_a.T; PWB0CabiA010013005.port.T = TsPWB0CabiA010013005.port.T; TsPWB0CabiA009013005.port.Q_flow + (TC_1550_1551.port_b.Q_flow + (TC_1542_1551.port_b.Q_flow + (TC_1243_1551.port_b.Q_flow + (TC_1002_1551.port_b.Q_flow + (PWB0CabiA009013005.port.Q_flow + (TC_1551_1552.port_a.Q_flow + TC_1551_1560.port_a.Q_flow)))))) = 0.0; PWB0CabiA009013005.port.T = TC_1002_1551.port_b.T; PWB0CabiA009013005.port.T = TC_1243_1551.port_b.T; PWB0CabiA009013005.port.T = TC_1542_1551.port_b.T; PWB0CabiA009013005.port.T = TC_1550_1551.port_b.T; PWB0CabiA009013005.port.T = TC_1551_1552.port_a.T; PWB0CabiA009013005.port.T = TC_1551_1560.port_a.T; PWB0CabiA009013005.port.T = TsPWB0CabiA009013005.port.T; TsPWB0CabiA008013005.port.Q_flow + (TC_1549_1550.port_b.Q_flow + (TC_1541_1550.port_b.Q_flow + (TC_1242_1550.port_b.Q_flow + (TC_1001_1550.port_b.Q_flow + (PWB0CabiA008013005.port.Q_flow + (TC_1550_1551.port_a.Q_flow + TC_1550_1559.port_a.Q_flow)))))) = 0.0; PWB0CabiA008013005.port.T = TC_1001_1550.port_b.T; PWB0CabiA008013005.port.T = TC_1242_1550.port_b.T; PWB0CabiA008013005.port.T = TC_1541_1550.port_b.T; PWB0CabiA008013005.port.T = TC_1549_1550.port_b.T; PWB0CabiA008013005.port.T = TC_1550_1551.port_a.T; PWB0CabiA008013005.port.T = TC_1550_1559.port_a.T; PWB0CabiA008013005.port.T = TsPWB0CabiA008013005.port.T; TsPWB0CabiA007013005.port.Q_flow + (TC_1548_1549.port_b.Q_flow + (TC_1540_1549.port_b.Q_flow + (TC_1241_1549.port_b.Q_flow + (TC_1000_1549.port_b.Q_flow + (PWB0CabiA007013005.port.Q_flow + (TC_1549_1550.port_a.Q_flow + TC_1549_1558.port_a.Q_flow)))))) = 0.0; PWB0CabiA007013005.port.T = TC_1000_1549.port_b.T; PWB0CabiA007013005.port.T = TC_1241_1549.port_b.T; PWB0CabiA007013005.port.T = TC_1540_1549.port_b.T; PWB0CabiA007013005.port.T = TC_1548_1549.port_b.T; PWB0CabiA007013005.port.T = TC_1549_1550.port_a.T; PWB0CabiA007013005.port.T = TC_1549_1558.port_a.T; PWB0CabiA007013005.port.T = TsPWB0CabiA007013005.port.T; TsPWB0CabiA006013005.port.Q_flow + (TC_1547_1548.port_b.Q_flow + (TC_1539_1548.port_b.Q_flow + (TC_1526_1548.port_b.Q_flow + (PWB0CabiA006013005.port.Q_flow + (TC_1548_1549.port_a.Q_flow + (TC_1548_1557.port_a.Q_flow + TC_1548_1664.port_a.Q_flow)))))) = 0.0; PWB0CabiA006013005.port.T = TC_1526_1548.port_b.T; PWB0CabiA006013005.port.T = TC_1539_1548.port_b.T; PWB0CabiA006013005.port.T = TC_1547_1548.port_b.T; PWB0CabiA006013005.port.T = TC_1548_1549.port_a.T; PWB0CabiA006013005.port.T = TC_1548_1557.port_a.T; PWB0CabiA006013005.port.T = TC_1548_1664.port_a.T; PWB0CabiA006013005.port.T = TsPWB0CabiA006013005.port.T; TsPWB0CabiA005013005.port.Q_flow + (TC_1546_1547.port_b.Q_flow + (TC_1538_1547.port_b.Q_flow + (TC_1525_1547.port_b.Q_flow + (PWB0CabiA005013005.port.Q_flow + (TC_1547_1548.port_a.Q_flow + (TC_1547_1556.port_a.Q_flow + TC_1547_1663.port_a.Q_flow)))))) = 0.0; PWB0CabiA005013005.port.T = TC_1525_1547.port_b.T; PWB0CabiA005013005.port.T = TC_1538_1547.port_b.T; PWB0CabiA005013005.port.T = TC_1546_1547.port_b.T; PWB0CabiA005013005.port.T = TC_1547_1548.port_a.T; PWB0CabiA005013005.port.T = TC_1547_1556.port_a.T; PWB0CabiA005013005.port.T = TC_1547_1663.port_a.T; PWB0CabiA005013005.port.T = TsPWB0CabiA005013005.port.T; TsPWB0CabiA004013005.port.Q_flow + (TC_1545_1546.port_b.Q_flow + (TC_1537_1546.port_b.Q_flow + (TC_1524_1546.port_b.Q_flow + (PWB0CabiA004013005.port.Q_flow + (TC_1546_1547.port_a.Q_flow + (TC_1546_1555.port_a.Q_flow + TC_1546_1662.port_a.Q_flow)))))) = 0.0; PWB0CabiA004013005.port.T = TC_1524_1546.port_b.T; PWB0CabiA004013005.port.T = TC_1537_1546.port_b.T; PWB0CabiA004013005.port.T = TC_1545_1546.port_b.T; PWB0CabiA004013005.port.T = TC_1546_1547.port_a.T; PWB0CabiA004013005.port.T = TC_1546_1555.port_a.T; PWB0CabiA004013005.port.T = TC_1546_1662.port_a.T; PWB0CabiA004013005.port.T = TsPWB0CabiA004013005.port.T; TsPWB0CabiA003013005.port.Q_flow + (TC_1536_1545.port_b.Q_flow + (TC_1240_1545.port_b.Q_flow + (TC_1130_1545.port_b.Q_flow + (TC_999_1545.port_b.Q_flow + (PWB0CabiA003013005.port.Q_flow + (TC_1545_1546.port_a.Q_flow + TC_1545_1554.port_a.Q_flow)))))) = 0.0; PWB0CabiA003013005.port.T = TC_1130_1545.port_b.T; PWB0CabiA003013005.port.T = TC_1240_1545.port_b.T; PWB0CabiA003013005.port.T = TC_1536_1545.port_b.T; PWB0CabiA003013005.port.T = TC_1545_1546.port_a.T; PWB0CabiA003013005.port.T = TC_1545_1554.port_a.T; PWB0CabiA003013005.port.T = TC_999_1545.port_b.T; PWB0CabiA003013005.port.T = TsPWB0CabiA003013005.port.T; TsPWB0CabiA011012005.port.Q_flow + (TC_1543_1544.port_b.Q_flow + (TC_1535_1544.port_b.Q_flow + (TC_1237_1544.port_b.Q_flow + (TC_1129_1544.port_b.Q_flow + (TC_996_1544.port_b.Q_flow + (PWB0CabiA011012005.port.Q_flow + TC_1544_1553.port_a.Q_flow)))))) = 0.0; PWB0CabiA011012005.port.T = TC_1129_1544.port_b.T; PWB0CabiA011012005.port.T = TC_1237_1544.port_b.T; PWB0CabiA011012005.port.T = TC_1535_1544.port_b.T; PWB0CabiA011012005.port.T = TC_1543_1544.port_b.T; PWB0CabiA011012005.port.T = TC_1544_1553.port_a.T; PWB0CabiA011012005.port.T = TC_996_1544.port_b.T; PWB0CabiA011012005.port.T = TsPWB0CabiA011012005.port.T; TsPWB0CabiA010012005.port.Q_flow + (TC_1542_1543.port_b.Q_flow + (TC_1534_1543.port_b.Q_flow + (TC_1236_1543.port_b.Q_flow + (TC_995_1543.port_b.Q_flow + (PWB0CabiA010012005.port.Q_flow + (TC_1543_1544.port_a.Q_flow + TC_1543_1552.port_a.Q_flow)))))) = 0.0; PWB0CabiA010012005.port.T = TC_1236_1543.port_b.T; PWB0CabiA010012005.port.T = TC_1534_1543.port_b.T; PWB0CabiA010012005.port.T = TC_1542_1543.port_b.T; PWB0CabiA010012005.port.T = TC_1543_1544.port_a.T; PWB0CabiA010012005.port.T = TC_1543_1552.port_a.T; PWB0CabiA010012005.port.T = TC_995_1543.port_b.T; PWB0CabiA010012005.port.T = TsPWB0CabiA010012005.port.T; TsPWB0CabiA009012005.port.Q_flow + (TC_1541_1542.port_b.Q_flow + (TC_1533_1542.port_b.Q_flow + (TC_1235_1542.port_b.Q_flow + (TC_994_1542.port_b.Q_flow + (PWB0CabiA009012005.port.Q_flow + (TC_1542_1543.port_a.Q_flow + TC_1542_1551.port_a.Q_flow)))))) = 0.0; PWB0CabiA009012005.port.T = TC_1235_1542.port_b.T; PWB0CabiA009012005.port.T = TC_1533_1542.port_b.T; PWB0CabiA009012005.port.T = TC_1541_1542.port_b.T; PWB0CabiA009012005.port.T = TC_1542_1543.port_a.T; PWB0CabiA009012005.port.T = TC_1542_1551.port_a.T; PWB0CabiA009012005.port.T = TC_994_1542.port_b.T; PWB0CabiA009012005.port.T = TsPWB0CabiA009012005.port.T; TsPWB0CabiA008012005.port.Q_flow + (TC_1540_1541.port_b.Q_flow + (TC_1532_1541.port_b.Q_flow + (TC_1234_1541.port_b.Q_flow + (TC_993_1541.port_b.Q_flow + (PWB0CabiA008012005.port.Q_flow + (TC_1541_1542.port_a.Q_flow + TC_1541_1550.port_a.Q_flow)))))) = 0.0; PWB0CabiA008012005.port.T = TC_1234_1541.port_b.T; PWB0CabiA008012005.port.T = TC_1532_1541.port_b.T; PWB0CabiA008012005.port.T = TC_1540_1541.port_b.T; PWB0CabiA008012005.port.T = TC_1541_1542.port_a.T; PWB0CabiA008012005.port.T = TC_1541_1550.port_a.T; PWB0CabiA008012005.port.T = TC_993_1541.port_b.T; PWB0CabiA008012005.port.T = TsPWB0CabiA008012005.port.T; TsPWB0CabiA007012005.port.Q_flow + (TC_1539_1540.port_b.Q_flow + (TC_1531_1540.port_b.Q_flow + (TC_1233_1540.port_b.Q_flow + (TC_992_1540.port_b.Q_flow + (PWB0CabiA007012005.port.Q_flow + (TC_1540_1541.port_a.Q_flow + TC_1540_1549.port_a.Q_flow)))))) = 0.0; PWB0CabiA007012005.port.T = TC_1233_1540.port_b.T; PWB0CabiA007012005.port.T = TC_1531_1540.port_b.T; PWB0CabiA007012005.port.T = TC_1539_1540.port_b.T; PWB0CabiA007012005.port.T = TC_1540_1541.port_a.T; PWB0CabiA007012005.port.T = TC_1540_1549.port_a.T; PWB0CabiA007012005.port.T = TC_992_1540.port_b.T; PWB0CabiA007012005.port.T = TsPWB0CabiA007012005.port.T; TsPWB0CabiA006012005.port.Q_flow + (TC_1538_1539.port_b.Q_flow + (TC_1530_1539.port_b.Q_flow + (TC_1523_1539.port_b.Q_flow + (PWB0CabiA006012005.port.Q_flow + (TC_1539_1540.port_a.Q_flow + (TC_1539_1548.port_a.Q_flow + TC_1539_1661.port_a.Q_flow)))))) = 0.0; PWB0CabiA006012005.port.T = TC_1523_1539.port_b.T; PWB0CabiA006012005.port.T = TC_1530_1539.port_b.T; PWB0CabiA006012005.port.T = TC_1538_1539.port_b.T; PWB0CabiA006012005.port.T = TC_1539_1540.port_a.T; PWB0CabiA006012005.port.T = TC_1539_1548.port_a.T; PWB0CabiA006012005.port.T = TC_1539_1661.port_a.T; PWB0CabiA006012005.port.T = TsPWB0CabiA006012005.port.T; TsPWB0CabiA005012005.port.Q_flow + (TC_1537_1538.port_b.Q_flow + (TC_1529_1538.port_b.Q_flow + (TC_1522_1538.port_b.Q_flow + (PWB0CabiA005012005.port.Q_flow + (TC_1538_1539.port_a.Q_flow + (TC_1538_1547.port_a.Q_flow + TC_1538_1660.port_a.Q_flow)))))) = 0.0; PWB0CabiA005012005.port.T = TC_1522_1538.port_b.T; PWB0CabiA005012005.port.T = TC_1529_1538.port_b.T; PWB0CabiA005012005.port.T = TC_1537_1538.port_b.T; PWB0CabiA005012005.port.T = TC_1538_1539.port_a.T; PWB0CabiA005012005.port.T = TC_1538_1547.port_a.T; PWB0CabiA005012005.port.T = TC_1538_1660.port_a.T; PWB0CabiA005012005.port.T = TsPWB0CabiA005012005.port.T; TsPWB0CabiA004012005.port.Q_flow + (TC_1536_1537.port_b.Q_flow + (TC_1528_1537.port_b.Q_flow + (TC_1521_1537.port_b.Q_flow + (PWB0CabiA004012005.port.Q_flow + (TC_1537_1538.port_a.Q_flow + (TC_1537_1546.port_a.Q_flow + TC_1537_1659.port_a.Q_flow)))))) = 0.0; PWB0CabiA004012005.port.T = TC_1521_1537.port_b.T; PWB0CabiA004012005.port.T = TC_1528_1537.port_b.T; PWB0CabiA004012005.port.T = TC_1536_1537.port_b.T; PWB0CabiA004012005.port.T = TC_1537_1538.port_a.T; PWB0CabiA004012005.port.T = TC_1537_1546.port_a.T; PWB0CabiA004012005.port.T = TC_1537_1659.port_a.T; PWB0CabiA004012005.port.T = TsPWB0CabiA004012005.port.T; TsPWB0CabiA003012005.port.Q_flow + (TC_1527_1536.port_b.Q_flow + (TC_1232_1536.port_b.Q_flow + (TC_1128_1536.port_b.Q_flow + (TC_991_1536.port_b.Q_flow + (PWB0CabiA003012005.port.Q_flow + (TC_1536_1537.port_a.Q_flow + TC_1536_1545.port_a.Q_flow)))))) = 0.0; PWB0CabiA003012005.port.T = TC_1128_1536.port_b.T; PWB0CabiA003012005.port.T = TC_1232_1536.port_b.T; PWB0CabiA003012005.port.T = TC_1527_1536.port_b.T; PWB0CabiA003012005.port.T = TC_1536_1537.port_a.T; PWB0CabiA003012005.port.T = TC_1536_1545.port_a.T; PWB0CabiA003012005.port.T = TC_991_1536.port_b.T; PWB0CabiA003012005.port.T = TsPWB0CabiA003012005.port.T; TsPWB0CabiA011011005.port.Q_flow + (TC_1534_1535.port_b.Q_flow + (TC_1229_1535.port_b.Q_flow + (TC_1127_1535.port_b.Q_flow + (TC_988_1535.port_b.Q_flow + (PWB0CabiA011011005.port.Q_flow + (TC_1535_1544.port_a.Q_flow + TC_1535_1607.port_a.Q_flow)))))) = 0.0; PWB0CabiA011011005.port.T = TC_1127_1535.port_b.T; PWB0CabiA011011005.port.T = TC_1229_1535.port_b.T; PWB0CabiA011011005.port.T = TC_1534_1535.port_b.T; PWB0CabiA011011005.port.T = TC_1535_1544.port_a.T; PWB0CabiA011011005.port.T = TC_1535_1607.port_a.T; PWB0CabiA011011005.port.T = TC_988_1535.port_b.T; PWB0CabiA011011005.port.T = TsPWB0CabiA011011005.port.T; TsPWB0CabiA010011005.port.Q_flow + (TC_1533_1534.port_b.Q_flow + (TC_1228_1534.port_b.Q_flow + (PWB0CabiA010011005.port.Q_flow + (TC_1534_1535.port_a.Q_flow + (TC_1534_1543.port_a.Q_flow + (TC_1534_1606.port_a.Q_flow + TC_1534_1655.port_a.Q_flow)))))) = 0.0; PWB0CabiA010011005.port.T = TC_1228_1534.port_b.T; PWB0CabiA010011005.port.T = TC_1533_1534.port_b.T; PWB0CabiA010011005.port.T = TC_1534_1535.port_a.T; PWB0CabiA010011005.port.T = TC_1534_1543.port_a.T; PWB0CabiA010011005.port.T = TC_1534_1606.port_a.T; PWB0CabiA010011005.port.T = TC_1534_1655.port_a.T; PWB0CabiA010011005.port.T = TsPWB0CabiA010011005.port.T; TsPWB0CabiA009011005.port.Q_flow + (TC_1532_1533.port_b.Q_flow + (TC_1227_1533.port_b.Q_flow + (PWB0CabiA009011005.port.Q_flow + (TC_1533_1534.port_a.Q_flow + (TC_1533_1542.port_a.Q_flow + (TC_1533_1605.port_a.Q_flow + TC_1533_1654.port_a.Q_flow)))))) = 0.0; PWB0CabiA009011005.port.T = TC_1227_1533.port_b.T; PWB0CabiA009011005.port.T = TC_1532_1533.port_b.T; PWB0CabiA009011005.port.T = TC_1533_1534.port_a.T; PWB0CabiA009011005.port.T = TC_1533_1542.port_a.T; PWB0CabiA009011005.port.T = TC_1533_1605.port_a.T; PWB0CabiA009011005.port.T = TC_1533_1654.port_a.T; PWB0CabiA009011005.port.T = TsPWB0CabiA009011005.port.T; TsPWB0CabiA008011005.port.Q_flow + (TC_1531_1532.port_b.Q_flow + (TC_1226_1532.port_b.Q_flow + (PWB0CabiA008011005.port.Q_flow + (TC_1532_1533.port_a.Q_flow + (TC_1532_1541.port_a.Q_flow + (TC_1532_1604.port_a.Q_flow + TC_1532_1653.port_a.Q_flow)))))) = 0.0; PWB0CabiA008011005.port.T = TC_1226_1532.port_b.T; PWB0CabiA008011005.port.T = TC_1531_1532.port_b.T; PWB0CabiA008011005.port.T = TC_1532_1533.port_a.T; PWB0CabiA008011005.port.T = TC_1532_1541.port_a.T; PWB0CabiA008011005.port.T = TC_1532_1604.port_a.T; PWB0CabiA008011005.port.T = TC_1532_1653.port_a.T; PWB0CabiA008011005.port.T = TsPWB0CabiA008011005.port.T; TsPWB0CabiA007011005.port.Q_flow + (TC_1530_1531.port_b.Q_flow + (TC_1225_1531.port_b.Q_flow + (TC_987_1531.port_b.Q_flow + (PWB0CabiA007011005.port.Q_flow + (TC_1531_1532.port_a.Q_flow + (TC_1531_1540.port_a.Q_flow + TC_1531_1603.port_a.Q_flow)))))) = 0.0; PWB0CabiA007011005.port.T = TC_1225_1531.port_b.T; PWB0CabiA007011005.port.T = TC_1530_1531.port_b.T; PWB0CabiA007011005.port.T = TC_1531_1532.port_a.T; PWB0CabiA007011005.port.T = TC_1531_1540.port_a.T; PWB0CabiA007011005.port.T = TC_1531_1603.port_a.T; PWB0CabiA007011005.port.T = TC_987_1531.port_b.T; PWB0CabiA007011005.port.T = TsPWB0CabiA007011005.port.T; TsPWB0CabiA006011005.port.Q_flow + (TC_1529_1530.port_b.Q_flow + (TC_1520_1530.port_b.Q_flow + (PWB0CabiA006011005.port.Q_flow + (TC_1530_1531.port_a.Q_flow + (TC_1530_1539.port_a.Q_flow + (TC_1530_1602.port_a.Q_flow + TC_1530_1658.port_a.Q_flow)))))) = 0.0; PWB0CabiA006011005.port.T = TC_1520_1530.port_b.T; PWB0CabiA006011005.port.T = TC_1529_1530.port_b.T; PWB0CabiA006011005.port.T = TC_1530_1531.port_a.T; PWB0CabiA006011005.port.T = TC_1530_1539.port_a.T; PWB0CabiA006011005.port.T = TC_1530_1602.port_a.T; PWB0CabiA006011005.port.T = TC_1530_1658.port_a.T; PWB0CabiA006011005.port.T = TsPWB0CabiA006011005.port.T; TsPWB0CabiA005011005.port.Q_flow + (TC_1528_1529.port_b.Q_flow + (TC_1519_1529.port_b.Q_flow + (PWB0CabiA005011005.port.Q_flow + (TC_1529_1530.port_a.Q_flow + (TC_1529_1538.port_a.Q_flow + (TC_1529_1601.port_a.Q_flow + TC_1529_1657.port_a.Q_flow)))))) = 0.0; PWB0CabiA005011005.port.T = TC_1519_1529.port_b.T; PWB0CabiA005011005.port.T = TC_1528_1529.port_b.T; PWB0CabiA005011005.port.T = TC_1529_1530.port_a.T; PWB0CabiA005011005.port.T = TC_1529_1538.port_a.T; PWB0CabiA005011005.port.T = TC_1529_1601.port_a.T; PWB0CabiA005011005.port.T = TC_1529_1657.port_a.T; PWB0CabiA005011005.port.T = TsPWB0CabiA005011005.port.T; TsPWB0CabiA004011005.port.Q_flow + (TC_1527_1528.port_b.Q_flow + (TC_1518_1528.port_b.Q_flow + (PWB0CabiA004011005.port.Q_flow + (TC_1528_1529.port_a.Q_flow + (TC_1528_1537.port_a.Q_flow + (TC_1528_1600.port_a.Q_flow + TC_1528_1656.port_a.Q_flow)))))) = 0.0; PWB0CabiA004011005.port.T = TC_1518_1528.port_b.T; PWB0CabiA004011005.port.T = TC_1527_1528.port_b.T; PWB0CabiA004011005.port.T = TC_1528_1529.port_a.T; PWB0CabiA004011005.port.T = TC_1528_1537.port_a.T; PWB0CabiA004011005.port.T = TC_1528_1600.port_a.T; PWB0CabiA004011005.port.T = TC_1528_1656.port_a.T; PWB0CabiA004011005.port.T = TsPWB0CabiA004011005.port.T; TsPWB0CabiA003011005.port.Q_flow + (TC_1224_1527.port_b.Q_flow + (TC_1126_1527.port_b.Q_flow + (TC_986_1527.port_b.Q_flow + (PWB0CabiA003011005.port.Q_flow + (TC_1527_1528.port_a.Q_flow + (TC_1527_1536.port_a.Q_flow + TC_1527_1599.port_a.Q_flow)))))) = 0.0; PWB0CabiA003011005.port.T = TC_1126_1527.port_b.T; PWB0CabiA003011005.port.T = TC_1224_1527.port_b.T; PWB0CabiA003011005.port.T = TC_1527_1528.port_a.T; PWB0CabiA003011005.port.T = TC_1527_1536.port_a.T; PWB0CabiA003011005.port.T = TC_1527_1599.port_a.T; PWB0CabiA003011005.port.T = TC_986_1527.port_b.T; PWB0CabiA003011005.port.T = TsPWB0CabiA003011005.port.T; TsST0CabiA010010003.port.Q_flow + (TC_1495_1496.port_b.Q_flow + (TC_1493_1496.port_b.Q_flow + (TC_1367_1496.port_b.Q_flow + (TC_1357_1496.port_b.Q_flow + (TC_787_1496.port_b.Q_flow + (ST0CabiA010010003.port.Q_flow + TC_1496_1517.port_a.Q_flow)))))) = 0.0; ST0CabiA010010003.port.T = TC_1357_1496.port_b.T; ST0CabiA010010003.port.T = TC_1367_1496.port_b.T; ST0CabiA010010003.port.T = TC_1493_1496.port_b.T; ST0CabiA010010003.port.T = TC_1495_1496.port_b.T; ST0CabiA010010003.port.T = TC_1496_1517.port_a.T; ST0CabiA010010003.port.T = TC_787_1496.port_b.T; ST0CabiA010010003.port.T = TsST0CabiA010010003.port.T; TsST0CabiA009010003.port.Q_flow + (TC_1494_1495.port_b.Q_flow + (TC_1492_1495.port_b.Q_flow + (TC_1366_1495.port_b.Q_flow + (TC_786_1495.port_b.Q_flow + (ST0CabiA009010003.port.Q_flow + (TC_1495_1496.port_a.Q_flow + TC_1495_1516.port_a.Q_flow)))))) = 0.0; ST0CabiA009010003.port.T = TC_1366_1495.port_b.T; ST0CabiA009010003.port.T = TC_1492_1495.port_b.T; ST0CabiA009010003.port.T = TC_1494_1495.port_b.T; ST0CabiA009010003.port.T = TC_1495_1496.port_a.T; ST0CabiA009010003.port.T = TC_1495_1516.port_a.T; ST0CabiA009010003.port.T = TC_786_1495.port_b.T; ST0CabiA009010003.port.T = TsST0CabiA009010003.port.T; TsST0CabiA008010003.port.Q_flow + (TC_1491_1494.port_b.Q_flow + (TC_1365_1494.port_b.Q_flow + (TC_1356_1494.port_b.Q_flow + (TC_785_1494.port_b.Q_flow + (ST0CabiA008010003.port.Q_flow + (TC_1494_1495.port_a.Q_flow + TC_1494_1515.port_a.Q_flow)))))) = 0.0; ST0CabiA008010003.port.T = TC_1356_1494.port_b.T; ST0CabiA008010003.port.T = TC_1365_1494.port_b.T; ST0CabiA008010003.port.T = TC_1491_1494.port_b.T; ST0CabiA008010003.port.T = TC_1494_1495.port_a.T; ST0CabiA008010003.port.T = TC_1494_1515.port_a.T; ST0CabiA008010003.port.T = TC_785_1494.port_b.T; ST0CabiA008010003.port.T = TsST0CabiA008010003.port.T; TsST0CabiA010009003.port.Q_flow + (TC_1492_1493.port_b.Q_flow + (TC_1490_1493.port_b.Q_flow + (TC_1349_1493.port_b.Q_flow + (TC_779_1493.port_b.Q_flow + (ST0CabiA010009003.port.Q_flow + (TC_1493_1496.port_a.Q_flow + TC_1493_1514.port_a.Q_flow)))))) = 0.0; ST0CabiA010009003.port.T = TC_1349_1493.port_b.T; ST0CabiA010009003.port.T = TC_1490_1493.port_b.T; ST0CabiA010009003.port.T = TC_1492_1493.port_b.T; ST0CabiA010009003.port.T = TC_1493_1496.port_a.T; ST0CabiA010009003.port.T = TC_1493_1514.port_a.T; ST0CabiA010009003.port.T = TC_779_1493.port_b.T; ST0CabiA010009003.port.T = TsST0CabiA010009003.port.T; TsST0CabiA009009003.port.Q_flow + (TC_1491_1492.port_b.Q_flow + (TC_1489_1492.port_b.Q_flow + (TC_778_1492.port_b.Q_flow + (ST0CabiA009009003.port.Q_flow + (TC_1492_1493.port_a.Q_flow + (TC_1492_1495.port_a.Q_flow + TC_1492_1513.port_a.Q_flow)))))) = 0.0; ST0CabiA009009003.port.T = TC_1489_1492.port_b.T; ST0CabiA009009003.port.T = TC_1491_1492.port_b.T; ST0CabiA009009003.port.T = TC_1492_1493.port_a.T; ST0CabiA009009003.port.T = TC_1492_1495.port_a.T; ST0CabiA009009003.port.T = TC_1492_1513.port_a.T; ST0CabiA009009003.port.T = TC_778_1492.port_b.T; ST0CabiA009009003.port.T = TsST0CabiA009009003.port.T; TsST0CabiA008009003.port.Q_flow + (TC_1488_1491.port_b.Q_flow + (TC_1348_1491.port_b.Q_flow + (TC_777_1491.port_b.Q_flow + (ST0CabiA008009003.port.Q_flow + (TC_1491_1492.port_a.Q_flow + (TC_1491_1494.port_a.Q_flow + TC_1491_1512.port_a.Q_flow)))))) = 0.0; ST0CabiA008009003.port.T = TC_1348_1491.port_b.T; ST0CabiA008009003.port.T = TC_1488_1491.port_b.T; ST0CabiA008009003.port.T = TC_1491_1492.port_a.T; ST0CabiA008009003.port.T = TC_1491_1494.port_a.T; ST0CabiA008009003.port.T = TC_1491_1512.port_a.T; ST0CabiA008009003.port.T = TC_777_1491.port_b.T; ST0CabiA008009003.port.T = TsST0CabiA008009003.port.T; TsST0CabiA010008003.port.Q_flow + (TC_1489_1490.port_b.Q_flow + (TC_1341_1490.port_b.Q_flow + (TC_1332_1490.port_b.Q_flow + (TC_771_1490.port_b.Q_flow + (ST0CabiA010008003.port.Q_flow + (TC_1490_1493.port_a.Q_flow + TC_1490_1511.port_a.Q_flow)))))) = 0.0; ST0CabiA010008003.port.T = TC_1332_1490.port_b.T; ST0CabiA010008003.port.T = TC_1341_1490.port_b.T; ST0CabiA010008003.port.T = TC_1489_1490.port_b.T; ST0CabiA010008003.port.T = TC_1490_1493.port_a.T; ST0CabiA010008003.port.T = TC_1490_1511.port_a.T; ST0CabiA010008003.port.T = TC_771_1490.port_b.T; ST0CabiA010008003.port.T = TsST0CabiA010008003.port.T; TsST0CabiA009008003.port.Q_flow + (TC_1488_1489.port_b.Q_flow + (TC_1331_1489.port_b.Q_flow + (TC_770_1489.port_b.Q_flow + (ST0CabiA009008003.port.Q_flow + (TC_1489_1490.port_a.Q_flow + (TC_1489_1492.port_a.Q_flow + TC_1489_1510.port_a.Q_flow)))))) = 0.0; ST0CabiA009008003.port.T = TC_1331_1489.port_b.T; ST0CabiA009008003.port.T = TC_1488_1489.port_b.T; ST0CabiA009008003.port.T = TC_1489_1490.port_a.T; ST0CabiA009008003.port.T = TC_1489_1492.port_a.T; ST0CabiA009008003.port.T = TC_1489_1510.port_a.T; ST0CabiA009008003.port.T = TC_770_1489.port_b.T; ST0CabiA009008003.port.T = TsST0CabiA009008003.port.T; TsST0CabiA008008003.port.Q_flow + (TC_1340_1488.port_b.Q_flow + (TC_1330_1488.port_b.Q_flow + (TC_769_1488.port_b.Q_flow + (ST0CabiA008008003.port.Q_flow + (TC_1488_1489.port_a.Q_flow + (TC_1488_1491.port_a.Q_flow + TC_1488_1509.port_a.Q_flow)))))) = 0.0; ST0CabiA008008003.port.T = TC_1330_1488.port_b.T; ST0CabiA008008003.port.T = TC_1340_1488.port_b.T; ST0CabiA008008003.port.T = TC_1488_1489.port_a.T; ST0CabiA008008003.port.T = TC_1488_1491.port_a.T; ST0CabiA008008003.port.T = TC_1488_1509.port_a.T; ST0CabiA008008003.port.T = TC_769_1488.port_b.T; ST0CabiA008008003.port.T = TsST0CabiA008008003.port.T; TsAIR0CabiA012002002.port.Q_flow + (TC_1486_1487.port_b.Q_flow + (TC_1476_1487.port_b.Q_flow + (TC_1279_1487.port_b.Q_flow + (TC_222_1487.port_b.Q_flow + (TC_219_1487.port_b.Q_flow + (TC_25_1487.port_b.Q_flow + AIR0CabiA012002002.port.Q_flow)))))) = 0.0; AIR0CabiA012002002.port.T = TC_1279_1487.port_b.T; AIR0CabiA012002002.port.T = TC_1476_1487.port_b.T; AIR0CabiA012002002.port.T = TC_1486_1487.port_b.T; AIR0CabiA012002002.port.T = TC_219_1487.port_b.T; AIR0CabiA012002002.port.T = TC_222_1487.port_b.T; AIR0CabiA012002002.port.T = TC_25_1487.port_b.T; AIR0CabiA012002002.port.T = TsAIR0CabiA012002002.port.T; TsAIR0CabiA011002002.port.Q_flow + (TC_1485_1486.port_b.Q_flow + (TC_1475_1486.port_b.Q_flow + (TC_1278_1486.port_b.Q_flow + (TC_218_1486.port_b.Q_flow + (TC_24_1486.port_b.Q_flow + (AIR0CabiA011002002.port.Q_flow + TC_1486_1487.port_a.Q_flow)))))) = 0.0; AIR0CabiA011002002.port.T = TC_1278_1486.port_b.T; AIR0CabiA011002002.port.T = TC_1475_1486.port_b.T; AIR0CabiA011002002.port.T = TC_1485_1486.port_b.T; AIR0CabiA011002002.port.T = TC_1486_1487.port_a.T; AIR0CabiA011002002.port.T = TC_218_1486.port_b.T; AIR0CabiA011002002.port.T = TC_24_1486.port_b.T; AIR0CabiA011002002.port.T = TsAIR0CabiA011002002.port.T; TsAIR0CabiA010002002.port.Q_flow + (TC_1484_1485.port_b.Q_flow + (TC_1474_1485.port_b.Q_flow + (TC_1277_1485.port_b.Q_flow + (TC_217_1485.port_b.Q_flow + (TC_23_1485.port_b.Q_flow + (AIR0CabiA010002002.port.Q_flow + TC_1485_1486.port_a.Q_flow)))))) = 0.0; AIR0CabiA010002002.port.T = TC_1277_1485.port_b.T; AIR0CabiA010002002.port.T = TC_1474_1485.port_b.T; AIR0CabiA010002002.port.T = TC_1484_1485.port_b.T; AIR0CabiA010002002.port.T = TC_1485_1486.port_a.T; AIR0CabiA010002002.port.T = TC_217_1485.port_b.T; AIR0CabiA010002002.port.T = TC_23_1485.port_b.T; AIR0CabiA010002002.port.T = TsAIR0CabiA010002002.port.T; TsAIR0CabiA009002002.port.Q_flow + (TC_1483_1484.port_b.Q_flow + (TC_1473_1484.port_b.Q_flow + (TC_1276_1484.port_b.Q_flow + (TC_216_1484.port_b.Q_flow + (TC_22_1484.port_b.Q_flow + (AIR0CabiA009002002.port.Q_flow + TC_1484_1485.port_a.Q_flow)))))) = 0.0; AIR0CabiA009002002.port.T = TC_1276_1484.port_b.T; AIR0CabiA009002002.port.T = TC_1473_1484.port_b.T; AIR0CabiA009002002.port.T = TC_1483_1484.port_b.T; AIR0CabiA009002002.port.T = TC_1484_1485.port_a.T; AIR0CabiA009002002.port.T = TC_216_1484.port_b.T; AIR0CabiA009002002.port.T = TC_22_1484.port_b.T; AIR0CabiA009002002.port.T = TsAIR0CabiA009002002.port.T; TsAIR0CabiA008002002.port.Q_flow + (TC_1482_1483.port_b.Q_flow + (TC_1472_1483.port_b.Q_flow + (TC_1275_1483.port_b.Q_flow + (TC_215_1483.port_b.Q_flow + (TC_21_1483.port_b.Q_flow + (AIR0CabiA008002002.port.Q_flow + TC_1483_1484.port_a.Q_flow)))))) = 0.0; AIR0CabiA008002002.port.T = TC_1275_1483.port_b.T; AIR0CabiA008002002.port.T = TC_1472_1483.port_b.T; AIR0CabiA008002002.port.T = TC_1482_1483.port_b.T; AIR0CabiA008002002.port.T = TC_1483_1484.port_a.T; AIR0CabiA008002002.port.T = TC_215_1483.port_b.T; AIR0CabiA008002002.port.T = TC_21_1483.port_b.T; AIR0CabiA008002002.port.T = TsAIR0CabiA008002002.port.T; TsAIR0CabiA007002002.port.Q_flow + (TC_1481_1482.port_b.Q_flow + (TC_1471_1482.port_b.Q_flow + (TC_1274_1482.port_b.Q_flow + (TC_214_1482.port_b.Q_flow + (TC_20_1482.port_b.Q_flow + (AIR0CabiA007002002.port.Q_flow + TC_1482_1483.port_a.Q_flow)))))) = 0.0; AIR0CabiA007002002.port.T = TC_1274_1482.port_b.T; AIR0CabiA007002002.port.T = TC_1471_1482.port_b.T; AIR0CabiA007002002.port.T = TC_1481_1482.port_b.T; AIR0CabiA007002002.port.T = TC_1482_1483.port_a.T; AIR0CabiA007002002.port.T = TC_20_1482.port_b.T; AIR0CabiA007002002.port.T = TC_214_1482.port_b.T; AIR0CabiA007002002.port.T = TsAIR0CabiA007002002.port.T; TsAIR0CabiA006002002.port.Q_flow + (TC_1480_1481.port_b.Q_flow + (TC_1470_1481.port_b.Q_flow + (TC_1273_1481.port_b.Q_flow + (TC_213_1481.port_b.Q_flow + (TC_19_1481.port_b.Q_flow + (AIR0CabiA006002002.port.Q_flow + TC_1481_1482.port_a.Q_flow)))))) = 0.0; AIR0CabiA006002002.port.T = TC_1273_1481.port_b.T; AIR0CabiA006002002.port.T = TC_1470_1481.port_b.T; AIR0CabiA006002002.port.T = TC_1480_1481.port_b.T; AIR0CabiA006002002.port.T = TC_1481_1482.port_a.T; AIR0CabiA006002002.port.T = TC_19_1481.port_b.T; AIR0CabiA006002002.port.T = TC_213_1481.port_b.T; AIR0CabiA006002002.port.T = TsAIR0CabiA006002002.port.T; TsAIR0CabiA005002002.port.Q_flow + (TC_1479_1480.port_b.Q_flow + (TC_1469_1480.port_b.Q_flow + (TC_1272_1480.port_b.Q_flow + (TC_212_1480.port_b.Q_flow + (TC_18_1480.port_b.Q_flow + (AIR0CabiA005002002.port.Q_flow + TC_1480_1481.port_a.Q_flow)))))) = 0.0; AIR0CabiA005002002.port.T = TC_1272_1480.port_b.T; AIR0CabiA005002002.port.T = TC_1469_1480.port_b.T; AIR0CabiA005002002.port.T = TC_1479_1480.port_b.T; AIR0CabiA005002002.port.T = TC_1480_1481.port_a.T; AIR0CabiA005002002.port.T = TC_18_1480.port_b.T; AIR0CabiA005002002.port.T = TC_212_1480.port_b.T; AIR0CabiA005002002.port.T = TsAIR0CabiA005002002.port.T; TsAIR0CabiA004002002.port.Q_flow + (TC_1478_1479.port_b.Q_flow + (TC_1468_1479.port_b.Q_flow + (TC_1271_1479.port_b.Q_flow + (TC_211_1479.port_b.Q_flow + (TC_17_1479.port_b.Q_flow + (AIR0CabiA004002002.port.Q_flow + TC_1479_1480.port_a.Q_flow)))))) = 0.0; AIR0CabiA004002002.port.T = TC_1271_1479.port_b.T; AIR0CabiA004002002.port.T = TC_1468_1479.port_b.T; AIR0CabiA004002002.port.T = TC_1478_1479.port_b.T; AIR0CabiA004002002.port.T = TC_1479_1480.port_a.T; AIR0CabiA004002002.port.T = TC_17_1479.port_b.T; AIR0CabiA004002002.port.T = TC_211_1479.port_b.T; AIR0CabiA004002002.port.T = TsAIR0CabiA004002002.port.T; TsAIR0CabiA003002002.port.Q_flow + (TC_1477_1478.port_b.Q_flow + (TC_1467_1478.port_b.Q_flow + (TC_1270_1478.port_b.Q_flow + (TC_210_1478.port_b.Q_flow + (TC_16_1478.port_b.Q_flow + (AIR0CabiA003002002.port.Q_flow + TC_1478_1479.port_a.Q_flow)))))) = 0.0; AIR0CabiA003002002.port.T = TC_1270_1478.port_b.T; AIR0CabiA003002002.port.T = TC_1467_1478.port_b.T; AIR0CabiA003002002.port.T = TC_1477_1478.port_b.T; AIR0CabiA003002002.port.T = TC_1478_1479.port_a.T; AIR0CabiA003002002.port.T = TC_16_1478.port_b.T; AIR0CabiA003002002.port.T = TC_210_1478.port_b.T; AIR0CabiA003002002.port.T = TsAIR0CabiA003002002.port.T; TsAIR0CabiA002002002.port.Q_flow + (TC_1466_1477.port_b.Q_flow + (TC_1269_1477.port_b.Q_flow + (TC_221_1477.port_b.Q_flow + (TC_209_1477.port_b.Q_flow + (TC_15_1477.port_b.Q_flow + (AIR0CabiA002002002.port.Q_flow + TC_1477_1478.port_a.Q_flow)))))) = 0.0; AIR0CabiA002002002.port.T = TC_1269_1477.port_b.T; AIR0CabiA002002002.port.T = TC_1466_1477.port_b.T; AIR0CabiA002002002.port.T = TC_1477_1478.port_a.T; AIR0CabiA002002002.port.T = TC_15_1477.port_b.T; AIR0CabiA002002002.port.T = TC_209_1477.port_b.T; AIR0CabiA002002002.port.T = TC_221_1477.port_b.T; AIR0CabiA002002002.port.T = TsAIR0CabiA002002002.port.T; TsAIR0CabiA012003002.port.Q_flow + (TC_1475_1476.port_b.Q_flow + (TC_1463_1476.port_b.Q_flow + (TC_1290_1476.port_b.Q_flow + (TC_224_1476.port_b.Q_flow + (TC_38_1476.port_b.Q_flow + (AIR0CabiA012003002.port.Q_flow + TC_1476_1487.port_a.Q_flow)))))) = 0.0; AIR0CabiA012003002.port.T = TC_1290_1476.port_b.T; AIR0CabiA012003002.port.T = TC_1463_1476.port_b.T; AIR0CabiA012003002.port.T = TC_1475_1476.port_b.T; AIR0CabiA012003002.port.T = TC_1476_1487.port_a.T; AIR0CabiA012003002.port.T = TC_224_1476.port_b.T; AIR0CabiA012003002.port.T = TC_38_1476.port_b.T; AIR0CabiA012003002.port.T = TsAIR0CabiA012003002.port.T; TsAIR0CabiA011003002.port.Q_flow + (TC_1474_1475.port_b.Q_flow + (TC_1289_1475.port_b.Q_flow + (TC_820_1475.port_b.Q_flow + (TC_37_1475.port_b.Q_flow + (AIR0CabiA011003002.port.Q_flow + (TC_1475_1476.port_a.Q_flow + TC_1475_1486.port_a.Q_flow)))))) = 0.0; AIR0CabiA011003002.port.T = TC_1289_1475.port_b.T; AIR0CabiA011003002.port.T = TC_1474_1475.port_b.T; AIR0CabiA011003002.port.T = TC_1475_1476.port_a.T; AIR0CabiA011003002.port.T = TC_1475_1486.port_a.T; AIR0CabiA011003002.port.T = TC_37_1475.port_b.T; AIR0CabiA011003002.port.T = TC_820_1475.port_b.T; AIR0CabiA011003002.port.T = TsAIR0CabiA011003002.port.T; TsAIR0CabiA010003002.port.Q_flow + (TC_1473_1474.port_b.Q_flow + (TC_1288_1474.port_b.Q_flow + (TC_819_1474.port_b.Q_flow + (TC_36_1474.port_b.Q_flow + (AIR0CabiA010003002.port.Q_flow + (TC_1474_1475.port_a.Q_flow + TC_1474_1485.port_a.Q_flow)))))) = 0.0; AIR0CabiA010003002.port.T = TC_1288_1474.port_b.T; AIR0CabiA010003002.port.T = TC_1473_1474.port_b.T; AIR0CabiA010003002.port.T = TC_1474_1475.port_a.T; AIR0CabiA010003002.port.T = TC_1474_1485.port_a.T; AIR0CabiA010003002.port.T = TC_36_1474.port_b.T; AIR0CabiA010003002.port.T = TC_819_1474.port_b.T; AIR0CabiA010003002.port.T = TsAIR0CabiA010003002.port.T; TsAIR0CabiA009003002.port.Q_flow + (TC_1472_1473.port_b.Q_flow + (TC_1287_1473.port_b.Q_flow + (TC_818_1473.port_b.Q_flow + (TC_35_1473.port_b.Q_flow + (AIR0CabiA009003002.port.Q_flow + (TC_1473_1474.port_a.Q_flow + TC_1473_1484.port_a.Q_flow)))))) = 0.0; AIR0CabiA009003002.port.T = TC_1287_1473.port_b.T; AIR0CabiA009003002.port.T = TC_1472_1473.port_b.T; AIR0CabiA009003002.port.T = TC_1473_1474.port_a.T; AIR0CabiA009003002.port.T = TC_1473_1484.port_a.T; AIR0CabiA009003002.port.T = TC_35_1473.port_b.T; AIR0CabiA009003002.port.T = TC_818_1473.port_b.T; AIR0CabiA009003002.port.T = TsAIR0CabiA009003002.port.T; TsAIR0CabiA008003002.port.Q_flow + (TC_1471_1472.port_b.Q_flow + (TC_1286_1472.port_b.Q_flow + (TC_817_1472.port_b.Q_flow + (TC_34_1472.port_b.Q_flow + (AIR0CabiA008003002.port.Q_flow + (TC_1472_1473.port_a.Q_flow + TC_1472_1483.port_a.Q_flow)))))) = 0.0; AIR0CabiA008003002.port.T = TC_1286_1472.port_b.T; AIR0CabiA008003002.port.T = TC_1471_1472.port_b.T; AIR0CabiA008003002.port.T = TC_1472_1473.port_a.T; AIR0CabiA008003002.port.T = TC_1472_1483.port_a.T; AIR0CabiA008003002.port.T = TC_34_1472.port_b.T; AIR0CabiA008003002.port.T = TC_817_1472.port_b.T; AIR0CabiA008003002.port.T = TsAIR0CabiA008003002.port.T; TsAIR0CabiA007003002.port.Q_flow + (TC_1470_1471.port_b.Q_flow + (TC_1285_1471.port_b.Q_flow + (TC_816_1471.port_b.Q_flow + (TC_33_1471.port_b.Q_flow + (AIR0CabiA007003002.port.Q_flow + (TC_1471_1472.port_a.Q_flow + TC_1471_1482.port_a.Q_flow)))))) = 0.0; AIR0CabiA007003002.port.T = TC_1285_1471.port_b.T; AIR0CabiA007003002.port.T = TC_1470_1471.port_b.T; AIR0CabiA007003002.port.T = TC_1471_1472.port_a.T; AIR0CabiA007003002.port.T = TC_1471_1482.port_a.T; AIR0CabiA007003002.port.T = TC_33_1471.port_b.T; AIR0CabiA007003002.port.T = TC_816_1471.port_b.T; AIR0CabiA007003002.port.T = TsAIR0CabiA007003002.port.T; TsAIR0CabiA006003002.port.Q_flow + (TC_1469_1470.port_b.Q_flow + (TC_1284_1470.port_b.Q_flow + (TC_815_1470.port_b.Q_flow + (TC_32_1470.port_b.Q_flow + (AIR0CabiA006003002.port.Q_flow + (TC_1470_1471.port_a.Q_flow + TC_1470_1481.port_a.Q_flow)))))) = 0.0; AIR0CabiA006003002.port.T = TC_1284_1470.port_b.T; AIR0CabiA006003002.port.T = TC_1469_1470.port_b.T; AIR0CabiA006003002.port.T = TC_1470_1471.port_a.T; AIR0CabiA006003002.port.T = TC_1470_1481.port_a.T; AIR0CabiA006003002.port.T = TC_32_1470.port_b.T; AIR0CabiA006003002.port.T = TC_815_1470.port_b.T; AIR0CabiA006003002.port.T = TsAIR0CabiA006003002.port.T; TsAIR0CabiA005003002.port.Q_flow + (TC_1468_1469.port_b.Q_flow + (TC_1283_1469.port_b.Q_flow + (TC_814_1469.port_b.Q_flow + (TC_31_1469.port_b.Q_flow + (AIR0CabiA005003002.port.Q_flow + (TC_1469_1470.port_a.Q_flow + TC_1469_1480.port_a.Q_flow)))))) = 0.0; AIR0CabiA005003002.port.T = TC_1283_1469.port_b.T; AIR0CabiA005003002.port.T = TC_1468_1469.port_b.T; AIR0CabiA005003002.port.T = TC_1469_1470.port_a.T; AIR0CabiA005003002.port.T = TC_1469_1480.port_a.T; AIR0CabiA005003002.port.T = TC_31_1469.port_b.T; AIR0CabiA005003002.port.T = TC_814_1469.port_b.T; AIR0CabiA005003002.port.T = TsAIR0CabiA005003002.port.T; TsAIR0CabiA004003002.port.Q_flow + (TC_1467_1468.port_b.Q_flow + (TC_1282_1468.port_b.Q_flow + (TC_813_1468.port_b.Q_flow + (TC_30_1468.port_b.Q_flow + (AIR0CabiA004003002.port.Q_flow + (TC_1468_1469.port_a.Q_flow + TC_1468_1479.port_a.Q_flow)))))) = 0.0; AIR0CabiA004003002.port.T = TC_1282_1468.port_b.T; AIR0CabiA004003002.port.T = TC_1467_1468.port_b.T; AIR0CabiA004003002.port.T = TC_1468_1469.port_a.T; AIR0CabiA004003002.port.T = TC_1468_1479.port_a.T; AIR0CabiA004003002.port.T = TC_30_1468.port_b.T; AIR0CabiA004003002.port.T = TC_813_1468.port_b.T; AIR0CabiA004003002.port.T = TsAIR0CabiA004003002.port.T; TsAIR0CabiA003003002.port.Q_flow + (TC_1466_1467.port_b.Q_flow + (TC_1462_1467.port_b.Q_flow + (TC_1281_1467.port_b.Q_flow + (TC_29_1467.port_b.Q_flow + (AIR0CabiA003003002.port.Q_flow + (TC_1467_1468.port_a.Q_flow + TC_1467_1478.port_a.Q_flow)))))) = 0.0; AIR0CabiA003003002.port.T = TC_1281_1467.port_b.T; AIR0CabiA003003002.port.T = TC_1462_1467.port_b.T; AIR0CabiA003003002.port.T = TC_1466_1467.port_b.T; AIR0CabiA003003002.port.T = TC_1467_1468.port_a.T; AIR0CabiA003003002.port.T = TC_1467_1478.port_a.T; AIR0CabiA003003002.port.T = TC_29_1467.port_b.T; AIR0CabiA003003002.port.T = TsAIR0CabiA003003002.port.T; TsAIR0CabiA002003002.port.Q_flow + (TC_1461_1466.port_b.Q_flow + (TC_1280_1466.port_b.Q_flow + (TC_223_1466.port_b.Q_flow + (TC_28_1466.port_b.Q_flow + (AIR0CabiA002003002.port.Q_flow + (TC_1466_1467.port_a.Q_flow + TC_1466_1477.port_a.Q_flow)))))) = 0.0; AIR0CabiA002003002.port.T = TC_1280_1466.port_b.T; AIR0CabiA002003002.port.T = TC_1461_1466.port_b.T; AIR0CabiA002003002.port.T = TC_1466_1467.port_a.T; AIR0CabiA002003002.port.T = TC_1466_1477.port_a.T; AIR0CabiA002003002.port.T = TC_223_1466.port_b.T; AIR0CabiA002003002.port.T = TC_28_1466.port_b.T; AIR0CabiA002003002.port.T = TsAIR0CabiA002003002.port.T; TsAIR0CabiA003005002.port.Q_flow + (TC_1464_1465.port_b.Q_flow + (TC_1462_1465.port_b.Q_flow + (TC_1416_1465.port_b.Q_flow + (TC_1303_1465.port_b.Q_flow + (TC_741_1465.port_b.Q_flow + (TC_55_1465.port_b.Q_flow + AIR0CabiA003005002.port.Q_flow)))))) = 0.0; AIR0CabiA003005002.port.T = TC_1303_1465.port_b.T; AIR0CabiA003005002.port.T = TC_1416_1465.port_b.T; AIR0CabiA003005002.port.T = TC_1462_1465.port_b.T; AIR0CabiA003005002.port.T = TC_1464_1465.port_b.T; AIR0CabiA003005002.port.T = TC_55_1465.port_b.T; AIR0CabiA003005002.port.T = TC_741_1465.port_b.T; AIR0CabiA003005002.port.T = TsAIR0CabiA003005002.port.T; TsAIR0CabiA002005002.port.Q_flow + (TC_1461_1464.port_b.Q_flow + (TC_1415_1464.port_b.Q_flow + (TC_1302_1464.port_b.Q_flow + (TC_227_1464.port_b.Q_flow + (TC_54_1464.port_b.Q_flow + (AIR0CabiA002005002.port.Q_flow + TC_1464_1465.port_a.Q_flow)))))) = 0.0; AIR0CabiA002005002.port.T = TC_1302_1464.port_b.T; AIR0CabiA002005002.port.T = TC_1415_1464.port_b.T; AIR0CabiA002005002.port.T = TC_1461_1464.port_b.T; AIR0CabiA002005002.port.T = TC_1464_1465.port_a.T; AIR0CabiA002005002.port.T = TC_227_1464.port_b.T; AIR0CabiA002005002.port.T = TC_54_1464.port_b.T; AIR0CabiA002005002.port.T = TsAIR0CabiA002005002.port.T; TsAIR0CabiA012004002.port.Q_flow + (TC_1414_1463.port_b.Q_flow + (TC_1301_1463.port_b.Q_flow + (TC_820_1463.port_b.Q_flow + (TC_226_1463.port_b.Q_flow + (TC_51_1463.port_b.Q_flow + (AIR0CabiA012004002.port.Q_flow + TC_1463_1476.port_a.Q_flow)))))) = 0.0; AIR0CabiA012004002.port.T = TC_1301_1463.port_b.T; AIR0CabiA012004002.port.T = TC_1414_1463.port_b.T; AIR0CabiA012004002.port.T = TC_1463_1476.port_a.T; AIR0CabiA012004002.port.T = TC_226_1463.port_b.T; AIR0CabiA012004002.port.T = TC_51_1463.port_b.T; AIR0CabiA012004002.port.T = TC_820_1463.port_b.T; AIR0CabiA012004002.port.T = TsAIR0CabiA012004002.port.T; TsAIR0CabiA003004002.port.Q_flow + (TC_1461_1462.port_b.Q_flow + (TC_1292_1462.port_b.Q_flow + (TC_813_1462.port_b.Q_flow + (TC_42_1462.port_b.Q_flow + (AIR0CabiA003004002.port.Q_flow + (TC_1462_1465.port_a.Q_flow + TC_1462_1467.port_a.Q_flow)))))) = 0.0; AIR0CabiA003004002.port.T = TC_1292_1462.port_b.T; AIR0CabiA003004002.port.T = TC_1461_1462.port_b.T; AIR0CabiA003004002.port.T = TC_1462_1465.port_a.T; AIR0CabiA003004002.port.T = TC_1462_1467.port_a.T; AIR0CabiA003004002.port.T = TC_42_1462.port_b.T; AIR0CabiA003004002.port.T = TC_813_1462.port_b.T; AIR0CabiA003004002.port.T = TsAIR0CabiA003004002.port.T; TsAIR0CabiA002004002.port.Q_flow + (TC_1291_1461.port_b.Q_flow + (TC_225_1461.port_b.Q_flow + (TC_41_1461.port_b.Q_flow + (AIR0CabiA002004002.port.Q_flow + (TC_1461_1462.port_a.Q_flow + (TC_1461_1464.port_a.Q_flow + TC_1461_1466.port_a.Q_flow)))))) = 0.0; AIR0CabiA002004002.port.T = TC_1291_1461.port_b.T; AIR0CabiA002004002.port.T = TC_1461_1462.port_a.T; AIR0CabiA002004002.port.T = TC_1461_1464.port_a.T; AIR0CabiA002004002.port.T = TC_1461_1466.port_a.T; AIR0CabiA002004002.port.T = TC_225_1461.port_b.T; AIR0CabiA002004002.port.T = TC_41_1461.port_b.T; AIR0CabiA002004002.port.T = TsAIR0CabiA002004002.port.T; TsAIR0CabiA012015002.port.Q_flow + (TC_1459_1460.port_b.Q_flow + (TC_1449_1460.port_b.Q_flow + (TC_1413_1460.port_b.Q_flow + (TC_260_1460.port_b.Q_flow + (TC_248_1460.port_b.Q_flow + (TC_194_1460.port_b.Q_flow + AIR0CabiA012015002.port.Q_flow)))))) = 0.0; AIR0CabiA012015002.port.T = TC_1413_1460.port_b.T; AIR0CabiA012015002.port.T = TC_1449_1460.port_b.T; AIR0CabiA012015002.port.T = TC_1459_1460.port_b.T; AIR0CabiA012015002.port.T = TC_194_1460.port_b.T; AIR0CabiA012015002.port.T = TC_248_1460.port_b.T; AIR0CabiA012015002.port.T = TC_260_1460.port_b.T; AIR0CabiA012015002.port.T = TsAIR0CabiA012015002.port.T; TsAIR0CabiA011015002.port.Q_flow + (TC_1458_1459.port_b.Q_flow + (TC_1448_1459.port_b.Q_flow + (TC_1412_1459.port_b.Q_flow + (TC_259_1459.port_b.Q_flow + (TC_193_1459.port_b.Q_flow + (AIR0CabiA011015002.port.Q_flow + TC_1459_1460.port_a.Q_flow)))))) = 0.0; AIR0CabiA011015002.port.T = TC_1412_1459.port_b.T; AIR0CabiA011015002.port.T = TC_1448_1459.port_b.T; AIR0CabiA011015002.port.T = TC_1458_1459.port_b.T; AIR0CabiA011015002.port.T = TC_1459_1460.port_a.T; AIR0CabiA011015002.port.T = TC_193_1459.port_b.T; AIR0CabiA011015002.port.T = TC_259_1459.port_b.T; AIR0CabiA011015002.port.T = TsAIR0CabiA011015002.port.T; TsAIR0CabiA010015002.port.Q_flow + (TC_1457_1458.port_b.Q_flow + (TC_1447_1458.port_b.Q_flow + (TC_1411_1458.port_b.Q_flow + (TC_258_1458.port_b.Q_flow + (TC_192_1458.port_b.Q_flow + (AIR0CabiA010015002.port.Q_flow + TC_1458_1459.port_a.Q_flow)))))) = 0.0; AIR0CabiA010015002.port.T = TC_1411_1458.port_b.T; AIR0CabiA010015002.port.T = TC_1447_1458.port_b.T; AIR0CabiA010015002.port.T = TC_1457_1458.port_b.T; AIR0CabiA010015002.port.T = TC_1458_1459.port_a.T; AIR0CabiA010015002.port.T = TC_192_1458.port_b.T; AIR0CabiA010015002.port.T = TC_258_1458.port_b.T; AIR0CabiA010015002.port.T = TsAIR0CabiA010015002.port.T; TsAIR0CabiA009015002.port.Q_flow + (TC_1456_1457.port_b.Q_flow + (TC_1446_1457.port_b.Q_flow + (TC_1410_1457.port_b.Q_flow + (TC_257_1457.port_b.Q_flow + (TC_191_1457.port_b.Q_flow + (AIR0CabiA009015002.port.Q_flow + TC_1457_1458.port_a.Q_flow)))))) = 0.0; AIR0CabiA009015002.port.T = TC_1410_1457.port_b.T; AIR0CabiA009015002.port.T = TC_1446_1457.port_b.T; AIR0CabiA009015002.port.T = TC_1456_1457.port_b.T; AIR0CabiA009015002.port.T = TC_1457_1458.port_a.T; AIR0CabiA009015002.port.T = TC_191_1457.port_b.T; AIR0CabiA009015002.port.T = TC_257_1457.port_b.T; AIR0CabiA009015002.port.T = TsAIR0CabiA009015002.port.T; TsAIR0CabiA008015002.port.Q_flow + (TC_1455_1456.port_b.Q_flow + (TC_1445_1456.port_b.Q_flow + (TC_1409_1456.port_b.Q_flow + (TC_256_1456.port_b.Q_flow + (TC_190_1456.port_b.Q_flow + (AIR0CabiA008015002.port.Q_flow + TC_1456_1457.port_a.Q_flow)))))) = 0.0; AIR0CabiA008015002.port.T = TC_1409_1456.port_b.T; AIR0CabiA008015002.port.T = TC_1445_1456.port_b.T; AIR0CabiA008015002.port.T = TC_1455_1456.port_b.T; AIR0CabiA008015002.port.T = TC_1456_1457.port_a.T; AIR0CabiA008015002.port.T = TC_190_1456.port_b.T; AIR0CabiA008015002.port.T = TC_256_1456.port_b.T; AIR0CabiA008015002.port.T = TsAIR0CabiA008015002.port.T; TsAIR0CabiA007015002.port.Q_flow + (TC_1454_1455.port_b.Q_flow + (TC_1444_1455.port_b.Q_flow + (TC_1408_1455.port_b.Q_flow + (TC_255_1455.port_b.Q_flow + (TC_189_1455.port_b.Q_flow + (AIR0CabiA007015002.port.Q_flow + TC_1455_1456.port_a.Q_flow)))))) = 0.0; AIR0CabiA007015002.port.T = TC_1408_1455.port_b.T; AIR0CabiA007015002.port.T = TC_1444_1455.port_b.T; AIR0CabiA007015002.port.T = TC_1454_1455.port_b.T; AIR0CabiA007015002.port.T = TC_1455_1456.port_a.T; AIR0CabiA007015002.port.T = TC_189_1455.port_b.T; AIR0CabiA007015002.port.T = TC_255_1455.port_b.T; AIR0CabiA007015002.port.T = TsAIR0CabiA007015002.port.T; TsAIR0CabiA006015002.port.Q_flow + (TC_1453_1454.port_b.Q_flow + (TC_1443_1454.port_b.Q_flow + (TC_1407_1454.port_b.Q_flow + (TC_254_1454.port_b.Q_flow + (TC_188_1454.port_b.Q_flow + (AIR0CabiA006015002.port.Q_flow + TC_1454_1455.port_a.Q_flow)))))) = 0.0; AIR0CabiA006015002.port.T = TC_1407_1454.port_b.T; AIR0CabiA006015002.port.T = TC_1443_1454.port_b.T; AIR0CabiA006015002.port.T = TC_1453_1454.port_b.T; AIR0CabiA006015002.port.T = TC_1454_1455.port_a.T; AIR0CabiA006015002.port.T = TC_188_1454.port_b.T; AIR0CabiA006015002.port.T = TC_254_1454.port_b.T; AIR0CabiA006015002.port.T = TsAIR0CabiA006015002.port.T; TsAIR0CabiA005015002.port.Q_flow + (TC_1452_1453.port_b.Q_flow + (TC_1442_1453.port_b.Q_flow + (TC_1406_1453.port_b.Q_flow + (TC_253_1453.port_b.Q_flow + (TC_187_1453.port_b.Q_flow + (AIR0CabiA005015002.port.Q_flow + TC_1453_1454.port_a.Q_flow)))))) = 0.0; AIR0CabiA005015002.port.T = TC_1406_1453.port_b.T; AIR0CabiA005015002.port.T = TC_1442_1453.port_b.T; AIR0CabiA005015002.port.T = TC_1452_1453.port_b.T; AIR0CabiA005015002.port.T = TC_1453_1454.port_a.T; AIR0CabiA005015002.port.T = TC_187_1453.port_b.T; AIR0CabiA005015002.port.T = TC_253_1453.port_b.T; AIR0CabiA005015002.port.T = TsAIR0CabiA005015002.port.T; TsAIR0CabiA004015002.port.Q_flow + (TC_1451_1452.port_b.Q_flow + (TC_1441_1452.port_b.Q_flow + (TC_1405_1452.port_b.Q_flow + (TC_252_1452.port_b.Q_flow + (TC_186_1452.port_b.Q_flow + (AIR0CabiA004015002.port.Q_flow + TC_1452_1453.port_a.Q_flow)))))) = 0.0; AIR0CabiA004015002.port.T = TC_1405_1452.port_b.T; AIR0CabiA004015002.port.T = TC_1441_1452.port_b.T; AIR0CabiA004015002.port.T = TC_1451_1452.port_b.T; AIR0CabiA004015002.port.T = TC_1452_1453.port_a.T; AIR0CabiA004015002.port.T = TC_186_1452.port_b.T; AIR0CabiA004015002.port.T = TC_252_1452.port_b.T; AIR0CabiA004015002.port.T = TsAIR0CabiA004015002.port.T; TsAIR0CabiA003015002.port.Q_flow + (TC_1450_1451.port_b.Q_flow + (TC_1440_1451.port_b.Q_flow + (TC_1404_1451.port_b.Q_flow + (TC_251_1451.port_b.Q_flow + (TC_185_1451.port_b.Q_flow + (AIR0CabiA003015002.port.Q_flow + TC_1451_1452.port_a.Q_flow)))))) = 0.0; AIR0CabiA003015002.port.T = TC_1404_1451.port_b.T; AIR0CabiA003015002.port.T = TC_1440_1451.port_b.T; AIR0CabiA003015002.port.T = TC_1450_1451.port_b.T; AIR0CabiA003015002.port.T = TC_1451_1452.port_a.T; AIR0CabiA003015002.port.T = TC_185_1451.port_b.T; AIR0CabiA003015002.port.T = TC_251_1451.port_b.T; AIR0CabiA003015002.port.T = TsAIR0CabiA003015002.port.T; TsAIR0CabiA002015002.port.Q_flow + (TC_1439_1450.port_b.Q_flow + (TC_1403_1450.port_b.Q_flow + (TC_250_1450.port_b.Q_flow + (TC_247_1450.port_b.Q_flow + (TC_184_1450.port_b.Q_flow + (AIR0CabiA002015002.port.Q_flow + TC_1450_1451.port_a.Q_flow)))))) = 0.0; AIR0CabiA002015002.port.T = TC_1403_1450.port_b.T; AIR0CabiA002015002.port.T = TC_1439_1450.port_b.T; AIR0CabiA002015002.port.T = TC_1450_1451.port_a.T; AIR0CabiA002015002.port.T = TC_184_1450.port_b.T; AIR0CabiA002015002.port.T = TC_247_1450.port_b.T; AIR0CabiA002015002.port.T = TC_250_1450.port_b.T; AIR0CabiA002015002.port.T = TsAIR0CabiA002015002.port.T; TsAIR0CabiA012014002.port.Q_flow + (TC_1448_1449.port_b.Q_flow + (TC_1438_1449.port_b.Q_flow + (TC_1402_1449.port_b.Q_flow + (TC_246_1449.port_b.Q_flow + (TC_181_1449.port_b.Q_flow + (AIR0CabiA012014002.port.Q_flow + TC_1449_1460.port_a.Q_flow)))))) = 0.0; AIR0CabiA012014002.port.T = TC_1402_1449.port_b.T; AIR0CabiA012014002.port.T = TC_1438_1449.port_b.T; AIR0CabiA012014002.port.T = TC_1448_1449.port_b.T; AIR0CabiA012014002.port.T = TC_1449_1460.port_a.T; AIR0CabiA012014002.port.T = TC_181_1449.port_b.T; AIR0CabiA012014002.port.T = TC_246_1449.port_b.T; AIR0CabiA012014002.port.T = TsAIR0CabiA012014002.port.T; TsAIR0CabiA011014002.port.Q_flow + (TC_1447_1448.port_b.Q_flow + (TC_1401_1448.port_b.Q_flow + (TC_812_1448.port_b.Q_flow + (TC_180_1448.port_b.Q_flow + (AIR0CabiA011014002.port.Q_flow + (TC_1448_1449.port_a.Q_flow + TC_1448_1459.port_a.Q_flow)))))) = 0.0; AIR0CabiA011014002.port.T = TC_1401_1448.port_b.T; AIR0CabiA011014002.port.T = TC_1447_1448.port_b.T; AIR0CabiA011014002.port.T = TC_1448_1449.port_a.T; AIR0CabiA011014002.port.T = TC_1448_1459.port_a.T; AIR0CabiA011014002.port.T = TC_180_1448.port_b.T; AIR0CabiA011014002.port.T = TC_812_1448.port_b.T; AIR0CabiA011014002.port.T = TsAIR0CabiA011014002.port.T; TsAIR0CabiA010014002.port.Q_flow + (TC_1446_1447.port_b.Q_flow + (TC_1400_1447.port_b.Q_flow + (TC_811_1447.port_b.Q_flow + (TC_179_1447.port_b.Q_flow + (AIR0CabiA010014002.port.Q_flow + (TC_1447_1448.port_a.Q_flow + TC_1447_1458.port_a.Q_flow)))))) = 0.0; AIR0CabiA010014002.port.T = TC_1400_1447.port_b.T; AIR0CabiA010014002.port.T = TC_1446_1447.port_b.T; AIR0CabiA010014002.port.T = TC_1447_1448.port_a.T; AIR0CabiA010014002.port.T = TC_1447_1458.port_a.T; AIR0CabiA010014002.port.T = TC_179_1447.port_b.T; AIR0CabiA010014002.port.T = TC_811_1447.port_b.T; AIR0CabiA010014002.port.T = TsAIR0CabiA010014002.port.T; TsAIR0CabiA009014002.port.Q_flow + (TC_1445_1446.port_b.Q_flow + (TC_1399_1446.port_b.Q_flow + (TC_810_1446.port_b.Q_flow + (TC_178_1446.port_b.Q_flow + (AIR0CabiA009014002.port.Q_flow + (TC_1446_1447.port_a.Q_flow + TC_1446_1457.port_a.Q_flow)))))) = 0.0; AIR0CabiA009014002.port.T = TC_1399_1446.port_b.T; AIR0CabiA009014002.port.T = TC_1445_1446.port_b.T; AIR0CabiA009014002.port.T = TC_1446_1447.port_a.T; AIR0CabiA009014002.port.T = TC_1446_1457.port_a.T; AIR0CabiA009014002.port.T = TC_178_1446.port_b.T; AIR0CabiA009014002.port.T = TC_810_1446.port_b.T; AIR0CabiA009014002.port.T = TsAIR0CabiA009014002.port.T; TsAIR0CabiA008014002.port.Q_flow + (TC_1444_1445.port_b.Q_flow + (TC_1398_1445.port_b.Q_flow + (TC_809_1445.port_b.Q_flow + (TC_177_1445.port_b.Q_flow + (AIR0CabiA008014002.port.Q_flow + (TC_1445_1446.port_a.Q_flow + TC_1445_1456.port_a.Q_flow)))))) = 0.0; AIR0CabiA008014002.port.T = TC_1398_1445.port_b.T; AIR0CabiA008014002.port.T = TC_1444_1445.port_b.T; AIR0CabiA008014002.port.T = TC_1445_1446.port_a.T; AIR0CabiA008014002.port.T = TC_1445_1456.port_a.T; AIR0CabiA008014002.port.T = TC_177_1445.port_b.T; AIR0CabiA008014002.port.T = TC_809_1445.port_b.T; AIR0CabiA008014002.port.T = TsAIR0CabiA008014002.port.T; TsAIR0CabiA007014002.port.Q_flow + (TC_1443_1444.port_b.Q_flow + (TC_1397_1444.port_b.Q_flow + (TC_808_1444.port_b.Q_flow + (TC_176_1444.port_b.Q_flow + (AIR0CabiA007014002.port.Q_flow + (TC_1444_1445.port_a.Q_flow + TC_1444_1455.port_a.Q_flow)))))) = 0.0; AIR0CabiA007014002.port.T = TC_1397_1444.port_b.T; AIR0CabiA007014002.port.T = TC_1443_1444.port_b.T; AIR0CabiA007014002.port.T = TC_1444_1445.port_a.T; AIR0CabiA007014002.port.T = TC_1444_1455.port_a.T; AIR0CabiA007014002.port.T = TC_176_1444.port_b.T; AIR0CabiA007014002.port.T = TC_808_1444.port_b.T; AIR0CabiA007014002.port.T = TsAIR0CabiA007014002.port.T; TsAIR0CabiA006014002.port.Q_flow + (TC_1442_1443.port_b.Q_flow + (TC_1396_1443.port_b.Q_flow + (TC_807_1443.port_b.Q_flow + (TC_175_1443.port_b.Q_flow + (AIR0CabiA006014002.port.Q_flow + (TC_1443_1444.port_a.Q_flow + TC_1443_1454.port_a.Q_flow)))))) = 0.0; AIR0CabiA006014002.port.T = TC_1396_1443.port_b.T; AIR0CabiA006014002.port.T = TC_1442_1443.port_b.T; AIR0CabiA006014002.port.T = TC_1443_1444.port_a.T; AIR0CabiA006014002.port.T = TC_1443_1454.port_a.T; AIR0CabiA006014002.port.T = TC_175_1443.port_b.T; AIR0CabiA006014002.port.T = TC_807_1443.port_b.T; AIR0CabiA006014002.port.T = TsAIR0CabiA006014002.port.T; TsAIR0CabiA005014002.port.Q_flow + (TC_1441_1442.port_b.Q_flow + (TC_1395_1442.port_b.Q_flow + (TC_806_1442.port_b.Q_flow + (TC_174_1442.port_b.Q_flow + (AIR0CabiA005014002.port.Q_flow + (TC_1442_1443.port_a.Q_flow + TC_1442_1453.port_a.Q_flow)))))) = 0.0; AIR0CabiA005014002.port.T = TC_1395_1442.port_b.T; AIR0CabiA005014002.port.T = TC_1441_1442.port_b.T; AIR0CabiA005014002.port.T = TC_1442_1443.port_a.T; AIR0CabiA005014002.port.T = TC_1442_1453.port_a.T; AIR0CabiA005014002.port.T = TC_174_1442.port_b.T; AIR0CabiA005014002.port.T = TC_806_1442.port_b.T; AIR0CabiA005014002.port.T = TsAIR0CabiA005014002.port.T; TsAIR0CabiA004014002.port.Q_flow + (TC_1440_1441.port_b.Q_flow + (TC_1394_1441.port_b.Q_flow + (TC_805_1441.port_b.Q_flow + (TC_173_1441.port_b.Q_flow + (AIR0CabiA004014002.port.Q_flow + (TC_1441_1442.port_a.Q_flow + TC_1441_1452.port_a.Q_flow)))))) = 0.0; AIR0CabiA004014002.port.T = TC_1394_1441.port_b.T; AIR0CabiA004014002.port.T = TC_1440_1441.port_b.T; AIR0CabiA004014002.port.T = TC_1441_1442.port_a.T; AIR0CabiA004014002.port.T = TC_1441_1452.port_a.T; AIR0CabiA004014002.port.T = TC_173_1441.port_b.T; AIR0CabiA004014002.port.T = TC_805_1441.port_b.T; AIR0CabiA004014002.port.T = TsAIR0CabiA004014002.port.T; TsAIR0CabiA003014002.port.Q_flow + (TC_1439_1440.port_b.Q_flow + (TC_1437_1440.port_b.Q_flow + (TC_1393_1440.port_b.Q_flow + (TC_172_1440.port_b.Q_flow + (AIR0CabiA003014002.port.Q_flow + (TC_1440_1441.port_a.Q_flow + TC_1440_1451.port_a.Q_flow)))))) = 0.0; AIR0CabiA003014002.port.T = TC_1393_1440.port_b.T; AIR0CabiA003014002.port.T = TC_1437_1440.port_b.T; AIR0CabiA003014002.port.T = TC_1439_1440.port_b.T; AIR0CabiA003014002.port.T = TC_1440_1441.port_a.T; AIR0CabiA003014002.port.T = TC_1440_1451.port_a.T; AIR0CabiA003014002.port.T = TC_172_1440.port_b.T; AIR0CabiA003014002.port.T = TsAIR0CabiA003014002.port.T; TsAIR0CabiA002014002.port.Q_flow + (TC_1436_1439.port_b.Q_flow + (TC_1392_1439.port_b.Q_flow + (TC_245_1439.port_b.Q_flow + (TC_171_1439.port_b.Q_flow + (AIR0CabiA002014002.port.Q_flow + (TC_1439_1440.port_a.Q_flow + TC_1439_1450.port_a.Q_flow)))))) = 0.0; AIR0CabiA002014002.port.T = TC_1392_1439.port_b.T; AIR0CabiA002014002.port.T = TC_1436_1439.port_b.T; AIR0CabiA002014002.port.T = TC_1439_1440.port_a.T; AIR0CabiA002014002.port.T = TC_1439_1450.port_a.T; AIR0CabiA002014002.port.T = TC_171_1439.port_b.T; AIR0CabiA002014002.port.T = TC_245_1439.port_b.T; AIR0CabiA002014002.port.T = TsAIR0CabiA002014002.port.T; TsAIR0CabiA012013002.port.Q_flow + (TC_1435_1438.port_b.Q_flow + (TC_1391_1438.port_b.Q_flow + (TC_812_1438.port_b.Q_flow + (TC_244_1438.port_b.Q_flow + (TC_168_1438.port_b.Q_flow + (AIR0CabiA012013002.port.Q_flow + TC_1438_1449.port_a.Q_flow)))))) = 0.0; AIR0CabiA012013002.port.T = TC_1391_1438.port_b.T; AIR0CabiA012013002.port.T = TC_1435_1438.port_b.T; AIR0CabiA012013002.port.T = TC_1438_1449.port_a.T; AIR0CabiA012013002.port.T = TC_168_1438.port_b.T; AIR0CabiA012013002.port.T = TC_244_1438.port_b.T; AIR0CabiA012013002.port.T = TC_812_1438.port_b.T; AIR0CabiA012013002.port.T = TsAIR0CabiA012013002.port.T; TsAIR0CabiA003013002.port.Q_flow + (TC_1436_1437.port_b.Q_flow + (TC_1434_1437.port_b.Q_flow + (TC_1382_1437.port_b.Q_flow + (TC_805_1437.port_b.Q_flow + (TC_159_1437.port_b.Q_flow + (AIR0CabiA003013002.port.Q_flow + TC_1437_1440.port_a.Q_flow)))))) = 0.0; AIR0CabiA003013002.port.T = TC_1382_1437.port_b.T; AIR0CabiA003013002.port.T = TC_1434_1437.port_b.T; AIR0CabiA003013002.port.T = TC_1436_1437.port_b.T; AIR0CabiA003013002.port.T = TC_1437_1440.port_a.T; AIR0CabiA003013002.port.T = TC_159_1437.port_b.T; AIR0CabiA003013002.port.T = TC_805_1437.port_b.T; AIR0CabiA003013002.port.T = TsAIR0CabiA003013002.port.T; TsAIR0CabiA002013002.port.Q_flow + (TC_1433_1436.port_b.Q_flow + (TC_1381_1436.port_b.Q_flow + (TC_243_1436.port_b.Q_flow + (TC_158_1436.port_b.Q_flow + (AIR0CabiA002013002.port.Q_flow + (TC_1436_1437.port_a.Q_flow + TC_1436_1439.port_a.Q_flow)))))) = 0.0; AIR0CabiA002013002.port.T = TC_1381_1436.port_b.T; AIR0CabiA002013002.port.T = TC_1433_1436.port_b.T; AIR0CabiA002013002.port.T = TC_1436_1437.port_a.T; AIR0CabiA002013002.port.T = TC_1436_1439.port_a.T; AIR0CabiA002013002.port.T = TC_158_1436.port_b.T; AIR0CabiA002013002.port.T = TC_243_1436.port_b.T; AIR0CabiA002013002.port.T = TsAIR0CabiA002013002.port.T; TsAIR0CabiA012012002.port.Q_flow + (TC_1432_1435.port_b.Q_flow + (TC_1380_1435.port_b.Q_flow + (TC_804_1435.port_b.Q_flow + (TC_242_1435.port_b.Q_flow + (TC_155_1435.port_b.Q_flow + (AIR0CabiA012012002.port.Q_flow + TC_1435_1438.port_a.Q_flow)))))) = 0.0; AIR0CabiA012012002.port.T = TC_1380_1435.port_b.T; AIR0CabiA012012002.port.T = TC_1432_1435.port_b.T; AIR0CabiA012012002.port.T = TC_1435_1438.port_a.T; AIR0CabiA012012002.port.T = TC_155_1435.port_b.T; AIR0CabiA012012002.port.T = TC_242_1435.port_b.T; AIR0CabiA012012002.port.T = TC_804_1435.port_b.T; AIR0CabiA012012002.port.T = TsAIR0CabiA012012002.port.T; TsAIR0CabiA003012002.port.Q_flow + (TC_1433_1434.port_b.Q_flow + (TC_1431_1434.port_b.Q_flow + (TC_1371_1434.port_b.Q_flow + (TC_797_1434.port_b.Q_flow + (TC_146_1434.port_b.Q_flow + (AIR0CabiA003012002.port.Q_flow + TC_1434_1437.port_a.Q_flow)))))) = 0.0; AIR0CabiA003012002.port.T = TC_1371_1434.port_b.T; AIR0CabiA003012002.port.T = TC_1431_1434.port_b.T; AIR0CabiA003012002.port.T = TC_1433_1434.port_b.T; AIR0CabiA003012002.port.T = TC_1434_1437.port_a.T; AIR0CabiA003012002.port.T = TC_146_1434.port_b.T; AIR0CabiA003012002.port.T = TC_797_1434.port_b.T; AIR0CabiA003012002.port.T = TsAIR0CabiA003012002.port.T; TsAIR0CabiA002012002.port.Q_flow + (TC_1430_1433.port_b.Q_flow + (TC_1370_1433.port_b.Q_flow + (TC_241_1433.port_b.Q_flow + (TC_145_1433.port_b.Q_flow + (AIR0CabiA002012002.port.Q_flow + (TC_1433_1434.port_a.Q_flow + TC_1433_1436.port_a.Q_flow)))))) = 0.0; AIR0CabiA002012002.port.T = TC_1370_1433.port_b.T; AIR0CabiA002012002.port.T = TC_1430_1433.port_b.T; AIR0CabiA002012002.port.T = TC_1433_1434.port_a.T; AIR0CabiA002012002.port.T = TC_1433_1436.port_a.T; AIR0CabiA002012002.port.T = TC_145_1433.port_b.T; AIR0CabiA002012002.port.T = TC_241_1433.port_b.T; AIR0CabiA002012002.port.T = TsAIR0CabiA002012002.port.T; TsAIR0CabiA012011002.port.Q_flow + (TC_1429_1432.port_b.Q_flow + (TC_1369_1432.port_b.Q_flow + (TC_796_1432.port_b.Q_flow + (TC_240_1432.port_b.Q_flow + (TC_142_1432.port_b.Q_flow + (AIR0CabiA012011002.port.Q_flow + TC_1432_1435.port_a.Q_flow)))))) = 0.0; AIR0CabiA012011002.port.T = TC_1369_1432.port_b.T; AIR0CabiA012011002.port.T = TC_1429_1432.port_b.T; AIR0CabiA012011002.port.T = TC_142_1432.port_b.T; AIR0CabiA012011002.port.T = TC_1432_1435.port_a.T; AIR0CabiA012011002.port.T = TC_240_1432.port_b.T; AIR0CabiA012011002.port.T = TC_796_1432.port_b.T; AIR0CabiA012011002.port.T = TsAIR0CabiA012011002.port.T; TsAIR0CabiA003011002.port.Q_flow + (TC_1430_1431.port_b.Q_flow + (TC_1428_1431.port_b.Q_flow + (TC_1360_1431.port_b.Q_flow + (TC_789_1431.port_b.Q_flow + (TC_133_1431.port_b.Q_flow + (AIR0CabiA003011002.port.Q_flow + TC_1431_1434.port_a.Q_flow)))))) = 0.0; AIR0CabiA003011002.port.T = TC_133_1431.port_b.T; AIR0CabiA003011002.port.T = TC_1360_1431.port_b.T; AIR0CabiA003011002.port.T = TC_1428_1431.port_b.T; AIR0CabiA003011002.port.T = TC_1430_1431.port_b.T; AIR0CabiA003011002.port.T = TC_1431_1434.port_a.T; AIR0CabiA003011002.port.T = TC_789_1431.port_b.T; AIR0CabiA003011002.port.T = TsAIR0CabiA003011002.port.T; TsAIR0CabiA002011002.port.Q_flow + (TC_1427_1430.port_b.Q_flow + (TC_1359_1430.port_b.Q_flow + (TC_239_1430.port_b.Q_flow + (TC_132_1430.port_b.Q_flow + (AIR0CabiA002011002.port.Q_flow + (TC_1430_1431.port_a.Q_flow + TC_1430_1433.port_a.Q_flow)))))) = 0.0; AIR0CabiA002011002.port.T = TC_132_1430.port_b.T; AIR0CabiA002011002.port.T = TC_1359_1430.port_b.T; AIR0CabiA002011002.port.T = TC_1427_1430.port_b.T; AIR0CabiA002011002.port.T = TC_1430_1431.port_a.T; AIR0CabiA002011002.port.T = TC_1430_1433.port_a.T; AIR0CabiA002011002.port.T = TC_239_1430.port_b.T; AIR0CabiA002011002.port.T = TsAIR0CabiA002011002.port.T; TsAIR0CabiA012010002.port.Q_flow + (TC_1426_1429.port_b.Q_flow + (TC_1358_1429.port_b.Q_flow + (TC_788_1429.port_b.Q_flow + (TC_238_1429.port_b.Q_flow + (TC_129_1429.port_b.Q_flow + (AIR0CabiA012010002.port.Q_flow + TC_1429_1432.port_a.Q_flow)))))) = 0.0; AIR0CabiA012010002.port.T = TC_129_1429.port_b.T; AIR0CabiA012010002.port.T = TC_1358_1429.port_b.T; AIR0CabiA012010002.port.T = TC_1426_1429.port_b.T; AIR0CabiA012010002.port.T = TC_1429_1432.port_a.T; AIR0CabiA012010002.port.T = TC_238_1429.port_b.T; AIR0CabiA012010002.port.T = TC_788_1429.port_b.T; AIR0CabiA012010002.port.T = TsAIR0CabiA012010002.port.T; TsAIR0CabiA003010002.port.Q_flow + (TC_1427_1428.port_b.Q_flow + (TC_1425_1428.port_b.Q_flow + (TC_1352_1428.port_b.Q_flow + (TC_781_1428.port_b.Q_flow + (TC_120_1428.port_b.Q_flow + (AIR0CabiA003010002.port.Q_flow + TC_1428_1431.port_a.Q_flow)))))) = 0.0; AIR0CabiA003010002.port.T = TC_120_1428.port_b.T; AIR0CabiA003010002.port.T = TC_1352_1428.port_b.T; AIR0CabiA003010002.port.T = TC_1425_1428.port_b.T; AIR0CabiA003010002.port.T = TC_1427_1428.port_b.T; AIR0CabiA003010002.port.T = TC_1428_1431.port_a.T; AIR0CabiA003010002.port.T = TC_781_1428.port_b.T; AIR0CabiA003010002.port.T = TsAIR0CabiA003010002.port.T; TsAIR0CabiA002010002.port.Q_flow + (TC_1424_1427.port_b.Q_flow + (TC_1351_1427.port_b.Q_flow + (TC_237_1427.port_b.Q_flow + (TC_119_1427.port_b.Q_flow + (AIR0CabiA002010002.port.Q_flow + (TC_1427_1428.port_a.Q_flow + TC_1427_1430.port_a.Q_flow)))))) = 0.0; AIR0CabiA002010002.port.T = TC_119_1427.port_b.T; AIR0CabiA002010002.port.T = TC_1351_1427.port_b.T; AIR0CabiA002010002.port.T = TC_1424_1427.port_b.T; AIR0CabiA002010002.port.T = TC_1427_1428.port_a.T; AIR0CabiA002010002.port.T = TC_1427_1430.port_a.T; AIR0CabiA002010002.port.T = TC_237_1427.port_b.T; AIR0CabiA002010002.port.T = TsAIR0CabiA002010002.port.T; TsAIR0CabiA012009002.port.Q_flow + (TC_1423_1426.port_b.Q_flow + (TC_1350_1426.port_b.Q_flow + (TC_780_1426.port_b.Q_flow + (TC_236_1426.port_b.Q_flow + (TC_116_1426.port_b.Q_flow + (AIR0CabiA012009002.port.Q_flow + TC_1426_1429.port_a.Q_flow)))))) = 0.0; AIR0CabiA012009002.port.T = TC_116_1426.port_b.T; AIR0CabiA012009002.port.T = TC_1350_1426.port_b.T; AIR0CabiA012009002.port.T = TC_1423_1426.port_b.T; AIR0CabiA012009002.port.T = TC_1426_1429.port_a.T; AIR0CabiA012009002.port.T = TC_236_1426.port_b.T; AIR0CabiA012009002.port.T = TC_780_1426.port_b.T; AIR0CabiA012009002.port.T = TsAIR0CabiA012009002.port.T; TsAIR0CabiA003009002.port.Q_flow + (TC_1424_1425.port_b.Q_flow + (TC_1422_1425.port_b.Q_flow + (TC_1344_1425.port_b.Q_flow + (TC_773_1425.port_b.Q_flow + (TC_107_1425.port_b.Q_flow + (AIR0CabiA003009002.port.Q_flow + TC_1425_1428.port_a.Q_flow)))))) = 0.0; AIR0CabiA003009002.port.T = TC_107_1425.port_b.T; AIR0CabiA003009002.port.T = TC_1344_1425.port_b.T; AIR0CabiA003009002.port.T = TC_1422_1425.port_b.T; AIR0CabiA003009002.port.T = TC_1424_1425.port_b.T; AIR0CabiA003009002.port.T = TC_1425_1428.port_a.T; AIR0CabiA003009002.port.T = TC_773_1425.port_b.T; AIR0CabiA003009002.port.T = TsAIR0CabiA003009002.port.T; TsAIR0CabiA002009002.port.Q_flow + (TC_1421_1424.port_b.Q_flow + (TC_1343_1424.port_b.Q_flow + (TC_235_1424.port_b.Q_flow + (TC_106_1424.port_b.Q_flow + (AIR0CabiA002009002.port.Q_flow + (TC_1424_1425.port_a.Q_flow + TC_1424_1427.port_a.Q_flow)))))) = 0.0; AIR0CabiA002009002.port.T = TC_106_1424.port_b.T; AIR0CabiA002009002.port.T = TC_1343_1424.port_b.T; AIR0CabiA002009002.port.T = TC_1421_1424.port_b.T; AIR0CabiA002009002.port.T = TC_1424_1425.port_a.T; AIR0CabiA002009002.port.T = TC_1424_1427.port_a.T; AIR0CabiA002009002.port.T = TC_235_1424.port_b.T; AIR0CabiA002009002.port.T = TsAIR0CabiA002009002.port.T; TsAIR0CabiA012008002.port.Q_flow + (TC_1420_1423.port_b.Q_flow + (TC_1342_1423.port_b.Q_flow + (TC_772_1423.port_b.Q_flow + (TC_234_1423.port_b.Q_flow + (TC_103_1423.port_b.Q_flow + (AIR0CabiA012008002.port.Q_flow + TC_1423_1426.port_a.Q_flow)))))) = 0.0; AIR0CabiA012008002.port.T = TC_103_1423.port_b.T; AIR0CabiA012008002.port.T = TC_1342_1423.port_b.T; AIR0CabiA012008002.port.T = TC_1420_1423.port_b.T; AIR0CabiA012008002.port.T = TC_1423_1426.port_a.T; AIR0CabiA012008002.port.T = TC_234_1423.port_b.T; AIR0CabiA012008002.port.T = TC_772_1423.port_b.T; AIR0CabiA012008002.port.T = TsAIR0CabiA012008002.port.T; TsAIR0CabiA003008002.port.Q_flow + (TC_1421_1422.port_b.Q_flow + (TC_1419_1422.port_b.Q_flow + (TC_1336_1422.port_b.Q_flow + (TC_765_1422.port_b.Q_flow + (TC_94_1422.port_b.Q_flow + (AIR0CabiA003008002.port.Q_flow + TC_1422_1425.port_a.Q_flow)))))) = 0.0; AIR0CabiA003008002.port.T = TC_1336_1422.port_b.T; AIR0CabiA003008002.port.T = TC_1419_1422.port_b.T; AIR0CabiA003008002.port.T = TC_1421_1422.port_b.T; AIR0CabiA003008002.port.T = TC_1422_1425.port_a.T; AIR0CabiA003008002.port.T = TC_765_1422.port_b.T; AIR0CabiA003008002.port.T = TC_94_1422.port_b.T; AIR0CabiA003008002.port.T = TsAIR0CabiA003008002.port.T; TsAIR0CabiA002008002.port.Q_flow + (TC_1418_1421.port_b.Q_flow + (TC_1335_1421.port_b.Q_flow + (TC_233_1421.port_b.Q_flow + (TC_93_1421.port_b.Q_flow + (AIR0CabiA002008002.port.Q_flow + (TC_1421_1422.port_a.Q_flow + TC_1421_1424.port_a.Q_flow)))))) = 0.0; AIR0CabiA002008002.port.T = TC_1335_1421.port_b.T; AIR0CabiA002008002.port.T = TC_1418_1421.port_b.T; AIR0CabiA002008002.port.T = TC_1421_1422.port_a.T; AIR0CabiA002008002.port.T = TC_1421_1424.port_a.T; AIR0CabiA002008002.port.T = TC_233_1421.port_b.T; AIR0CabiA002008002.port.T = TC_93_1421.port_b.T; AIR0CabiA002008002.port.T = TsAIR0CabiA002008002.port.T; TsAIR0CabiA012007002.port.Q_flow + (TC_1417_1420.port_b.Q_flow + (TC_1334_1420.port_b.Q_flow + (TC_764_1420.port_b.Q_flow + (TC_232_1420.port_b.Q_flow + (TC_90_1420.port_b.Q_flow + (AIR0CabiA012007002.port.Q_flow + TC_1420_1423.port_a.Q_flow)))))) = 0.0; AIR0CabiA012007002.port.T = TC_1334_1420.port_b.T; AIR0CabiA012007002.port.T = TC_1417_1420.port_b.T; AIR0CabiA012007002.port.T = TC_1420_1423.port_a.T; AIR0CabiA012007002.port.T = TC_232_1420.port_b.T; AIR0CabiA012007002.port.T = TC_764_1420.port_b.T; AIR0CabiA012007002.port.T = TC_90_1420.port_b.T; AIR0CabiA012007002.port.T = TsAIR0CabiA012007002.port.T; TsAIR0CabiA003007002.port.Q_flow + (TC_1418_1419.port_b.Q_flow + (TC_1416_1419.port_b.Q_flow + (TC_1325_1419.port_b.Q_flow + (TC_757_1419.port_b.Q_flow + (TC_81_1419.port_b.Q_flow + (AIR0CabiA003007002.port.Q_flow + TC_1419_1422.port_a.Q_flow)))))) = 0.0; AIR0CabiA003007002.port.T = TC_1325_1419.port_b.T; AIR0CabiA003007002.port.T = TC_1416_1419.port_b.T; AIR0CabiA003007002.port.T = TC_1418_1419.port_b.T; AIR0CabiA003007002.port.T = TC_1419_1422.port_a.T; AIR0CabiA003007002.port.T = TC_757_1419.port_b.T; AIR0CabiA003007002.port.T = TC_81_1419.port_b.T; AIR0CabiA003007002.port.T = TsAIR0CabiA003007002.port.T; TsAIR0CabiA002007002.port.Q_flow + (TC_1415_1418.port_b.Q_flow + (TC_1324_1418.port_b.Q_flow + (TC_231_1418.port_b.Q_flow + (TC_80_1418.port_b.Q_flow + (AIR0CabiA002007002.port.Q_flow + (TC_1418_1419.port_a.Q_flow + TC_1418_1421.port_a.Q_flow)))))) = 0.0; AIR0CabiA002007002.port.T = TC_1324_1418.port_b.T; AIR0CabiA002007002.port.T = TC_1415_1418.port_b.T; AIR0CabiA002007002.port.T = TC_1418_1419.port_a.T; AIR0CabiA002007002.port.T = TC_1418_1421.port_a.T; AIR0CabiA002007002.port.T = TC_231_1418.port_b.T; AIR0CabiA002007002.port.T = TC_80_1418.port_b.T; AIR0CabiA002007002.port.T = TsAIR0CabiA002007002.port.T; TsAIR0CabiA012006002.port.Q_flow + (TC_1414_1417.port_b.Q_flow + (TC_1323_1417.port_b.Q_flow + (TC_756_1417.port_b.Q_flow + (TC_230_1417.port_b.Q_flow + (TC_77_1417.port_b.Q_flow + (AIR0CabiA012006002.port.Q_flow + TC_1417_1420.port_a.Q_flow)))))) = 0.0; AIR0CabiA012006002.port.T = TC_1323_1417.port_b.T; AIR0CabiA012006002.port.T = TC_1414_1417.port_b.T; AIR0CabiA012006002.port.T = TC_1417_1420.port_a.T; AIR0CabiA012006002.port.T = TC_230_1417.port_b.T; AIR0CabiA012006002.port.T = TC_756_1417.port_b.T; AIR0CabiA012006002.port.T = TC_77_1417.port_b.T; AIR0CabiA012006002.port.T = TsAIR0CabiA012006002.port.T; TsAIR0CabiA003006002.port.Q_flow + (TC_1415_1416.port_b.Q_flow + (TC_1314_1416.port_b.Q_flow + (TC_749_1416.port_b.Q_flow + (TC_68_1416.port_b.Q_flow + (AIR0CabiA003006002.port.Q_flow + (TC_1416_1419.port_a.Q_flow + TC_1416_1465.port_a.Q_flow)))))) = 0.0; AIR0CabiA003006002.port.T = TC_1314_1416.port_b.T; AIR0CabiA003006002.port.T = TC_1415_1416.port_b.T; AIR0CabiA003006002.port.T = TC_1416_1419.port_a.T; AIR0CabiA003006002.port.T = TC_1416_1465.port_a.T; AIR0CabiA003006002.port.T = TC_68_1416.port_b.T; AIR0CabiA003006002.port.T = TC_749_1416.port_b.T; AIR0CabiA003006002.port.T = TsAIR0CabiA003006002.port.T; TsAIR0CabiA002006002.port.Q_flow + (TC_1313_1415.port_b.Q_flow + (TC_229_1415.port_b.Q_flow + (TC_67_1415.port_b.Q_flow + (AIR0CabiA002006002.port.Q_flow + (TC_1415_1416.port_a.Q_flow + (TC_1415_1418.port_a.Q_flow + TC_1415_1464.port_a.Q_flow)))))) = 0.0; AIR0CabiA002006002.port.T = TC_1313_1415.port_b.T; AIR0CabiA002006002.port.T = TC_1415_1416.port_a.T; AIR0CabiA002006002.port.T = TC_1415_1418.port_a.T; AIR0CabiA002006002.port.T = TC_1415_1464.port_a.T; AIR0CabiA002006002.port.T = TC_229_1415.port_b.T; AIR0CabiA002006002.port.T = TC_67_1415.port_b.T; AIR0CabiA002006002.port.T = TsAIR0CabiA002006002.port.T; TsAIR0CabiA012005002.port.Q_flow + (TC_1312_1414.port_b.Q_flow + (TC_748_1414.port_b.Q_flow + (TC_228_1414.port_b.Q_flow + (TC_64_1414.port_b.Q_flow + (AIR0CabiA012005002.port.Q_flow + (TC_1414_1417.port_a.Q_flow + TC_1414_1463.port_a.Q_flow)))))) = 0.0; AIR0CabiA012005002.port.T = TC_1312_1414.port_b.T; AIR0CabiA012005002.port.T = TC_1414_1417.port_a.T; AIR0CabiA012005002.port.T = TC_1414_1463.port_a.T; AIR0CabiA012005002.port.T = TC_228_1414.port_b.T; AIR0CabiA012005002.port.T = TC_64_1414.port_b.T; AIR0CabiA012005002.port.T = TC_748_1414.port_b.T; AIR0CabiA012005002.port.T = TsAIR0CabiA012005002.port.T; TsAIR0CabiA012015003.port.Q_flow + (TC_1412_1413.port_b.Q_flow + (TC_1402_1413.port_b.Q_flow + (TC_1268_1413.port_b.Q_flow + (TC_422_1413.port_b.Q_flow + (TC_410_1413.port_b.Q_flow + (AIR0CabiA012015003.port.Q_flow + TC_1413_1460.port_a.Q_flow)))))) = 0.0; AIR0CabiA012015003.port.T = TC_1268_1413.port_b.T; AIR0CabiA012015003.port.T = TC_1402_1413.port_b.T; AIR0CabiA012015003.port.T = TC_1412_1413.port_b.T; AIR0CabiA012015003.port.T = TC_1413_1460.port_a.T; AIR0CabiA012015003.port.T = TC_410_1413.port_b.T; AIR0CabiA012015003.port.T = TC_422_1413.port_b.T; AIR0CabiA012015003.port.T = TsAIR0CabiA012015003.port.T; TsAIR0CabiA011015003.port.Q_flow + (TC_1411_1412.port_b.Q_flow + (TC_1401_1412.port_b.Q_flow + (TC_1267_1412.port_b.Q_flow + (TC_421_1412.port_b.Q_flow + (AIR0CabiA011015003.port.Q_flow + (TC_1412_1413.port_a.Q_flow + TC_1412_1459.port_a.Q_flow)))))) = 0.0; AIR0CabiA011015003.port.T = TC_1267_1412.port_b.T; AIR0CabiA011015003.port.T = TC_1401_1412.port_b.T; AIR0CabiA011015003.port.T = TC_1411_1412.port_b.T; AIR0CabiA011015003.port.T = TC_1412_1413.port_a.T; AIR0CabiA011015003.port.T = TC_1412_1459.port_a.T; AIR0CabiA011015003.port.T = TC_421_1412.port_b.T; AIR0CabiA011015003.port.T = TsAIR0CabiA011015003.port.T; TsAIR0CabiA010015003.port.Q_flow + (TC_1410_1411.port_b.Q_flow + (TC_1400_1411.port_b.Q_flow + (TC_1266_1411.port_b.Q_flow + (TC_420_1411.port_b.Q_flow + (AIR0CabiA010015003.port.Q_flow + (TC_1411_1412.port_a.Q_flow + TC_1411_1458.port_a.Q_flow)))))) = 0.0; AIR0CabiA010015003.port.T = TC_1266_1411.port_b.T; AIR0CabiA010015003.port.T = TC_1400_1411.port_b.T; AIR0CabiA010015003.port.T = TC_1410_1411.port_b.T; AIR0CabiA010015003.port.T = TC_1411_1412.port_a.T; AIR0CabiA010015003.port.T = TC_1411_1458.port_a.T; AIR0CabiA010015003.port.T = TC_420_1411.port_b.T; AIR0CabiA010015003.port.T = TsAIR0CabiA010015003.port.T; TsAIR0CabiA009015003.port.Q_flow + (TC_1409_1410.port_b.Q_flow + (TC_1399_1410.port_b.Q_flow + (TC_1265_1410.port_b.Q_flow + (TC_419_1410.port_b.Q_flow + (AIR0CabiA009015003.port.Q_flow + (TC_1410_1411.port_a.Q_flow + TC_1410_1457.port_a.Q_flow)))))) = 0.0; AIR0CabiA009015003.port.T = TC_1265_1410.port_b.T; AIR0CabiA009015003.port.T = TC_1399_1410.port_b.T; AIR0CabiA009015003.port.T = TC_1409_1410.port_b.T; AIR0CabiA009015003.port.T = TC_1410_1411.port_a.T; AIR0CabiA009015003.port.T = TC_1410_1457.port_a.T; AIR0CabiA009015003.port.T = TC_419_1410.port_b.T; AIR0CabiA009015003.port.T = TsAIR0CabiA009015003.port.T; TsAIR0CabiA008015003.port.Q_flow + (TC_1408_1409.port_b.Q_flow + (TC_1398_1409.port_b.Q_flow + (TC_1264_1409.port_b.Q_flow + (TC_418_1409.port_b.Q_flow + (AIR0CabiA008015003.port.Q_flow + (TC_1409_1410.port_a.Q_flow + TC_1409_1456.port_a.Q_flow)))))) = 0.0; AIR0CabiA008015003.port.T = TC_1264_1409.port_b.T; AIR0CabiA008015003.port.T = TC_1398_1409.port_b.T; AIR0CabiA008015003.port.T = TC_1408_1409.port_b.T; AIR0CabiA008015003.port.T = TC_1409_1410.port_a.T; AIR0CabiA008015003.port.T = TC_1409_1456.port_a.T; AIR0CabiA008015003.port.T = TC_418_1409.port_b.T; AIR0CabiA008015003.port.T = TsAIR0CabiA008015003.port.T; TsAIR0CabiA007015003.port.Q_flow + (TC_1407_1408.port_b.Q_flow + (TC_1397_1408.port_b.Q_flow + (TC_1263_1408.port_b.Q_flow + (TC_417_1408.port_b.Q_flow + (AIR0CabiA007015003.port.Q_flow + (TC_1408_1409.port_a.Q_flow + TC_1408_1455.port_a.Q_flow)))))) = 0.0; AIR0CabiA007015003.port.T = TC_1263_1408.port_b.T; AIR0CabiA007015003.port.T = TC_1397_1408.port_b.T; AIR0CabiA007015003.port.T = TC_1407_1408.port_b.T; AIR0CabiA007015003.port.T = TC_1408_1409.port_a.T; AIR0CabiA007015003.port.T = TC_1408_1455.port_a.T; AIR0CabiA007015003.port.T = TC_417_1408.port_b.T; AIR0CabiA007015003.port.T = TsAIR0CabiA007015003.port.T; TsAIR0CabiA006015003.port.Q_flow + (TC_1406_1407.port_b.Q_flow + (TC_1396_1407.port_b.Q_flow + (TC_1262_1407.port_b.Q_flow + (TC_416_1407.port_b.Q_flow + (AIR0CabiA006015003.port.Q_flow + (TC_1407_1408.port_a.Q_flow + TC_1407_1454.port_a.Q_flow)))))) = 0.0; AIR0CabiA006015003.port.T = TC_1262_1407.port_b.T; AIR0CabiA006015003.port.T = TC_1396_1407.port_b.T; AIR0CabiA006015003.port.T = TC_1406_1407.port_b.T; AIR0CabiA006015003.port.T = TC_1407_1408.port_a.T; AIR0CabiA006015003.port.T = TC_1407_1454.port_a.T; AIR0CabiA006015003.port.T = TC_416_1407.port_b.T; AIR0CabiA006015003.port.T = TsAIR0CabiA006015003.port.T; TsAIR0CabiA005015003.port.Q_flow + (TC_1405_1406.port_b.Q_flow + (TC_1395_1406.port_b.Q_flow + (TC_1261_1406.port_b.Q_flow + (TC_415_1406.port_b.Q_flow + (AIR0CabiA005015003.port.Q_flow + (TC_1406_1407.port_a.Q_flow + TC_1406_1453.port_a.Q_flow)))))) = 0.0; AIR0CabiA005015003.port.T = TC_1261_1406.port_b.T; AIR0CabiA005015003.port.T = TC_1395_1406.port_b.T; AIR0CabiA005015003.port.T = TC_1405_1406.port_b.T; AIR0CabiA005015003.port.T = TC_1406_1407.port_a.T; AIR0CabiA005015003.port.T = TC_1406_1453.port_a.T; AIR0CabiA005015003.port.T = TC_415_1406.port_b.T; AIR0CabiA005015003.port.T = TsAIR0CabiA005015003.port.T; TsAIR0CabiA004015003.port.Q_flow + (TC_1404_1405.port_b.Q_flow + (TC_1394_1405.port_b.Q_flow + (TC_1260_1405.port_b.Q_flow + (TC_414_1405.port_b.Q_flow + (AIR0CabiA004015003.port.Q_flow + (TC_1405_1406.port_a.Q_flow + TC_1405_1452.port_a.Q_flow)))))) = 0.0; AIR0CabiA004015003.port.T = TC_1260_1405.port_b.T; AIR0CabiA004015003.port.T = TC_1394_1405.port_b.T; AIR0CabiA004015003.port.T = TC_1404_1405.port_b.T; AIR0CabiA004015003.port.T = TC_1405_1406.port_a.T; AIR0CabiA004015003.port.T = TC_1405_1452.port_a.T; AIR0CabiA004015003.port.T = TC_414_1405.port_b.T; AIR0CabiA004015003.port.T = TsAIR0CabiA004015003.port.T; TsAIR0CabiA003015003.port.Q_flow + (TC_1403_1404.port_b.Q_flow + (TC_1393_1404.port_b.Q_flow + (TC_1259_1404.port_b.Q_flow + (TC_413_1404.port_b.Q_flow + (AIR0CabiA003015003.port.Q_flow + (TC_1404_1405.port_a.Q_flow + TC_1404_1451.port_a.Q_flow)))))) = 0.0; AIR0CabiA003015003.port.T = TC_1259_1404.port_b.T; AIR0CabiA003015003.port.T = TC_1393_1404.port_b.T; AIR0CabiA003015003.port.T = TC_1403_1404.port_b.T; AIR0CabiA003015003.port.T = TC_1404_1405.port_a.T; AIR0CabiA003015003.port.T = TC_1404_1451.port_a.T; AIR0CabiA003015003.port.T = TC_413_1404.port_b.T; AIR0CabiA003015003.port.T = TsAIR0CabiA003015003.port.T; TsAIR0CabiA002015003.port.Q_flow + (TC_1392_1403.port_b.Q_flow + (TC_1258_1403.port_b.Q_flow + (TC_412_1403.port_b.Q_flow + (TC_409_1403.port_b.Q_flow + (AIR0CabiA002015003.port.Q_flow + (TC_1403_1404.port_a.Q_flow + TC_1403_1450.port_a.Q_flow)))))) = 0.0; AIR0CabiA002015003.port.T = TC_1258_1403.port_b.T; AIR0CabiA002015003.port.T = TC_1392_1403.port_b.T; AIR0CabiA002015003.port.T = TC_1403_1404.port_a.T; AIR0CabiA002015003.port.T = TC_1403_1450.port_a.T; AIR0CabiA002015003.port.T = TC_409_1403.port_b.T; AIR0CabiA002015003.port.T = TC_412_1403.port_b.T; AIR0CabiA002015003.port.T = TsAIR0CabiA002015003.port.T; TsAIR0CabiA012014003.port.Q_flow + (TC_1401_1402.port_b.Q_flow + (TC_1391_1402.port_b.Q_flow + (TC_1257_1402.port_b.Q_flow + (TC_408_1402.port_b.Q_flow + (AIR0CabiA012014003.port.Q_flow + (TC_1402_1413.port_a.Q_flow + TC_1402_1449.port_a.Q_flow)))))) = 0.0; AIR0CabiA012014003.port.T = TC_1257_1402.port_b.T; AIR0CabiA012014003.port.T = TC_1391_1402.port_b.T; AIR0CabiA012014003.port.T = TC_1401_1402.port_b.T; AIR0CabiA012014003.port.T = TC_1402_1413.port_a.T; AIR0CabiA012014003.port.T = TC_1402_1449.port_a.T; AIR0CabiA012014003.port.T = TC_408_1402.port_b.T; AIR0CabiA012014003.port.T = TsAIR0CabiA012014003.port.T; TsAIR0CabiA011014003.port.Q_flow + (TC_1400_1401.port_b.Q_flow + (TC_1390_1401.port_b.Q_flow + (TC_1256_1401.port_b.Q_flow + (AIR0CabiA011014003.port.Q_flow + (TC_1401_1402.port_a.Q_flow + (TC_1401_1412.port_a.Q_flow + TC_1401_1448.port_a.Q_flow)))))) = 0.0; AIR0CabiA011014003.port.T = TC_1256_1401.port_b.T; AIR0CabiA011014003.port.T = TC_1390_1401.port_b.T; AIR0CabiA011014003.port.T = TC_1400_1401.port_b.T; AIR0CabiA011014003.port.T = TC_1401_1402.port_a.T; AIR0CabiA011014003.port.T = TC_1401_1412.port_a.T; AIR0CabiA011014003.port.T = TC_1401_1448.port_a.T; AIR0CabiA011014003.port.T = TsAIR0CabiA011014003.port.T; TsAIR0CabiA010014003.port.Q_flow + (TC_1399_1400.port_b.Q_flow + (TC_1389_1400.port_b.Q_flow + (TC_1255_1400.port_b.Q_flow + (AIR0CabiA010014003.port.Q_flow + (TC_1400_1401.port_a.Q_flow + (TC_1400_1411.port_a.Q_flow + TC_1400_1447.port_a.Q_flow)))))) = 0.0; AIR0CabiA010014003.port.T = TC_1255_1400.port_b.T; AIR0CabiA010014003.port.T = TC_1389_1400.port_b.T; AIR0CabiA010014003.port.T = TC_1399_1400.port_b.T; AIR0CabiA010014003.port.T = TC_1400_1401.port_a.T; AIR0CabiA010014003.port.T = TC_1400_1411.port_a.T; AIR0CabiA010014003.port.T = TC_1400_1447.port_a.T; AIR0CabiA010014003.port.T = TsAIR0CabiA010014003.port.T; TsAIR0CabiA009014003.port.Q_flow + (TC_1398_1399.port_b.Q_flow + (TC_1388_1399.port_b.Q_flow + (TC_1254_1399.port_b.Q_flow + (AIR0CabiA009014003.port.Q_flow + (TC_1399_1400.port_a.Q_flow + (TC_1399_1410.port_a.Q_flow + TC_1399_1446.port_a.Q_flow)))))) = 0.0; AIR0CabiA009014003.port.T = TC_1254_1399.port_b.T; AIR0CabiA009014003.port.T = TC_1388_1399.port_b.T; AIR0CabiA009014003.port.T = TC_1398_1399.port_b.T; AIR0CabiA009014003.port.T = TC_1399_1400.port_a.T; AIR0CabiA009014003.port.T = TC_1399_1410.port_a.T; AIR0CabiA009014003.port.T = TC_1399_1446.port_a.T; AIR0CabiA009014003.port.T = TsAIR0CabiA009014003.port.T; TsAIR0CabiA008014003.port.Q_flow + (TC_1397_1398.port_b.Q_flow + (TC_1387_1398.port_b.Q_flow + (TC_1253_1398.port_b.Q_flow + (AIR0CabiA008014003.port.Q_flow + (TC_1398_1399.port_a.Q_flow + (TC_1398_1409.port_a.Q_flow + TC_1398_1445.port_a.Q_flow)))))) = 0.0; AIR0CabiA008014003.port.T = TC_1253_1398.port_b.T; AIR0CabiA008014003.port.T = TC_1387_1398.port_b.T; AIR0CabiA008014003.port.T = TC_1397_1398.port_b.T; AIR0CabiA008014003.port.T = TC_1398_1399.port_a.T; AIR0CabiA008014003.port.T = TC_1398_1409.port_a.T; AIR0CabiA008014003.port.T = TC_1398_1445.port_a.T; AIR0CabiA008014003.port.T = TsAIR0CabiA008014003.port.T; TsAIR0CabiA007014003.port.Q_flow + (TC_1396_1397.port_b.Q_flow + (TC_1386_1397.port_b.Q_flow + (TC_1252_1397.port_b.Q_flow + (AIR0CabiA007014003.port.Q_flow + (TC_1397_1398.port_a.Q_flow + (TC_1397_1408.port_a.Q_flow + TC_1397_1444.port_a.Q_flow)))))) = 0.0; AIR0CabiA007014003.port.T = TC_1252_1397.port_b.T; AIR0CabiA007014003.port.T = TC_1386_1397.port_b.T; AIR0CabiA007014003.port.T = TC_1396_1397.port_b.T; AIR0CabiA007014003.port.T = TC_1397_1398.port_a.T; AIR0CabiA007014003.port.T = TC_1397_1408.port_a.T; AIR0CabiA007014003.port.T = TC_1397_1444.port_a.T; AIR0CabiA007014003.port.T = TsAIR0CabiA007014003.port.T; TsAIR0CabiA006014003.port.Q_flow + (TC_1395_1396.port_b.Q_flow + (TC_1385_1396.port_b.Q_flow + (TC_1251_1396.port_b.Q_flow + (AIR0CabiA006014003.port.Q_flow + (TC_1396_1397.port_a.Q_flow + (TC_1396_1407.port_a.Q_flow + TC_1396_1443.port_a.Q_flow)))))) = 0.0; AIR0CabiA006014003.port.T = TC_1251_1396.port_b.T; AIR0CabiA006014003.port.T = TC_1385_1396.port_b.T; AIR0CabiA006014003.port.T = TC_1395_1396.port_b.T; AIR0CabiA006014003.port.T = TC_1396_1397.port_a.T; AIR0CabiA006014003.port.T = TC_1396_1407.port_a.T; AIR0CabiA006014003.port.T = TC_1396_1443.port_a.T; AIR0CabiA006014003.port.T = TsAIR0CabiA006014003.port.T; TsAIR0CabiA005014003.port.Q_flow + (TC_1394_1395.port_b.Q_flow + (TC_1384_1395.port_b.Q_flow + (TC_1250_1395.port_b.Q_flow + (AIR0CabiA005014003.port.Q_flow + (TC_1395_1396.port_a.Q_flow + (TC_1395_1406.port_a.Q_flow + TC_1395_1442.port_a.Q_flow)))))) = 0.0; AIR0CabiA005014003.port.T = TC_1250_1395.port_b.T; AIR0CabiA005014003.port.T = TC_1384_1395.port_b.T; AIR0CabiA005014003.port.T = TC_1394_1395.port_b.T; AIR0CabiA005014003.port.T = TC_1395_1396.port_a.T; AIR0CabiA005014003.port.T = TC_1395_1406.port_a.T; AIR0CabiA005014003.port.T = TC_1395_1442.port_a.T; AIR0CabiA005014003.port.T = TsAIR0CabiA005014003.port.T; TsAIR0CabiA004014003.port.Q_flow + (TC_1393_1394.port_b.Q_flow + (TC_1383_1394.port_b.Q_flow + (TC_1249_1394.port_b.Q_flow + (AIR0CabiA004014003.port.Q_flow + (TC_1394_1395.port_a.Q_flow + (TC_1394_1405.port_a.Q_flow + TC_1394_1441.port_a.Q_flow)))))) = 0.0; AIR0CabiA004014003.port.T = TC_1249_1394.port_b.T; AIR0CabiA004014003.port.T = TC_1383_1394.port_b.T; AIR0CabiA004014003.port.T = TC_1393_1394.port_b.T; AIR0CabiA004014003.port.T = TC_1394_1395.port_a.T; AIR0CabiA004014003.port.T = TC_1394_1405.port_a.T; AIR0CabiA004014003.port.T = TC_1394_1441.port_a.T; AIR0CabiA004014003.port.T = TsAIR0CabiA004014003.port.T; TsAIR0CabiA003014003.port.Q_flow + (TC_1392_1393.port_b.Q_flow + (TC_1382_1393.port_b.Q_flow + (TC_1248_1393.port_b.Q_flow + (AIR0CabiA003014003.port.Q_flow + (TC_1393_1394.port_a.Q_flow + (TC_1393_1404.port_a.Q_flow + TC_1393_1440.port_a.Q_flow)))))) = 0.0; AIR0CabiA003014003.port.T = TC_1248_1393.port_b.T; AIR0CabiA003014003.port.T = TC_1382_1393.port_b.T; AIR0CabiA003014003.port.T = TC_1392_1393.port_b.T; AIR0CabiA003014003.port.T = TC_1393_1394.port_a.T; AIR0CabiA003014003.port.T = TC_1393_1404.port_a.T; AIR0CabiA003014003.port.T = TC_1393_1440.port_a.T; AIR0CabiA003014003.port.T = TsAIR0CabiA003014003.port.T; TsAIR0CabiA002014003.port.Q_flow + (TC_1381_1392.port_b.Q_flow + (TC_1247_1392.port_b.Q_flow + (TC_407_1392.port_b.Q_flow + (AIR0CabiA002014003.port.Q_flow + (TC_1392_1393.port_a.Q_flow + (TC_1392_1403.port_a.Q_flow + TC_1392_1439.port_a.Q_flow)))))) = 0.0; AIR0CabiA002014003.port.T = TC_1247_1392.port_b.T; AIR0CabiA002014003.port.T = TC_1381_1392.port_b.T; AIR0CabiA002014003.port.T = TC_1392_1393.port_a.T; AIR0CabiA002014003.port.T = TC_1392_1403.port_a.T; AIR0CabiA002014003.port.T = TC_1392_1439.port_a.T; AIR0CabiA002014003.port.T = TC_407_1392.port_b.T; AIR0CabiA002014003.port.T = TsAIR0CabiA002014003.port.T; TsAIR0CabiA012013003.port.Q_flow + (TC_1390_1391.port_b.Q_flow + (TC_1380_1391.port_b.Q_flow + (TC_1246_1391.port_b.Q_flow + (TC_406_1391.port_b.Q_flow + (AIR0CabiA012013003.port.Q_flow + (TC_1391_1402.port_a.Q_flow + TC_1391_1438.port_a.Q_flow)))))) = 0.0; AIR0CabiA012013003.port.T = TC_1246_1391.port_b.T; AIR0CabiA012013003.port.T = TC_1380_1391.port_b.T; AIR0CabiA012013003.port.T = TC_1390_1391.port_b.T; AIR0CabiA012013003.port.T = TC_1391_1402.port_a.T; AIR0CabiA012013003.port.T = TC_1391_1438.port_a.T; AIR0CabiA012013003.port.T = TC_406_1391.port_b.T; AIR0CabiA012013003.port.T = TsAIR0CabiA012013003.port.T; TsAIR0CabiA011013003.port.Q_flow + (TC_1389_1390.port_b.Q_flow + (TC_1379_1390.port_b.Q_flow + (TC_1245_1390.port_b.Q_flow + (TC_812_1390.port_b.Q_flow + (AIR0CabiA011013003.port.Q_flow + (TC_1390_1391.port_a.Q_flow + TC_1390_1401.port_a.Q_flow)))))) = 0.0; AIR0CabiA011013003.port.T = TC_1245_1390.port_b.T; AIR0CabiA011013003.port.T = TC_1379_1390.port_b.T; AIR0CabiA011013003.port.T = TC_1389_1390.port_b.T; AIR0CabiA011013003.port.T = TC_1390_1391.port_a.T; AIR0CabiA011013003.port.T = TC_1390_1401.port_a.T; AIR0CabiA011013003.port.T = TC_812_1390.port_b.T; AIR0CabiA011013003.port.T = TsAIR0CabiA011013003.port.T; TsAIR0CabiA010013003.port.Q_flow + (TC_1388_1389.port_b.Q_flow + (TC_1378_1389.port_b.Q_flow + (TC_1244_1389.port_b.Q_flow + (TC_811_1389.port_b.Q_flow + (AIR0CabiA010013003.port.Q_flow + (TC_1389_1390.port_a.Q_flow + TC_1389_1400.port_a.Q_flow)))))) = 0.0; AIR0CabiA010013003.port.T = TC_1244_1389.port_b.T; AIR0CabiA010013003.port.T = TC_1378_1389.port_b.T; AIR0CabiA010013003.port.T = TC_1388_1389.port_b.T; AIR0CabiA010013003.port.T = TC_1389_1390.port_a.T; AIR0CabiA010013003.port.T = TC_1389_1400.port_a.T; AIR0CabiA010013003.port.T = TC_811_1389.port_b.T; AIR0CabiA010013003.port.T = TsAIR0CabiA010013003.port.T; TsAIR0CabiA009013003.port.Q_flow + (TC_1387_1388.port_b.Q_flow + (TC_1377_1388.port_b.Q_flow + (TC_1243_1388.port_b.Q_flow + (TC_810_1388.port_b.Q_flow + (AIR0CabiA009013003.port.Q_flow + (TC_1388_1389.port_a.Q_flow + TC_1388_1399.port_a.Q_flow)))))) = 0.0; AIR0CabiA009013003.port.T = TC_1243_1388.port_b.T; AIR0CabiA009013003.port.T = TC_1377_1388.port_b.T; AIR0CabiA009013003.port.T = TC_1387_1388.port_b.T; AIR0CabiA009013003.port.T = TC_1388_1389.port_a.T; AIR0CabiA009013003.port.T = TC_1388_1399.port_a.T; AIR0CabiA009013003.port.T = TC_810_1388.port_b.T; AIR0CabiA009013003.port.T = TsAIR0CabiA009013003.port.T; TsAIR0CabiA008013003.port.Q_flow + (TC_1386_1387.port_b.Q_flow + (TC_1376_1387.port_b.Q_flow + (TC_1242_1387.port_b.Q_flow + (TC_809_1387.port_b.Q_flow + (AIR0CabiA008013003.port.Q_flow + (TC_1387_1388.port_a.Q_flow + TC_1387_1398.port_a.Q_flow)))))) = 0.0; AIR0CabiA008013003.port.T = TC_1242_1387.port_b.T; AIR0CabiA008013003.port.T = TC_1376_1387.port_b.T; AIR0CabiA008013003.port.T = TC_1386_1387.port_b.T; AIR0CabiA008013003.port.T = TC_1387_1388.port_a.T; AIR0CabiA008013003.port.T = TC_1387_1398.port_a.T; AIR0CabiA008013003.port.T = TC_809_1387.port_b.T; AIR0CabiA008013003.port.T = TsAIR0CabiA008013003.port.T; TsAIR0CabiA007013003.port.Q_flow + (TC_1385_1386.port_b.Q_flow + (TC_1375_1386.port_b.Q_flow + (TC_1241_1386.port_b.Q_flow + (TC_808_1386.port_b.Q_flow + (AIR0CabiA007013003.port.Q_flow + (TC_1386_1387.port_a.Q_flow + TC_1386_1397.port_a.Q_flow)))))) = 0.0; AIR0CabiA007013003.port.T = TC_1241_1386.port_b.T; AIR0CabiA007013003.port.T = TC_1375_1386.port_b.T; AIR0CabiA007013003.port.T = TC_1385_1386.port_b.T; AIR0CabiA007013003.port.T = TC_1386_1387.port_a.T; AIR0CabiA007013003.port.T = TC_1386_1397.port_a.T; AIR0CabiA007013003.port.T = TC_808_1386.port_b.T; AIR0CabiA007013003.port.T = TsAIR0CabiA007013003.port.T; TsAIR0CabiA006013003.port.Q_flow + (TC_1384_1385.port_b.Q_flow + (TC_1374_1385.port_b.Q_flow + (TC_807_1385.port_b.Q_flow + (AIR0CabiA006013003.port.Q_flow + (TC_1385_1386.port_a.Q_flow + (TC_1385_1396.port_a.Q_flow + TC_1385_1526.port_a.Q_flow)))))) = 0.0; AIR0CabiA006013003.port.T = TC_1374_1385.port_b.T; AIR0CabiA006013003.port.T = TC_1384_1385.port_b.T; AIR0CabiA006013003.port.T = TC_1385_1386.port_a.T; AIR0CabiA006013003.port.T = TC_1385_1396.port_a.T; AIR0CabiA006013003.port.T = TC_1385_1526.port_a.T; AIR0CabiA006013003.port.T = TC_807_1385.port_b.T; AIR0CabiA006013003.port.T = TsAIR0CabiA006013003.port.T; TsAIR0CabiA005013003.port.Q_flow + (TC_1383_1384.port_b.Q_flow + (TC_1373_1384.port_b.Q_flow + (TC_806_1384.port_b.Q_flow + (AIR0CabiA005013003.port.Q_flow + (TC_1384_1385.port_a.Q_flow + (TC_1384_1395.port_a.Q_flow + TC_1384_1525.port_a.Q_flow)))))) = 0.0; AIR0CabiA005013003.port.T = TC_1373_1384.port_b.T; AIR0CabiA005013003.port.T = TC_1383_1384.port_b.T; AIR0CabiA005013003.port.T = TC_1384_1385.port_a.T; AIR0CabiA005013003.port.T = TC_1384_1395.port_a.T; AIR0CabiA005013003.port.T = TC_1384_1525.port_a.T; AIR0CabiA005013003.port.T = TC_806_1384.port_b.T; AIR0CabiA005013003.port.T = TsAIR0CabiA005013003.port.T; TsAIR0CabiA004013003.port.Q_flow + (TC_1382_1383.port_b.Q_flow + (TC_1372_1383.port_b.Q_flow + (TC_805_1383.port_b.Q_flow + (AIR0CabiA004013003.port.Q_flow + (TC_1383_1384.port_a.Q_flow + (TC_1383_1394.port_a.Q_flow + TC_1383_1524.port_a.Q_flow)))))) = 0.0; AIR0CabiA004013003.port.T = TC_1372_1383.port_b.T; AIR0CabiA004013003.port.T = TC_1382_1383.port_b.T; AIR0CabiA004013003.port.T = TC_1383_1384.port_a.T; AIR0CabiA004013003.port.T = TC_1383_1394.port_a.T; AIR0CabiA004013003.port.T = TC_1383_1524.port_a.T; AIR0CabiA004013003.port.T = TC_805_1383.port_b.T; AIR0CabiA004013003.port.T = TsAIR0CabiA004013003.port.T; TsAIR0CabiA003013003.port.Q_flow + (TC_1381_1382.port_b.Q_flow + (TC_1371_1382.port_b.Q_flow + (TC_1240_1382.port_b.Q_flow + (AIR0CabiA003013003.port.Q_flow + (TC_1382_1383.port_a.Q_flow + (TC_1382_1393.port_a.Q_flow + TC_1382_1437.port_a.Q_flow)))))) = 0.0; AIR0CabiA003013003.port.T = TC_1240_1382.port_b.T; AIR0CabiA003013003.port.T = TC_1371_1382.port_b.T; AIR0CabiA003013003.port.T = TC_1381_1382.port_b.T; AIR0CabiA003013003.port.T = TC_1382_1383.port_a.T; AIR0CabiA003013003.port.T = TC_1382_1393.port_a.T; AIR0CabiA003013003.port.T = TC_1382_1437.port_a.T; AIR0CabiA003013003.port.T = TsAIR0CabiA003013003.port.T; TsAIR0CabiA002013003.port.Q_flow + (TC_1370_1381.port_b.Q_flow + (TC_1239_1381.port_b.Q_flow + (TC_405_1381.port_b.Q_flow + (AIR0CabiA002013003.port.Q_flow + (TC_1381_1382.port_a.Q_flow + (TC_1381_1392.port_a.Q_flow + TC_1381_1436.port_a.Q_flow)))))) = 0.0; AIR0CabiA002013003.port.T = TC_1239_1381.port_b.T; AIR0CabiA002013003.port.T = TC_1370_1381.port_b.T; AIR0CabiA002013003.port.T = TC_1381_1382.port_a.T; AIR0CabiA002013003.port.T = TC_1381_1392.port_a.T; AIR0CabiA002013003.port.T = TC_1381_1436.port_a.T; AIR0CabiA002013003.port.T = TC_405_1381.port_b.T; AIR0CabiA002013003.port.T = TsAIR0CabiA002013003.port.T; TsAIR0CabiA012012003.port.Q_flow + (TC_1379_1380.port_b.Q_flow + (TC_1369_1380.port_b.Q_flow + (TC_1238_1380.port_b.Q_flow + (TC_404_1380.port_b.Q_flow + (AIR0CabiA012012003.port.Q_flow + (TC_1380_1391.port_a.Q_flow + TC_1380_1435.port_a.Q_flow)))))) = 0.0; AIR0CabiA012012003.port.T = TC_1238_1380.port_b.T; AIR0CabiA012012003.port.T = TC_1369_1380.port_b.T; AIR0CabiA012012003.port.T = TC_1379_1380.port_b.T; AIR0CabiA012012003.port.T = TC_1380_1391.port_a.T; AIR0CabiA012012003.port.T = TC_1380_1435.port_a.T; AIR0CabiA012012003.port.T = TC_404_1380.port_b.T; AIR0CabiA012012003.port.T = TsAIR0CabiA012012003.port.T; TsAIR0CabiA011012003.port.Q_flow + (TC_1378_1379.port_b.Q_flow + (TC_1368_1379.port_b.Q_flow + (TC_1237_1379.port_b.Q_flow + (TC_804_1379.port_b.Q_flow + (AIR0CabiA011012003.port.Q_flow + (TC_1379_1380.port_a.Q_flow + TC_1379_1390.port_a.Q_flow)))))) = 0.0; AIR0CabiA011012003.port.T = TC_1237_1379.port_b.T; AIR0CabiA011012003.port.T = TC_1368_1379.port_b.T; AIR0CabiA011012003.port.T = TC_1378_1379.port_b.T; AIR0CabiA011012003.port.T = TC_1379_1380.port_a.T; AIR0CabiA011012003.port.T = TC_1379_1390.port_a.T; AIR0CabiA011012003.port.T = TC_804_1379.port_b.T; AIR0CabiA011012003.port.T = TsAIR0CabiA011012003.port.T; TsAIR0CabiA010012003.port.Q_flow + (TC_1377_1378.port_b.Q_flow + (TC_1367_1378.port_b.Q_flow + (TC_1236_1378.port_b.Q_flow + (TC_803_1378.port_b.Q_flow + (AIR0CabiA010012003.port.Q_flow + (TC_1378_1379.port_a.Q_flow + TC_1378_1389.port_a.Q_flow)))))) = 0.0; AIR0CabiA010012003.port.T = TC_1236_1378.port_b.T; AIR0CabiA010012003.port.T = TC_1367_1378.port_b.T; AIR0CabiA010012003.port.T = TC_1377_1378.port_b.T; AIR0CabiA010012003.port.T = TC_1378_1379.port_a.T; AIR0CabiA010012003.port.T = TC_1378_1389.port_a.T; AIR0CabiA010012003.port.T = TC_803_1378.port_b.T; AIR0CabiA010012003.port.T = TsAIR0CabiA010012003.port.T; TsAIR0CabiA009012003.port.Q_flow + (TC_1376_1377.port_b.Q_flow + (TC_1366_1377.port_b.Q_flow + (TC_1235_1377.port_b.Q_flow + (TC_802_1377.port_b.Q_flow + (AIR0CabiA009012003.port.Q_flow + (TC_1377_1378.port_a.Q_flow + TC_1377_1388.port_a.Q_flow)))))) = 0.0; AIR0CabiA009012003.port.T = TC_1235_1377.port_b.T; AIR0CabiA009012003.port.T = TC_1366_1377.port_b.T; AIR0CabiA009012003.port.T = TC_1376_1377.port_b.T; AIR0CabiA009012003.port.T = TC_1377_1378.port_a.T; AIR0CabiA009012003.port.T = TC_1377_1388.port_a.T; AIR0CabiA009012003.port.T = TC_802_1377.port_b.T; AIR0CabiA009012003.port.T = TsAIR0CabiA009012003.port.T; TsAIR0CabiA008012003.port.Q_flow + (TC_1375_1376.port_b.Q_flow + (TC_1365_1376.port_b.Q_flow + (TC_1234_1376.port_b.Q_flow + (TC_801_1376.port_b.Q_flow + (AIR0CabiA008012003.port.Q_flow + (TC_1376_1377.port_a.Q_flow + TC_1376_1387.port_a.Q_flow)))))) = 0.0; AIR0CabiA008012003.port.T = TC_1234_1376.port_b.T; AIR0CabiA008012003.port.T = TC_1365_1376.port_b.T; AIR0CabiA008012003.port.T = TC_1375_1376.port_b.T; AIR0CabiA008012003.port.T = TC_1376_1377.port_a.T; AIR0CabiA008012003.port.T = TC_1376_1387.port_a.T; AIR0CabiA008012003.port.T = TC_801_1376.port_b.T; AIR0CabiA008012003.port.T = TsAIR0CabiA008012003.port.T; TsAIR0CabiA007012003.port.Q_flow + (TC_1374_1375.port_b.Q_flow + (TC_1364_1375.port_b.Q_flow + (TC_1233_1375.port_b.Q_flow + (TC_800_1375.port_b.Q_flow + (AIR0CabiA007012003.port.Q_flow + (TC_1375_1376.port_a.Q_flow + TC_1375_1386.port_a.Q_flow)))))) = 0.0; AIR0CabiA007012003.port.T = TC_1233_1375.port_b.T; AIR0CabiA007012003.port.T = TC_1364_1375.port_b.T; AIR0CabiA007012003.port.T = TC_1374_1375.port_b.T; AIR0CabiA007012003.port.T = TC_1375_1376.port_a.T; AIR0CabiA007012003.port.T = TC_1375_1386.port_a.T; AIR0CabiA007012003.port.T = TC_800_1375.port_b.T; AIR0CabiA007012003.port.T = TsAIR0CabiA007012003.port.T; TsAIR0CabiA006012003.port.Q_flow + (TC_1373_1374.port_b.Q_flow + (TC_1363_1374.port_b.Q_flow + (TC_799_1374.port_b.Q_flow + (AIR0CabiA006012003.port.Q_flow + (TC_1374_1375.port_a.Q_flow + (TC_1374_1385.port_a.Q_flow + TC_1374_1523.port_a.Q_flow)))))) = 0.0; AIR0CabiA006012003.port.T = TC_1363_1374.port_b.T; AIR0CabiA006012003.port.T = TC_1373_1374.port_b.T; AIR0CabiA006012003.port.T = TC_1374_1375.port_a.T; AIR0CabiA006012003.port.T = TC_1374_1385.port_a.T; AIR0CabiA006012003.port.T = TC_1374_1523.port_a.T; AIR0CabiA006012003.port.T = TC_799_1374.port_b.T; AIR0CabiA006012003.port.T = TsAIR0CabiA006012003.port.T; TsAIR0CabiA005012003.port.Q_flow + (TC_1372_1373.port_b.Q_flow + (TC_1362_1373.port_b.Q_flow + (TC_798_1373.port_b.Q_flow + (AIR0CabiA005012003.port.Q_flow + (TC_1373_1374.port_a.Q_flow + (TC_1373_1384.port_a.Q_flow + TC_1373_1522.port_a.Q_flow)))))) = 0.0; AIR0CabiA005012003.port.T = TC_1362_1373.port_b.T; AIR0CabiA005012003.port.T = TC_1372_1373.port_b.T; AIR0CabiA005012003.port.T = TC_1373_1374.port_a.T; AIR0CabiA005012003.port.T = TC_1373_1384.port_a.T; AIR0CabiA005012003.port.T = TC_1373_1522.port_a.T; AIR0CabiA005012003.port.T = TC_798_1373.port_b.T; AIR0CabiA005012003.port.T = TsAIR0CabiA005012003.port.T; TsAIR0CabiA004012003.port.Q_flow + (TC_1371_1372.port_b.Q_flow + (TC_1361_1372.port_b.Q_flow + (TC_797_1372.port_b.Q_flow + (AIR0CabiA004012003.port.Q_flow + (TC_1372_1373.port_a.Q_flow + (TC_1372_1383.port_a.Q_flow + TC_1372_1521.port_a.Q_flow)))))) = 0.0; AIR0CabiA004012003.port.T = TC_1361_1372.port_b.T; AIR0CabiA004012003.port.T = TC_1371_1372.port_b.T; AIR0CabiA004012003.port.T = TC_1372_1373.port_a.T; AIR0CabiA004012003.port.T = TC_1372_1383.port_a.T; AIR0CabiA004012003.port.T = TC_1372_1521.port_a.T; AIR0CabiA004012003.port.T = TC_797_1372.port_b.T; AIR0CabiA004012003.port.T = TsAIR0CabiA004012003.port.T; TsAIR0CabiA003012003.port.Q_flow + (TC_1370_1371.port_b.Q_flow + (TC_1360_1371.port_b.Q_flow + (TC_1232_1371.port_b.Q_flow + (AIR0CabiA003012003.port.Q_flow + (TC_1371_1372.port_a.Q_flow + (TC_1371_1382.port_a.Q_flow + TC_1371_1434.port_a.Q_flow)))))) = 0.0; AIR0CabiA003012003.port.T = TC_1232_1371.port_b.T; AIR0CabiA003012003.port.T = TC_1360_1371.port_b.T; AIR0CabiA003012003.port.T = TC_1370_1371.port_b.T; AIR0CabiA003012003.port.T = TC_1371_1372.port_a.T; AIR0CabiA003012003.port.T = TC_1371_1382.port_a.T; AIR0CabiA003012003.port.T = TC_1371_1434.port_a.T; AIR0CabiA003012003.port.T = TsAIR0CabiA003012003.port.T; TsAIR0CabiA002012003.port.Q_flow + (TC_1359_1370.port_b.Q_flow + (TC_1231_1370.port_b.Q_flow + (TC_403_1370.port_b.Q_flow + (AIR0CabiA002012003.port.Q_flow + (TC_1370_1371.port_a.Q_flow + (TC_1370_1381.port_a.Q_flow + TC_1370_1433.port_a.Q_flow)))))) = 0.0; AIR0CabiA002012003.port.T = TC_1231_1370.port_b.T; AIR0CabiA002012003.port.T = TC_1359_1370.port_b.T; AIR0CabiA002012003.port.T = TC_1370_1371.port_a.T; AIR0CabiA002012003.port.T = TC_1370_1381.port_a.T; AIR0CabiA002012003.port.T = TC_1370_1433.port_a.T; AIR0CabiA002012003.port.T = TC_403_1370.port_b.T; AIR0CabiA002012003.port.T = TsAIR0CabiA002012003.port.T; TsAIR0CabiA012011003.port.Q_flow + (TC_1368_1369.port_b.Q_flow + (TC_1358_1369.port_b.Q_flow + (TC_1230_1369.port_b.Q_flow + (TC_402_1369.port_b.Q_flow + (AIR0CabiA012011003.port.Q_flow + (TC_1369_1380.port_a.Q_flow + TC_1369_1432.port_a.Q_flow)))))) = 0.0; AIR0CabiA012011003.port.T = TC_1230_1369.port_b.T; AIR0CabiA012011003.port.T = TC_1358_1369.port_b.T; AIR0CabiA012011003.port.T = TC_1368_1369.port_b.T; AIR0CabiA012011003.port.T = TC_1369_1380.port_a.T; AIR0CabiA012011003.port.T = TC_1369_1432.port_a.T; AIR0CabiA012011003.port.T = TC_402_1369.port_b.T; AIR0CabiA012011003.port.T = TsAIR0CabiA012011003.port.T; TsAIR0CabiA011011003.port.Q_flow + (TC_1367_1368.port_b.Q_flow + (TC_1357_1368.port_b.Q_flow + (TC_1229_1368.port_b.Q_flow + (TC_796_1368.port_b.Q_flow + (AIR0CabiA011011003.port.Q_flow + (TC_1368_1369.port_a.Q_flow + TC_1368_1379.port_a.Q_flow)))))) = 0.0; AIR0CabiA011011003.port.T = TC_1229_1368.port_b.T; AIR0CabiA011011003.port.T = TC_1357_1368.port_b.T; AIR0CabiA011011003.port.T = TC_1367_1368.port_b.T; AIR0CabiA011011003.port.T = TC_1368_1369.port_a.T; AIR0CabiA011011003.port.T = TC_1368_1379.port_a.T; AIR0CabiA011011003.port.T = TC_796_1368.port_b.T; AIR0CabiA011011003.port.T = TsAIR0CabiA011011003.port.T; TsAIR0CabiA010011003.port.Q_flow + (TC_1366_1367.port_b.Q_flow + (TC_1228_1367.port_b.Q_flow + (TC_795_1367.port_b.Q_flow + (AIR0CabiA010011003.port.Q_flow + (TC_1367_1368.port_a.Q_flow + (TC_1367_1378.port_a.Q_flow + TC_1367_1496.port_a.Q_flow)))))) = 0.0; AIR0CabiA010011003.port.T = TC_1228_1367.port_b.T; AIR0CabiA010011003.port.T = TC_1366_1367.port_b.T; AIR0CabiA010011003.port.T = TC_1367_1368.port_a.T; AIR0CabiA010011003.port.T = TC_1367_1378.port_a.T; AIR0CabiA010011003.port.T = TC_1367_1496.port_a.T; AIR0CabiA010011003.port.T = TC_795_1367.port_b.T; AIR0CabiA010011003.port.T = TsAIR0CabiA010011003.port.T; TsAIR0CabiA009011003.port.Q_flow + (TC_1365_1366.port_b.Q_flow + (TC_1227_1366.port_b.Q_flow + (TC_794_1366.port_b.Q_flow + (AIR0CabiA009011003.port.Q_flow + (TC_1366_1367.port_a.Q_flow + (TC_1366_1377.port_a.Q_flow + TC_1366_1495.port_a.Q_flow)))))) = 0.0; AIR0CabiA009011003.port.T = TC_1227_1366.port_b.T; AIR0CabiA009011003.port.T = TC_1365_1366.port_b.T; AIR0CabiA009011003.port.T = TC_1366_1367.port_a.T; AIR0CabiA009011003.port.T = TC_1366_1377.port_a.T; AIR0CabiA009011003.port.T = TC_1366_1495.port_a.T; AIR0CabiA009011003.port.T = TC_794_1366.port_b.T; AIR0CabiA009011003.port.T = TsAIR0CabiA009011003.port.T; TsAIR0CabiA008011003.port.Q_flow + (TC_1364_1365.port_b.Q_flow + (TC_1226_1365.port_b.Q_flow + (TC_793_1365.port_b.Q_flow + (AIR0CabiA008011003.port.Q_flow + (TC_1365_1366.port_a.Q_flow + (TC_1365_1376.port_a.Q_flow + TC_1365_1494.port_a.Q_flow)))))) = 0.0; AIR0CabiA008011003.port.T = TC_1226_1365.port_b.T; AIR0CabiA008011003.port.T = TC_1364_1365.port_b.T; AIR0CabiA008011003.port.T = TC_1365_1366.port_a.T; AIR0CabiA008011003.port.T = TC_1365_1376.port_a.T; AIR0CabiA008011003.port.T = TC_1365_1494.port_a.T; AIR0CabiA008011003.port.T = TC_793_1365.port_b.T; AIR0CabiA008011003.port.T = TsAIR0CabiA008011003.port.T; TsAIR0CabiA007011003.port.Q_flow + (TC_1363_1364.port_b.Q_flow + (TC_1356_1364.port_b.Q_flow + (TC_1225_1364.port_b.Q_flow + (TC_792_1364.port_b.Q_flow + (AIR0CabiA007011003.port.Q_flow + (TC_1364_1365.port_a.Q_flow + TC_1364_1375.port_a.Q_flow)))))) = 0.0; AIR0CabiA007011003.port.T = TC_1225_1364.port_b.T; AIR0CabiA007011003.port.T = TC_1356_1364.port_b.T; AIR0CabiA007011003.port.T = TC_1363_1364.port_b.T; AIR0CabiA007011003.port.T = TC_1364_1365.port_a.T; AIR0CabiA007011003.port.T = TC_1364_1375.port_a.T; AIR0CabiA007011003.port.T = TC_792_1364.port_b.T; AIR0CabiA007011003.port.T = TsAIR0CabiA007011003.port.T; TsAIR0CabiA006011003.port.Q_flow + (TC_1362_1363.port_b.Q_flow + (TC_1355_1363.port_b.Q_flow + (TC_791_1363.port_b.Q_flow + (AIR0CabiA006011003.port.Q_flow + (TC_1363_1364.port_a.Q_flow + (TC_1363_1374.port_a.Q_flow + TC_1363_1520.port_a.Q_flow)))))) = 0.0; AIR0CabiA006011003.port.T = TC_1355_1363.port_b.T; AIR0CabiA006011003.port.T = TC_1362_1363.port_b.T; AIR0CabiA006011003.port.T = TC_1363_1364.port_a.T; AIR0CabiA006011003.port.T = TC_1363_1374.port_a.T; AIR0CabiA006011003.port.T = TC_1363_1520.port_a.T; AIR0CabiA006011003.port.T = TC_791_1363.port_b.T; AIR0CabiA006011003.port.T = TsAIR0CabiA006011003.port.T; TsAIR0CabiA005011003.port.Q_flow + (TC_1361_1362.port_b.Q_flow + (TC_1354_1362.port_b.Q_flow + (TC_790_1362.port_b.Q_flow + (AIR0CabiA005011003.port.Q_flow + (TC_1362_1363.port_a.Q_flow + (TC_1362_1373.port_a.Q_flow + TC_1362_1519.port_a.Q_flow)))))) = 0.0; AIR0CabiA005011003.port.T = TC_1354_1362.port_b.T; AIR0CabiA005011003.port.T = TC_1361_1362.port_b.T; AIR0CabiA005011003.port.T = TC_1362_1363.port_a.T; AIR0CabiA005011003.port.T = TC_1362_1373.port_a.T; AIR0CabiA005011003.port.T = TC_1362_1519.port_a.T; AIR0CabiA005011003.port.T = TC_790_1362.port_b.T; AIR0CabiA005011003.port.T = TsAIR0CabiA005011003.port.T; TsAIR0CabiA004011003.port.Q_flow + (TC_1360_1361.port_b.Q_flow + (TC_1353_1361.port_b.Q_flow + (TC_789_1361.port_b.Q_flow + (AIR0CabiA004011003.port.Q_flow + (TC_1361_1362.port_a.Q_flow + (TC_1361_1372.port_a.Q_flow + TC_1361_1518.port_a.Q_flow)))))) = 0.0; AIR0CabiA004011003.port.T = TC_1353_1361.port_b.T; AIR0CabiA004011003.port.T = TC_1360_1361.port_b.T; AIR0CabiA004011003.port.T = TC_1361_1362.port_a.T; AIR0CabiA004011003.port.T = TC_1361_1372.port_a.T; AIR0CabiA004011003.port.T = TC_1361_1518.port_a.T; AIR0CabiA004011003.port.T = TC_789_1361.port_b.T; AIR0CabiA004011003.port.T = TsAIR0CabiA004011003.port.T; TsAIR0CabiA003011003.port.Q_flow + (TC_1359_1360.port_b.Q_flow + (TC_1352_1360.port_b.Q_flow + (TC_1224_1360.port_b.Q_flow + (AIR0CabiA003011003.port.Q_flow + (TC_1360_1361.port_a.Q_flow + (TC_1360_1371.port_a.Q_flow + TC_1360_1431.port_a.Q_flow)))))) = 0.0; AIR0CabiA003011003.port.T = TC_1224_1360.port_b.T; AIR0CabiA003011003.port.T = TC_1352_1360.port_b.T; AIR0CabiA003011003.port.T = TC_1359_1360.port_b.T; AIR0CabiA003011003.port.T = TC_1360_1361.port_a.T; AIR0CabiA003011003.port.T = TC_1360_1371.port_a.T; AIR0CabiA003011003.port.T = TC_1360_1431.port_a.T; AIR0CabiA003011003.port.T = TsAIR0CabiA003011003.port.T; TsAIR0CabiA002011003.port.Q_flow + (TC_1351_1359.port_b.Q_flow + (TC_1223_1359.port_b.Q_flow + (TC_401_1359.port_b.Q_flow + (AIR0CabiA002011003.port.Q_flow + (TC_1359_1360.port_a.Q_flow + (TC_1359_1370.port_a.Q_flow + TC_1359_1430.port_a.Q_flow)))))) = 0.0; AIR0CabiA002011003.port.T = TC_1223_1359.port_b.T; AIR0CabiA002011003.port.T = TC_1351_1359.port_b.T; AIR0CabiA002011003.port.T = TC_1359_1360.port_a.T; AIR0CabiA002011003.port.T = TC_1359_1370.port_a.T; AIR0CabiA002011003.port.T = TC_1359_1430.port_a.T; AIR0CabiA002011003.port.T = TC_401_1359.port_b.T; AIR0CabiA002011003.port.T = TsAIR0CabiA002011003.port.T; TsAIR0CabiA012010003.port.Q_flow + (TC_1357_1358.port_b.Q_flow + (TC_1350_1358.port_b.Q_flow + (TC_1222_1358.port_b.Q_flow + (TC_400_1358.port_b.Q_flow + (AIR0CabiA012010003.port.Q_flow + (TC_1358_1369.port_a.Q_flow + TC_1358_1429.port_a.Q_flow)))))) = 0.0; AIR0CabiA012010003.port.T = TC_1222_1358.port_b.T; AIR0CabiA012010003.port.T = TC_1350_1358.port_b.T; AIR0CabiA012010003.port.T = TC_1357_1358.port_b.T; AIR0CabiA012010003.port.T = TC_1358_1369.port_a.T; AIR0CabiA012010003.port.T = TC_1358_1429.port_a.T; AIR0CabiA012010003.port.T = TC_400_1358.port_b.T; AIR0CabiA012010003.port.T = TsAIR0CabiA012010003.port.T; TsAIR0CabiA011010003.port.Q_flow + (TC_1349_1357.port_b.Q_flow + (TC_1221_1357.port_b.Q_flow + (TC_788_1357.port_b.Q_flow + (AIR0CabiA011010003.port.Q_flow + (TC_1357_1358.port_a.Q_flow + (TC_1357_1368.port_a.Q_flow + TC_1357_1496.port_a.Q_flow)))))) = 0.0; AIR0CabiA011010003.port.T = TC_1221_1357.port_b.T; AIR0CabiA011010003.port.T = TC_1349_1357.port_b.T; AIR0CabiA011010003.port.T = TC_1357_1358.port_a.T; AIR0CabiA011010003.port.T = TC_1357_1368.port_a.T; AIR0CabiA011010003.port.T = TC_1357_1496.port_a.T; AIR0CabiA011010003.port.T = TC_788_1357.port_b.T; AIR0CabiA011010003.port.T = TsAIR0CabiA011010003.port.T; TsAIR0CabiA007010003.port.Q_flow + (TC_1355_1356.port_b.Q_flow + (TC_1348_1356.port_b.Q_flow + (TC_1220_1356.port_b.Q_flow + (TC_784_1356.port_b.Q_flow + (AIR0CabiA007010003.port.Q_flow + (TC_1356_1364.port_a.Q_flow + TC_1356_1494.port_a.Q_flow)))))) = 0.0; AIR0CabiA007010003.port.T = TC_1220_1356.port_b.T; AIR0CabiA007010003.port.T = TC_1348_1356.port_b.T; AIR0CabiA007010003.port.T = TC_1355_1356.port_b.T; AIR0CabiA007010003.port.T = TC_1356_1364.port_a.T; AIR0CabiA007010003.port.T = TC_1356_1494.port_a.T; AIR0CabiA007010003.port.T = TC_784_1356.port_b.T; AIR0CabiA007010003.port.T = TsAIR0CabiA007010003.port.T; TsAIR0CabiA006010003.port.Q_flow + (TC_1354_1355.port_b.Q_flow + (TC_1347_1355.port_b.Q_flow + (TC_1219_1355.port_b.Q_flow + (TC_783_1355.port_b.Q_flow + (AIR0CabiA006010003.port.Q_flow + (TC_1355_1356.port_a.Q_flow + TC_1355_1363.port_a.Q_flow)))))) = 0.0; AIR0CabiA006010003.port.T = TC_1219_1355.port_b.T; AIR0CabiA006010003.port.T = TC_1347_1355.port_b.T; AIR0CabiA006010003.port.T = TC_1354_1355.port_b.T; AIR0CabiA006010003.port.T = TC_1355_1356.port_a.T; AIR0CabiA006010003.port.T = TC_1355_1363.port_a.T; AIR0CabiA006010003.port.T = TC_783_1355.port_b.T; AIR0CabiA006010003.port.T = TsAIR0CabiA006010003.port.T; TsAIR0CabiA005010003.port.Q_flow + (TC_1353_1354.port_b.Q_flow + (TC_1346_1354.port_b.Q_flow + (TC_1218_1354.port_b.Q_flow + (TC_782_1354.port_b.Q_flow + (AIR0CabiA005010003.port.Q_flow + (TC_1354_1355.port_a.Q_flow + TC_1354_1362.port_a.Q_flow)))))) = 0.0; AIR0CabiA005010003.port.T = TC_1218_1354.port_b.T; AIR0CabiA005010003.port.T = TC_1346_1354.port_b.T; AIR0CabiA005010003.port.T = TC_1353_1354.port_b.T; AIR0CabiA005010003.port.T = TC_1354_1355.port_a.T; AIR0CabiA005010003.port.T = TC_1354_1362.port_a.T; AIR0CabiA005010003.port.T = TC_782_1354.port_b.T; AIR0CabiA005010003.port.T = TsAIR0CabiA005010003.port.T; TsAIR0CabiA004010003.port.Q_flow + (TC_1352_1353.port_b.Q_flow + (TC_1345_1353.port_b.Q_flow + (TC_1217_1353.port_b.Q_flow + (TC_781_1353.port_b.Q_flow + (AIR0CabiA004010003.port.Q_flow + (TC_1353_1354.port_a.Q_flow + TC_1353_1361.port_a.Q_flow)))))) = 0.0; AIR0CabiA004010003.port.T = TC_1217_1353.port_b.T; AIR0CabiA004010003.port.T = TC_1345_1353.port_b.T; AIR0CabiA004010003.port.T = TC_1352_1353.port_b.T; AIR0CabiA004010003.port.T = TC_1353_1354.port_a.T; AIR0CabiA004010003.port.T = TC_1353_1361.port_a.T; AIR0CabiA004010003.port.T = TC_781_1353.port_b.T; AIR0CabiA004010003.port.T = TsAIR0CabiA004010003.port.T; TsAIR0CabiA003010003.port.Q_flow + (TC_1351_1352.port_b.Q_flow + (TC_1344_1352.port_b.Q_flow + (TC_1216_1352.port_b.Q_flow + (AIR0CabiA003010003.port.Q_flow + (TC_1352_1353.port_a.Q_flow + (TC_1352_1360.port_a.Q_flow + TC_1352_1428.port_a.Q_flow)))))) = 0.0; AIR0CabiA003010003.port.T = TC_1216_1352.port_b.T; AIR0CabiA003010003.port.T = TC_1344_1352.port_b.T; AIR0CabiA003010003.port.T = TC_1351_1352.port_b.T; AIR0CabiA003010003.port.T = TC_1352_1353.port_a.T; AIR0CabiA003010003.port.T = TC_1352_1360.port_a.T; AIR0CabiA003010003.port.T = TC_1352_1428.port_a.T; AIR0CabiA003010003.port.T = TsAIR0CabiA003010003.port.T; TsAIR0CabiA002010003.port.Q_flow + (TC_1343_1351.port_b.Q_flow + (TC_1215_1351.port_b.Q_flow + (TC_399_1351.port_b.Q_flow + (AIR0CabiA002010003.port.Q_flow + (TC_1351_1352.port_a.Q_flow + (TC_1351_1359.port_a.Q_flow + TC_1351_1427.port_a.Q_flow)))))) = 0.0; AIR0CabiA002010003.port.T = TC_1215_1351.port_b.T; AIR0CabiA002010003.port.T = TC_1343_1351.port_b.T; AIR0CabiA002010003.port.T = TC_1351_1352.port_a.T; AIR0CabiA002010003.port.T = TC_1351_1359.port_a.T; AIR0CabiA002010003.port.T = TC_1351_1427.port_a.T; AIR0CabiA002010003.port.T = TC_399_1351.port_b.T; AIR0CabiA002010003.port.T = TsAIR0CabiA002010003.port.T; TsAIR0CabiA012009003.port.Q_flow + (TC_1349_1350.port_b.Q_flow + (TC_1342_1350.port_b.Q_flow + (TC_1214_1350.port_b.Q_flow + (TC_398_1350.port_b.Q_flow + (AIR0CabiA012009003.port.Q_flow + (TC_1350_1358.port_a.Q_flow + TC_1350_1426.port_a.Q_flow)))))) = 0.0; AIR0CabiA012009003.port.T = TC_1214_1350.port_b.T; AIR0CabiA012009003.port.T = TC_1342_1350.port_b.T; AIR0CabiA012009003.port.T = TC_1349_1350.port_b.T; AIR0CabiA012009003.port.T = TC_1350_1358.port_a.T; AIR0CabiA012009003.port.T = TC_1350_1426.port_a.T; AIR0CabiA012009003.port.T = TC_398_1350.port_b.T; AIR0CabiA012009003.port.T = TsAIR0CabiA012009003.port.T; TsAIR0CabiA011009003.port.Q_flow + (TC_1341_1349.port_b.Q_flow + (TC_1213_1349.port_b.Q_flow + (TC_780_1349.port_b.Q_flow + (AIR0CabiA011009003.port.Q_flow + (TC_1349_1350.port_a.Q_flow + (TC_1349_1357.port_a.Q_flow + TC_1349_1493.port_a.Q_flow)))))) = 0.0; AIR0CabiA011009003.port.T = TC_1213_1349.port_b.T; AIR0CabiA011009003.port.T = TC_1341_1349.port_b.T; AIR0CabiA011009003.port.T = TC_1349_1350.port_a.T; AIR0CabiA011009003.port.T = TC_1349_1357.port_a.T; AIR0CabiA011009003.port.T = TC_1349_1493.port_a.T; AIR0CabiA011009003.port.T = TC_780_1349.port_b.T; AIR0CabiA011009003.port.T = TsAIR0CabiA011009003.port.T; TsAIR0CabiA007009003.port.Q_flow + (TC_1347_1348.port_b.Q_flow + (TC_1340_1348.port_b.Q_flow + (TC_1212_1348.port_b.Q_flow + (TC_776_1348.port_b.Q_flow + (AIR0CabiA007009003.port.Q_flow + (TC_1348_1356.port_a.Q_flow + TC_1348_1491.port_a.Q_flow)))))) = 0.0; AIR0CabiA007009003.port.T = TC_1212_1348.port_b.T; AIR0CabiA007009003.port.T = TC_1340_1348.port_b.T; AIR0CabiA007009003.port.T = TC_1347_1348.port_b.T; AIR0CabiA007009003.port.T = TC_1348_1356.port_a.T; AIR0CabiA007009003.port.T = TC_1348_1491.port_a.T; AIR0CabiA007009003.port.T = TC_776_1348.port_b.T; AIR0CabiA007009003.port.T = TsAIR0CabiA007009003.port.T; TsAIR0CabiA006009003.port.Q_flow + (TC_1346_1347.port_b.Q_flow + (TC_1339_1347.port_b.Q_flow + (TC_1211_1347.port_b.Q_flow + (TC_775_1347.port_b.Q_flow + (AIR0CabiA006009003.port.Q_flow + (TC_1347_1348.port_a.Q_flow + TC_1347_1355.port_a.Q_flow)))))) = 0.0; AIR0CabiA006009003.port.T = TC_1211_1347.port_b.T; AIR0CabiA006009003.port.T = TC_1339_1347.port_b.T; AIR0CabiA006009003.port.T = TC_1346_1347.port_b.T; AIR0CabiA006009003.port.T = TC_1347_1348.port_a.T; AIR0CabiA006009003.port.T = TC_1347_1355.port_a.T; AIR0CabiA006009003.port.T = TC_775_1347.port_b.T; AIR0CabiA006009003.port.T = TsAIR0CabiA006009003.port.T; TsAIR0CabiA005009003.port.Q_flow + (TC_1345_1346.port_b.Q_flow + (TC_1338_1346.port_b.Q_flow + (TC_1210_1346.port_b.Q_flow + (TC_774_1346.port_b.Q_flow + (AIR0CabiA005009003.port.Q_flow + (TC_1346_1347.port_a.Q_flow + TC_1346_1354.port_a.Q_flow)))))) = 0.0; AIR0CabiA005009003.port.T = TC_1210_1346.port_b.T; AIR0CabiA005009003.port.T = TC_1338_1346.port_b.T; AIR0CabiA005009003.port.T = TC_1345_1346.port_b.T; AIR0CabiA005009003.port.T = TC_1346_1347.port_a.T; AIR0CabiA005009003.port.T = TC_1346_1354.port_a.T; AIR0CabiA005009003.port.T = TC_774_1346.port_b.T; AIR0CabiA005009003.port.T = TsAIR0CabiA005009003.port.T; TsAIR0CabiA004009003.port.Q_flow + (TC_1344_1345.port_b.Q_flow + (TC_1337_1345.port_b.Q_flow + (TC_1209_1345.port_b.Q_flow + (TC_773_1345.port_b.Q_flow + (AIR0CabiA004009003.port.Q_flow + (TC_1345_1346.port_a.Q_flow + TC_1345_1353.port_a.Q_flow)))))) = 0.0; AIR0CabiA004009003.port.T = TC_1209_1345.port_b.T; AIR0CabiA004009003.port.T = TC_1337_1345.port_b.T; AIR0CabiA004009003.port.T = TC_1344_1345.port_b.T; AIR0CabiA004009003.port.T = TC_1345_1346.port_a.T; AIR0CabiA004009003.port.T = TC_1345_1353.port_a.T; AIR0CabiA004009003.port.T = TC_773_1345.port_b.T; AIR0CabiA004009003.port.T = TsAIR0CabiA004009003.port.T; TsAIR0CabiA003009003.port.Q_flow + (TC_1343_1344.port_b.Q_flow + (TC_1336_1344.port_b.Q_flow + (TC_1208_1344.port_b.Q_flow + (AIR0CabiA003009003.port.Q_flow + (TC_1344_1345.port_a.Q_flow + (TC_1344_1352.port_a.Q_flow + TC_1344_1425.port_a.Q_flow)))))) = 0.0; AIR0CabiA003009003.port.T = TC_1208_1344.port_b.T; AIR0CabiA003009003.port.T = TC_1336_1344.port_b.T; AIR0CabiA003009003.port.T = TC_1343_1344.port_b.T; AIR0CabiA003009003.port.T = TC_1344_1345.port_a.T; AIR0CabiA003009003.port.T = TC_1344_1352.port_a.T; AIR0CabiA003009003.port.T = TC_1344_1425.port_a.T; AIR0CabiA003009003.port.T = TsAIR0CabiA003009003.port.T; TsAIR0CabiA002009003.port.Q_flow + (TC_1335_1343.port_b.Q_flow + (TC_1207_1343.port_b.Q_flow + (TC_397_1343.port_b.Q_flow + (AIR0CabiA002009003.port.Q_flow + (TC_1343_1344.port_a.Q_flow + (TC_1343_1351.port_a.Q_flow + TC_1343_1424.port_a.Q_flow)))))) = 0.0; AIR0CabiA002009003.port.T = TC_1207_1343.port_b.T; AIR0CabiA002009003.port.T = TC_1335_1343.port_b.T; AIR0CabiA002009003.port.T = TC_1343_1344.port_a.T; AIR0CabiA002009003.port.T = TC_1343_1351.port_a.T; AIR0CabiA002009003.port.T = TC_1343_1424.port_a.T; AIR0CabiA002009003.port.T = TC_397_1343.port_b.T; AIR0CabiA002009003.port.T = TsAIR0CabiA002009003.port.T; TsAIR0CabiA012008003.port.Q_flow + (TC_1341_1342.port_b.Q_flow + (TC_1334_1342.port_b.Q_flow + (TC_1206_1342.port_b.Q_flow + (TC_396_1342.port_b.Q_flow + (AIR0CabiA012008003.port.Q_flow + (TC_1342_1350.port_a.Q_flow + TC_1342_1423.port_a.Q_flow)))))) = 0.0; AIR0CabiA012008003.port.T = TC_1206_1342.port_b.T; AIR0CabiA012008003.port.T = TC_1334_1342.port_b.T; AIR0CabiA012008003.port.T = TC_1341_1342.port_b.T; AIR0CabiA012008003.port.T = TC_1342_1350.port_a.T; AIR0CabiA012008003.port.T = TC_1342_1423.port_a.T; AIR0CabiA012008003.port.T = TC_396_1342.port_b.T; AIR0CabiA012008003.port.T = TsAIR0CabiA012008003.port.T; TsAIR0CabiA011008003.port.Q_flow + (TC_1333_1341.port_b.Q_flow + (TC_1205_1341.port_b.Q_flow + (TC_772_1341.port_b.Q_flow + (AIR0CabiA011008003.port.Q_flow + (TC_1341_1342.port_a.Q_flow + (TC_1341_1349.port_a.Q_flow + TC_1341_1490.port_a.Q_flow)))))) = 0.0; AIR0CabiA011008003.port.T = TC_1205_1341.port_b.T; AIR0CabiA011008003.port.T = TC_1333_1341.port_b.T; AIR0CabiA011008003.port.T = TC_1341_1342.port_a.T; AIR0CabiA011008003.port.T = TC_1341_1349.port_a.T; AIR0CabiA011008003.port.T = TC_1341_1490.port_a.T; AIR0CabiA011008003.port.T = TC_772_1341.port_b.T; AIR0CabiA011008003.port.T = TsAIR0CabiA011008003.port.T; TsAIR0CabiA007008003.port.Q_flow + (TC_1339_1340.port_b.Q_flow + (TC_1329_1340.port_b.Q_flow + (TC_1204_1340.port_b.Q_flow + (TC_768_1340.port_b.Q_flow + (AIR0CabiA007008003.port.Q_flow + (TC_1340_1348.port_a.Q_flow + TC_1340_1488.port_a.Q_flow)))))) = 0.0; AIR0CabiA007008003.port.T = TC_1204_1340.port_b.T; AIR0CabiA007008003.port.T = TC_1329_1340.port_b.T; AIR0CabiA007008003.port.T = TC_1339_1340.port_b.T; AIR0CabiA007008003.port.T = TC_1340_1348.port_a.T; AIR0CabiA007008003.port.T = TC_1340_1488.port_a.T; AIR0CabiA007008003.port.T = TC_768_1340.port_b.T; AIR0CabiA007008003.port.T = TsAIR0CabiA007008003.port.T; TsAIR0CabiA006008003.port.Q_flow + (TC_1338_1339.port_b.Q_flow + (TC_1328_1339.port_b.Q_flow + (TC_1203_1339.port_b.Q_flow + (TC_767_1339.port_b.Q_flow + (AIR0CabiA006008003.port.Q_flow + (TC_1339_1340.port_a.Q_flow + TC_1339_1347.port_a.Q_flow)))))) = 0.0; AIR0CabiA006008003.port.T = TC_1203_1339.port_b.T; AIR0CabiA006008003.port.T = TC_1328_1339.port_b.T; AIR0CabiA006008003.port.T = TC_1338_1339.port_b.T; AIR0CabiA006008003.port.T = TC_1339_1340.port_a.T; AIR0CabiA006008003.port.T = TC_1339_1347.port_a.T; AIR0CabiA006008003.port.T = TC_767_1339.port_b.T; AIR0CabiA006008003.port.T = TsAIR0CabiA006008003.port.T; TsAIR0CabiA005008003.port.Q_flow + (TC_1337_1338.port_b.Q_flow + (TC_1327_1338.port_b.Q_flow + (TC_1202_1338.port_b.Q_flow + (TC_766_1338.port_b.Q_flow + (AIR0CabiA005008003.port.Q_flow + (TC_1338_1339.port_a.Q_flow + TC_1338_1346.port_a.Q_flow)))))) = 0.0; AIR0CabiA005008003.port.T = TC_1202_1338.port_b.T; AIR0CabiA005008003.port.T = TC_1327_1338.port_b.T; AIR0CabiA005008003.port.T = TC_1337_1338.port_b.T; AIR0CabiA005008003.port.T = TC_1338_1339.port_a.T; AIR0CabiA005008003.port.T = TC_1338_1346.port_a.T; AIR0CabiA005008003.port.T = TC_766_1338.port_b.T; AIR0CabiA005008003.port.T = TsAIR0CabiA005008003.port.T; TsAIR0CabiA004008003.port.Q_flow + (TC_1336_1337.port_b.Q_flow + (TC_1326_1337.port_b.Q_flow + (TC_1201_1337.port_b.Q_flow + (TC_765_1337.port_b.Q_flow + (AIR0CabiA004008003.port.Q_flow + (TC_1337_1338.port_a.Q_flow + TC_1337_1345.port_a.Q_flow)))))) = 0.0; AIR0CabiA004008003.port.T = TC_1201_1337.port_b.T; AIR0CabiA004008003.port.T = TC_1326_1337.port_b.T; AIR0CabiA004008003.port.T = TC_1336_1337.port_b.T; AIR0CabiA004008003.port.T = TC_1337_1338.port_a.T; AIR0CabiA004008003.port.T = TC_1337_1345.port_a.T; AIR0CabiA004008003.port.T = TC_765_1337.port_b.T; AIR0CabiA004008003.port.T = TsAIR0CabiA004008003.port.T; TsAIR0CabiA003008003.port.Q_flow + (TC_1335_1336.port_b.Q_flow + (TC_1325_1336.port_b.Q_flow + (TC_1200_1336.port_b.Q_flow + (AIR0CabiA003008003.port.Q_flow + (TC_1336_1337.port_a.Q_flow + (TC_1336_1344.port_a.Q_flow + TC_1336_1422.port_a.Q_flow)))))) = 0.0; AIR0CabiA003008003.port.T = TC_1200_1336.port_b.T; AIR0CabiA003008003.port.T = TC_1325_1336.port_b.T; AIR0CabiA003008003.port.T = TC_1335_1336.port_b.T; AIR0CabiA003008003.port.T = TC_1336_1337.port_a.T; AIR0CabiA003008003.port.T = TC_1336_1344.port_a.T; AIR0CabiA003008003.port.T = TC_1336_1422.port_a.T; AIR0CabiA003008003.port.T = TsAIR0CabiA003008003.port.T; TsAIR0CabiA002008003.port.Q_flow + (TC_1324_1335.port_b.Q_flow + (TC_1199_1335.port_b.Q_flow + (TC_395_1335.port_b.Q_flow + (AIR0CabiA002008003.port.Q_flow + (TC_1335_1336.port_a.Q_flow + (TC_1335_1343.port_a.Q_flow + TC_1335_1421.port_a.Q_flow)))))) = 0.0; AIR0CabiA002008003.port.T = TC_1199_1335.port_b.T; AIR0CabiA002008003.port.T = TC_1324_1335.port_b.T; AIR0CabiA002008003.port.T = TC_1335_1336.port_a.T; AIR0CabiA002008003.port.T = TC_1335_1343.port_a.T; AIR0CabiA002008003.port.T = TC_1335_1421.port_a.T; AIR0CabiA002008003.port.T = TC_395_1335.port_b.T; AIR0CabiA002008003.port.T = TsAIR0CabiA002008003.port.T; TsAIR0CabiA012007003.port.Q_flow + (TC_1333_1334.port_b.Q_flow + (TC_1323_1334.port_b.Q_flow + (TC_1198_1334.port_b.Q_flow + (TC_394_1334.port_b.Q_flow + (AIR0CabiA012007003.port.Q_flow + (TC_1334_1342.port_a.Q_flow + TC_1334_1420.port_a.Q_flow)))))) = 0.0; AIR0CabiA012007003.port.T = TC_1198_1334.port_b.T; AIR0CabiA012007003.port.T = TC_1323_1334.port_b.T; AIR0CabiA012007003.port.T = TC_1333_1334.port_b.T; AIR0CabiA012007003.port.T = TC_1334_1342.port_a.T; AIR0CabiA012007003.port.T = TC_1334_1420.port_a.T; AIR0CabiA012007003.port.T = TC_394_1334.port_b.T; AIR0CabiA012007003.port.T = TsAIR0CabiA012007003.port.T; TsAIR0CabiA011007003.port.Q_flow + (TC_1332_1333.port_b.Q_flow + (TC_1322_1333.port_b.Q_flow + (TC_1197_1333.port_b.Q_flow + (TC_764_1333.port_b.Q_flow + (AIR0CabiA011007003.port.Q_flow + (TC_1333_1334.port_a.Q_flow + TC_1333_1341.port_a.Q_flow)))))) = 0.0; AIR0CabiA011007003.port.T = TC_1197_1333.port_b.T; AIR0CabiA011007003.port.T = TC_1322_1333.port_b.T; AIR0CabiA011007003.port.T = TC_1332_1333.port_b.T; AIR0CabiA011007003.port.T = TC_1333_1334.port_a.T; AIR0CabiA011007003.port.T = TC_1333_1341.port_a.T; AIR0CabiA011007003.port.T = TC_764_1333.port_b.T; AIR0CabiA011007003.port.T = TsAIR0CabiA011007003.port.T; TsAIR0CabiA010007003.port.Q_flow + (TC_1331_1332.port_b.Q_flow + (TC_1321_1332.port_b.Q_flow + (TC_1196_1332.port_b.Q_flow + (TC_763_1332.port_b.Q_flow + (AIR0CabiA010007003.port.Q_flow + (TC_1332_1333.port_a.Q_flow + TC_1332_1490.port_a.Q_flow)))))) = 0.0; AIR0CabiA010007003.port.T = TC_1196_1332.port_b.T; AIR0CabiA010007003.port.T = TC_1321_1332.port_b.T; AIR0CabiA010007003.port.T = TC_1331_1332.port_b.T; AIR0CabiA010007003.port.T = TC_1332_1333.port_a.T; AIR0CabiA010007003.port.T = TC_1332_1490.port_a.T; AIR0CabiA010007003.port.T = TC_763_1332.port_b.T; AIR0CabiA010007003.port.T = TsAIR0CabiA010007003.port.T; TsAIR0CabiA009007003.port.Q_flow + (TC_1330_1331.port_b.Q_flow + (TC_1320_1331.port_b.Q_flow + (TC_1195_1331.port_b.Q_flow + (TC_762_1331.port_b.Q_flow + (AIR0CabiA009007003.port.Q_flow + (TC_1331_1332.port_a.Q_flow + TC_1331_1489.port_a.Q_flow)))))) = 0.0; AIR0CabiA009007003.port.T = TC_1195_1331.port_b.T; AIR0CabiA009007003.port.T = TC_1320_1331.port_b.T; AIR0CabiA009007003.port.T = TC_1330_1331.port_b.T; AIR0CabiA009007003.port.T = TC_1331_1332.port_a.T; AIR0CabiA009007003.port.T = TC_1331_1489.port_a.T; AIR0CabiA009007003.port.T = TC_762_1331.port_b.T; AIR0CabiA009007003.port.T = TsAIR0CabiA009007003.port.T; TsAIR0CabiA008007003.port.Q_flow + (TC_1329_1330.port_b.Q_flow + (TC_1319_1330.port_b.Q_flow + (TC_1194_1330.port_b.Q_flow + (TC_761_1330.port_b.Q_flow + (AIR0CabiA008007003.port.Q_flow + (TC_1330_1331.port_a.Q_flow + TC_1330_1488.port_a.Q_flow)))))) = 0.0; AIR0CabiA008007003.port.T = TC_1194_1330.port_b.T; AIR0CabiA008007003.port.T = TC_1319_1330.port_b.T; AIR0CabiA008007003.port.T = TC_1329_1330.port_b.T; AIR0CabiA008007003.port.T = TC_1330_1331.port_a.T; AIR0CabiA008007003.port.T = TC_1330_1488.port_a.T; AIR0CabiA008007003.port.T = TC_761_1330.port_b.T; AIR0CabiA008007003.port.T = TsAIR0CabiA008007003.port.T; TsAIR0CabiA007007003.port.Q_flow + (TC_1328_1329.port_b.Q_flow + (TC_1318_1329.port_b.Q_flow + (TC_1193_1329.port_b.Q_flow + (TC_760_1329.port_b.Q_flow + (AIR0CabiA007007003.port.Q_flow + (TC_1329_1330.port_a.Q_flow + TC_1329_1340.port_a.Q_flow)))))) = 0.0; AIR0CabiA007007003.port.T = TC_1193_1329.port_b.T; AIR0CabiA007007003.port.T = TC_1318_1329.port_b.T; AIR0CabiA007007003.port.T = TC_1328_1329.port_b.T; AIR0CabiA007007003.port.T = TC_1329_1330.port_a.T; AIR0CabiA007007003.port.T = TC_1329_1340.port_a.T; AIR0CabiA007007003.port.T = TC_760_1329.port_b.T; AIR0CabiA007007003.port.T = TsAIR0CabiA007007003.port.T; TsAIR0CabiA006007003.port.Q_flow + (TC_1327_1328.port_b.Q_flow + (TC_1317_1328.port_b.Q_flow + (TC_1192_1328.port_b.Q_flow + (TC_759_1328.port_b.Q_flow + (AIR0CabiA006007003.port.Q_flow + (TC_1328_1329.port_a.Q_flow + TC_1328_1339.port_a.Q_flow)))))) = 0.0; AIR0CabiA006007003.port.T = TC_1192_1328.port_b.T; AIR0CabiA006007003.port.T = TC_1317_1328.port_b.T; AIR0CabiA006007003.port.T = TC_1327_1328.port_b.T; AIR0CabiA006007003.port.T = TC_1328_1329.port_a.T; AIR0CabiA006007003.port.T = TC_1328_1339.port_a.T; AIR0CabiA006007003.port.T = TC_759_1328.port_b.T; AIR0CabiA006007003.port.T = TsAIR0CabiA006007003.port.T; TsAIR0CabiA005007003.port.Q_flow + (TC_1326_1327.port_b.Q_flow + (TC_1316_1327.port_b.Q_flow + (TC_1191_1327.port_b.Q_flow + (TC_758_1327.port_b.Q_flow + (AIR0CabiA005007003.port.Q_flow + (TC_1327_1328.port_a.Q_flow + TC_1327_1338.port_a.Q_flow)))))) = 0.0; AIR0CabiA005007003.port.T = TC_1191_1327.port_b.T; AIR0CabiA005007003.port.T = TC_1316_1327.port_b.T; AIR0CabiA005007003.port.T = TC_1326_1327.port_b.T; AIR0CabiA005007003.port.T = TC_1327_1328.port_a.T; AIR0CabiA005007003.port.T = TC_1327_1338.port_a.T; AIR0CabiA005007003.port.T = TC_758_1327.port_b.T; AIR0CabiA005007003.port.T = TsAIR0CabiA005007003.port.T; TsAIR0CabiA004007003.port.Q_flow + (TC_1325_1326.port_b.Q_flow + (TC_1315_1326.port_b.Q_flow + (TC_1190_1326.port_b.Q_flow + (TC_757_1326.port_b.Q_flow + (AIR0CabiA004007003.port.Q_flow + (TC_1326_1327.port_a.Q_flow + TC_1326_1337.port_a.Q_flow)))))) = 0.0; AIR0CabiA004007003.port.T = TC_1190_1326.port_b.T; AIR0CabiA004007003.port.T = TC_1315_1326.port_b.T; AIR0CabiA004007003.port.T = TC_1325_1326.port_b.T; AIR0CabiA004007003.port.T = TC_1326_1327.port_a.T; AIR0CabiA004007003.port.T = TC_1326_1337.port_a.T; AIR0CabiA004007003.port.T = TC_757_1326.port_b.T; AIR0CabiA004007003.port.T = TsAIR0CabiA004007003.port.T; TsAIR0CabiA003007003.port.Q_flow + (TC_1324_1325.port_b.Q_flow + (TC_1314_1325.port_b.Q_flow + (TC_1189_1325.port_b.Q_flow + (AIR0CabiA003007003.port.Q_flow + (TC_1325_1326.port_a.Q_flow + (TC_1325_1336.port_a.Q_flow + TC_1325_1419.port_a.Q_flow)))))) = 0.0; AIR0CabiA003007003.port.T = TC_1189_1325.port_b.T; AIR0CabiA003007003.port.T = TC_1314_1325.port_b.T; AIR0CabiA003007003.port.T = TC_1324_1325.port_b.T; AIR0CabiA003007003.port.T = TC_1325_1326.port_a.T; AIR0CabiA003007003.port.T = TC_1325_1336.port_a.T; AIR0CabiA003007003.port.T = TC_1325_1419.port_a.T; AIR0CabiA003007003.port.T = TsAIR0CabiA003007003.port.T; TsAIR0CabiA002007003.port.Q_flow + (TC_1313_1324.port_b.Q_flow + (TC_1188_1324.port_b.Q_flow + (TC_393_1324.port_b.Q_flow + (AIR0CabiA002007003.port.Q_flow + (TC_1324_1325.port_a.Q_flow + (TC_1324_1335.port_a.Q_flow + TC_1324_1418.port_a.Q_flow)))))) = 0.0; AIR0CabiA002007003.port.T = TC_1188_1324.port_b.T; AIR0CabiA002007003.port.T = TC_1313_1324.port_b.T; AIR0CabiA002007003.port.T = TC_1324_1325.port_a.T; AIR0CabiA002007003.port.T = TC_1324_1335.port_a.T; AIR0CabiA002007003.port.T = TC_1324_1418.port_a.T; AIR0CabiA002007003.port.T = TC_393_1324.port_b.T; AIR0CabiA002007003.port.T = TsAIR0CabiA002007003.port.T; TsAIR0CabiA012006003.port.Q_flow + (TC_1322_1323.port_b.Q_flow + (TC_1312_1323.port_b.Q_flow + (TC_1187_1323.port_b.Q_flow + (TC_392_1323.port_b.Q_flow + (AIR0CabiA012006003.port.Q_flow + (TC_1323_1334.port_a.Q_flow + TC_1323_1417.port_a.Q_flow)))))) = 0.0; AIR0CabiA012006003.port.T = TC_1187_1323.port_b.T; AIR0CabiA012006003.port.T = TC_1312_1323.port_b.T; AIR0CabiA012006003.port.T = TC_1322_1323.port_b.T; AIR0CabiA012006003.port.T = TC_1323_1334.port_a.T; AIR0CabiA012006003.port.T = TC_1323_1417.port_a.T; AIR0CabiA012006003.port.T = TC_392_1323.port_b.T; AIR0CabiA012006003.port.T = TsAIR0CabiA012006003.port.T; TsAIR0CabiA011006003.port.Q_flow + (TC_1321_1322.port_b.Q_flow + (TC_1311_1322.port_b.Q_flow + (TC_1186_1322.port_b.Q_flow + (TC_756_1322.port_b.Q_flow + (AIR0CabiA011006003.port.Q_flow + (TC_1322_1323.port_a.Q_flow + TC_1322_1333.port_a.Q_flow)))))) = 0.0; AIR0CabiA011006003.port.T = TC_1186_1322.port_b.T; AIR0CabiA011006003.port.T = TC_1311_1322.port_b.T; AIR0CabiA011006003.port.T = TC_1321_1322.port_b.T; AIR0CabiA011006003.port.T = TC_1322_1323.port_a.T; AIR0CabiA011006003.port.T = TC_1322_1333.port_a.T; AIR0CabiA011006003.port.T = TC_756_1322.port_b.T; AIR0CabiA011006003.port.T = TsAIR0CabiA011006003.port.T; TsAIR0CabiA010006003.port.Q_flow + (TC_1320_1321.port_b.Q_flow + (TC_1310_1321.port_b.Q_flow + (TC_1185_1321.port_b.Q_flow + (TC_755_1321.port_b.Q_flow + (AIR0CabiA010006003.port.Q_flow + (TC_1321_1322.port_a.Q_flow + TC_1321_1332.port_a.Q_flow)))))) = 0.0; AIR0CabiA010006003.port.T = TC_1185_1321.port_b.T; AIR0CabiA010006003.port.T = TC_1310_1321.port_b.T; AIR0CabiA010006003.port.T = TC_1320_1321.port_b.T; AIR0CabiA010006003.port.T = TC_1321_1322.port_a.T; AIR0CabiA010006003.port.T = TC_1321_1332.port_a.T; AIR0CabiA010006003.port.T = TC_755_1321.port_b.T; AIR0CabiA010006003.port.T = TsAIR0CabiA010006003.port.T; TsAIR0CabiA009006003.port.Q_flow + (TC_1319_1320.port_b.Q_flow + (TC_1309_1320.port_b.Q_flow + (TC_1184_1320.port_b.Q_flow + (TC_754_1320.port_b.Q_flow + (AIR0CabiA009006003.port.Q_flow + (TC_1320_1321.port_a.Q_flow + TC_1320_1331.port_a.Q_flow)))))) = 0.0; AIR0CabiA009006003.port.T = TC_1184_1320.port_b.T; AIR0CabiA009006003.port.T = TC_1309_1320.port_b.T; AIR0CabiA009006003.port.T = TC_1319_1320.port_b.T; AIR0CabiA009006003.port.T = TC_1320_1321.port_a.T; AIR0CabiA009006003.port.T = TC_1320_1331.port_a.T; AIR0CabiA009006003.port.T = TC_754_1320.port_b.T; AIR0CabiA009006003.port.T = TsAIR0CabiA009006003.port.T; TsAIR0CabiA008006003.port.Q_flow + (TC_1318_1319.port_b.Q_flow + (TC_1308_1319.port_b.Q_flow + (TC_1183_1319.port_b.Q_flow + (TC_753_1319.port_b.Q_flow + (AIR0CabiA008006003.port.Q_flow + (TC_1319_1320.port_a.Q_flow + TC_1319_1330.port_a.Q_flow)))))) = 0.0; AIR0CabiA008006003.port.T = TC_1183_1319.port_b.T; AIR0CabiA008006003.port.T = TC_1308_1319.port_b.T; AIR0CabiA008006003.port.T = TC_1318_1319.port_b.T; AIR0CabiA008006003.port.T = TC_1319_1320.port_a.T; AIR0CabiA008006003.port.T = TC_1319_1330.port_a.T; AIR0CabiA008006003.port.T = TC_753_1319.port_b.T; AIR0CabiA008006003.port.T = TsAIR0CabiA008006003.port.T; TsAIR0CabiA007006003.port.Q_flow + (TC_1317_1318.port_b.Q_flow + (TC_1307_1318.port_b.Q_flow + (TC_752_1318.port_b.Q_flow + (AIR0CabiA007006003.port.Q_flow + (TC_1318_1319.port_a.Q_flow + (TC_1318_1329.port_a.Q_flow + TC_1318_1508.port_a.Q_flow)))))) = 0.0; AIR0CabiA007006003.port.T = TC_1307_1318.port_b.T; AIR0CabiA007006003.port.T = TC_1317_1318.port_b.T; AIR0CabiA007006003.port.T = TC_1318_1319.port_a.T; AIR0CabiA007006003.port.T = TC_1318_1329.port_a.T; AIR0CabiA007006003.port.T = TC_1318_1508.port_a.T; AIR0CabiA007006003.port.T = TC_752_1318.port_b.T; AIR0CabiA007006003.port.T = TsAIR0CabiA007006003.port.T; TsAIR0CabiA006006003.port.Q_flow + (TC_1316_1317.port_b.Q_flow + (TC_1306_1317.port_b.Q_flow + (TC_751_1317.port_b.Q_flow + (AIR0CabiA006006003.port.Q_flow + (TC_1317_1318.port_a.Q_flow + (TC_1317_1328.port_a.Q_flow + TC_1317_1507.port_a.Q_flow)))))) = 0.0; AIR0CabiA006006003.port.T = TC_1306_1317.port_b.T; AIR0CabiA006006003.port.T = TC_1316_1317.port_b.T; AIR0CabiA006006003.port.T = TC_1317_1318.port_a.T; AIR0CabiA006006003.port.T = TC_1317_1328.port_a.T; AIR0CabiA006006003.port.T = TC_1317_1507.port_a.T; AIR0CabiA006006003.port.T = TC_751_1317.port_b.T; AIR0CabiA006006003.port.T = TsAIR0CabiA006006003.port.T; TsAIR0CabiA005006003.port.Q_flow + (TC_1315_1316.port_b.Q_flow + (TC_1305_1316.port_b.Q_flow + (TC_750_1316.port_b.Q_flow + (AIR0CabiA005006003.port.Q_flow + (TC_1316_1317.port_a.Q_flow + (TC_1316_1327.port_a.Q_flow + TC_1316_1506.port_a.Q_flow)))))) = 0.0; AIR0CabiA005006003.port.T = TC_1305_1316.port_b.T; AIR0CabiA005006003.port.T = TC_1315_1316.port_b.T; AIR0CabiA005006003.port.T = TC_1316_1317.port_a.T; AIR0CabiA005006003.port.T = TC_1316_1327.port_a.T; AIR0CabiA005006003.port.T = TC_1316_1506.port_a.T; AIR0CabiA005006003.port.T = TC_750_1316.port_b.T; AIR0CabiA005006003.port.T = TsAIR0CabiA005006003.port.T; TsAIR0CabiA004006003.port.Q_flow + (TC_1314_1315.port_b.Q_flow + (TC_1304_1315.port_b.Q_flow + (TC_749_1315.port_b.Q_flow + (AIR0CabiA004006003.port.Q_flow + (TC_1315_1316.port_a.Q_flow + (TC_1315_1326.port_a.Q_flow + TC_1315_1505.port_a.Q_flow)))))) = 0.0; AIR0CabiA004006003.port.T = TC_1304_1315.port_b.T; AIR0CabiA004006003.port.T = TC_1314_1315.port_b.T; AIR0CabiA004006003.port.T = TC_1315_1316.port_a.T; AIR0CabiA004006003.port.T = TC_1315_1326.port_a.T; AIR0CabiA004006003.port.T = TC_1315_1505.port_a.T; AIR0CabiA004006003.port.T = TC_749_1315.port_b.T; AIR0CabiA004006003.port.T = TsAIR0CabiA004006003.port.T; TsAIR0CabiA003006003.port.Q_flow + (TC_1313_1314.port_b.Q_flow + (TC_1303_1314.port_b.Q_flow + (TC_1182_1314.port_b.Q_flow + (AIR0CabiA003006003.port.Q_flow + (TC_1314_1315.port_a.Q_flow + (TC_1314_1325.port_a.Q_flow + TC_1314_1416.port_a.Q_flow)))))) = 0.0; AIR0CabiA003006003.port.T = TC_1182_1314.port_b.T; AIR0CabiA003006003.port.T = TC_1303_1314.port_b.T; AIR0CabiA003006003.port.T = TC_1313_1314.port_b.T; AIR0CabiA003006003.port.T = TC_1314_1315.port_a.T; AIR0CabiA003006003.port.T = TC_1314_1325.port_a.T; AIR0CabiA003006003.port.T = TC_1314_1416.port_a.T; AIR0CabiA003006003.port.T = TsAIR0CabiA003006003.port.T; TsAIR0CabiA002006003.port.Q_flow + (TC_1302_1313.port_b.Q_flow + (TC_1181_1313.port_b.Q_flow + (TC_391_1313.port_b.Q_flow + (AIR0CabiA002006003.port.Q_flow + (TC_1313_1314.port_a.Q_flow + (TC_1313_1324.port_a.Q_flow + TC_1313_1415.port_a.Q_flow)))))) = 0.0; AIR0CabiA002006003.port.T = TC_1181_1313.port_b.T; AIR0CabiA002006003.port.T = TC_1302_1313.port_b.T; AIR0CabiA002006003.port.T = TC_1313_1314.port_a.T; AIR0CabiA002006003.port.T = TC_1313_1324.port_a.T; AIR0CabiA002006003.port.T = TC_1313_1415.port_a.T; AIR0CabiA002006003.port.T = TC_391_1313.port_b.T; AIR0CabiA002006003.port.T = TsAIR0CabiA002006003.port.T; TsAIR0CabiA012005003.port.Q_flow + (TC_1311_1312.port_b.Q_flow + (TC_1301_1312.port_b.Q_flow + (TC_1180_1312.port_b.Q_flow + (TC_390_1312.port_b.Q_flow + (AIR0CabiA012005003.port.Q_flow + (TC_1312_1323.port_a.Q_flow + TC_1312_1414.port_a.Q_flow)))))) = 0.0; AIR0CabiA012005003.port.T = TC_1180_1312.port_b.T; AIR0CabiA012005003.port.T = TC_1301_1312.port_b.T; AIR0CabiA012005003.port.T = TC_1311_1312.port_b.T; AIR0CabiA012005003.port.T = TC_1312_1323.port_a.T; AIR0CabiA012005003.port.T = TC_1312_1414.port_a.T; AIR0CabiA012005003.port.T = TC_390_1312.port_b.T; AIR0CabiA012005003.port.T = TsAIR0CabiA012005003.port.T; TsAIR0CabiA011005003.port.Q_flow + (TC_1310_1311.port_b.Q_flow + (TC_1300_1311.port_b.Q_flow + (TC_1179_1311.port_b.Q_flow + (TC_748_1311.port_b.Q_flow + (AIR0CabiA011005003.port.Q_flow + (TC_1311_1312.port_a.Q_flow + TC_1311_1322.port_a.Q_flow)))))) = 0.0; AIR0CabiA011005003.port.T = TC_1179_1311.port_b.T; AIR0CabiA011005003.port.T = TC_1300_1311.port_b.T; AIR0CabiA011005003.port.T = TC_1310_1311.port_b.T; AIR0CabiA011005003.port.T = TC_1311_1312.port_a.T; AIR0CabiA011005003.port.T = TC_1311_1322.port_a.T; AIR0CabiA011005003.port.T = TC_748_1311.port_b.T; AIR0CabiA011005003.port.T = TsAIR0CabiA011005003.port.T; TsAIR0CabiA010005003.port.Q_flow + (TC_1309_1310.port_b.Q_flow + (TC_1299_1310.port_b.Q_flow + (TC_1178_1310.port_b.Q_flow + (TC_747_1310.port_b.Q_flow + (AIR0CabiA010005003.port.Q_flow + (TC_1310_1311.port_a.Q_flow + TC_1310_1321.port_a.Q_flow)))))) = 0.0; AIR0CabiA010005003.port.T = TC_1178_1310.port_b.T; AIR0CabiA010005003.port.T = TC_1299_1310.port_b.T; AIR0CabiA010005003.port.T = TC_1309_1310.port_b.T; AIR0CabiA010005003.port.T = TC_1310_1311.port_a.T; AIR0CabiA010005003.port.T = TC_1310_1321.port_a.T; AIR0CabiA010005003.port.T = TC_747_1310.port_b.T; AIR0CabiA010005003.port.T = TsAIR0CabiA010005003.port.T; TsAIR0CabiA009005003.port.Q_flow + (TC_1308_1309.port_b.Q_flow + (TC_1298_1309.port_b.Q_flow + (TC_1177_1309.port_b.Q_flow + (TC_746_1309.port_b.Q_flow + (AIR0CabiA009005003.port.Q_flow + (TC_1309_1310.port_a.Q_flow + TC_1309_1320.port_a.Q_flow)))))) = 0.0; AIR0CabiA009005003.port.T = TC_1177_1309.port_b.T; AIR0CabiA009005003.port.T = TC_1298_1309.port_b.T; AIR0CabiA009005003.port.T = TC_1308_1309.port_b.T; AIR0CabiA009005003.port.T = TC_1309_1310.port_a.T; AIR0CabiA009005003.port.T = TC_1309_1320.port_a.T; AIR0CabiA009005003.port.T = TC_746_1309.port_b.T; AIR0CabiA009005003.port.T = TsAIR0CabiA009005003.port.T; TsAIR0CabiA008005003.port.Q_flow + (TC_1307_1308.port_b.Q_flow + (TC_1297_1308.port_b.Q_flow + (TC_1176_1308.port_b.Q_flow + (TC_745_1308.port_b.Q_flow + (AIR0CabiA008005003.port.Q_flow + (TC_1308_1309.port_a.Q_flow + TC_1308_1319.port_a.Q_flow)))))) = 0.0; AIR0CabiA008005003.port.T = TC_1176_1308.port_b.T; AIR0CabiA008005003.port.T = TC_1297_1308.port_b.T; AIR0CabiA008005003.port.T = TC_1307_1308.port_b.T; AIR0CabiA008005003.port.T = TC_1308_1309.port_a.T; AIR0CabiA008005003.port.T = TC_1308_1319.port_a.T; AIR0CabiA008005003.port.T = TC_745_1308.port_b.T; AIR0CabiA008005003.port.T = TsAIR0CabiA008005003.port.T; TsAIR0CabiA007005003.port.Q_flow + (TC_1306_1307.port_b.Q_flow + (TC_1296_1307.port_b.Q_flow + (TC_744_1307.port_b.Q_flow + (AIR0CabiA007005003.port.Q_flow + (TC_1307_1308.port_a.Q_flow + (TC_1307_1318.port_a.Q_flow + TC_1307_1504.port_a.Q_flow)))))) = 0.0; AIR0CabiA007005003.port.T = TC_1296_1307.port_b.T; AIR0CabiA007005003.port.T = TC_1306_1307.port_b.T; AIR0CabiA007005003.port.T = TC_1307_1308.port_a.T; AIR0CabiA007005003.port.T = TC_1307_1318.port_a.T; AIR0CabiA007005003.port.T = TC_1307_1504.port_a.T; AIR0CabiA007005003.port.T = TC_744_1307.port_b.T; AIR0CabiA007005003.port.T = TsAIR0CabiA007005003.port.T; TsAIR0CabiA006005003.port.Q_flow + (TC_1305_1306.port_b.Q_flow + (TC_1295_1306.port_b.Q_flow + (TC_743_1306.port_b.Q_flow + (AIR0CabiA006005003.port.Q_flow + (TC_1306_1307.port_a.Q_flow + (TC_1306_1317.port_a.Q_flow + TC_1306_1503.port_a.Q_flow)))))) = 0.0; AIR0CabiA006005003.port.T = TC_1295_1306.port_b.T; AIR0CabiA006005003.port.T = TC_1305_1306.port_b.T; AIR0CabiA006005003.port.T = TC_1306_1307.port_a.T; AIR0CabiA006005003.port.T = TC_1306_1317.port_a.T; AIR0CabiA006005003.port.T = TC_1306_1503.port_a.T; AIR0CabiA006005003.port.T = TC_743_1306.port_b.T; AIR0CabiA006005003.port.T = TsAIR0CabiA006005003.port.T; TsAIR0CabiA005005003.port.Q_flow + (TC_1304_1305.port_b.Q_flow + (TC_1294_1305.port_b.Q_flow + (TC_742_1305.port_b.Q_flow + (AIR0CabiA005005003.port.Q_flow + (TC_1305_1306.port_a.Q_flow + (TC_1305_1316.port_a.Q_flow + TC_1305_1502.port_a.Q_flow)))))) = 0.0; AIR0CabiA005005003.port.T = TC_1294_1305.port_b.T; AIR0CabiA005005003.port.T = TC_1304_1305.port_b.T; AIR0CabiA005005003.port.T = TC_1305_1306.port_a.T; AIR0CabiA005005003.port.T = TC_1305_1316.port_a.T; AIR0CabiA005005003.port.T = TC_1305_1502.port_a.T; AIR0CabiA005005003.port.T = TC_742_1305.port_b.T; AIR0CabiA005005003.port.T = TsAIR0CabiA005005003.port.T; TsAIR0CabiA004005003.port.Q_flow + (TC_1303_1304.port_b.Q_flow + (TC_1293_1304.port_b.Q_flow + (TC_741_1304.port_b.Q_flow + (AIR0CabiA004005003.port.Q_flow + (TC_1304_1305.port_a.Q_flow + (TC_1304_1315.port_a.Q_flow + TC_1304_1501.port_a.Q_flow)))))) = 0.0; AIR0CabiA004005003.port.T = TC_1293_1304.port_b.T; AIR0CabiA004005003.port.T = TC_1303_1304.port_b.T; AIR0CabiA004005003.port.T = TC_1304_1305.port_a.T; AIR0CabiA004005003.port.T = TC_1304_1315.port_a.T; AIR0CabiA004005003.port.T = TC_1304_1501.port_a.T; AIR0CabiA004005003.port.T = TC_741_1304.port_b.T; AIR0CabiA004005003.port.T = TsAIR0CabiA004005003.port.T; TsAIR0CabiA003005003.port.Q_flow + (TC_1302_1303.port_b.Q_flow + (TC_1292_1303.port_b.Q_flow + (TC_1175_1303.port_b.Q_flow + (AIR0CabiA003005003.port.Q_flow + (TC_1303_1304.port_a.Q_flow + (TC_1303_1314.port_a.Q_flow + TC_1303_1465.port_a.Q_flow)))))) = 0.0; AIR0CabiA003005003.port.T = TC_1175_1303.port_b.T; AIR0CabiA003005003.port.T = TC_1292_1303.port_b.T; AIR0CabiA003005003.port.T = TC_1302_1303.port_b.T; AIR0CabiA003005003.port.T = TC_1303_1304.port_a.T; AIR0CabiA003005003.port.T = TC_1303_1314.port_a.T; AIR0CabiA003005003.port.T = TC_1303_1465.port_a.T; AIR0CabiA003005003.port.T = TsAIR0CabiA003005003.port.T; TsAIR0CabiA002005003.port.Q_flow + (TC_1291_1302.port_b.Q_flow + (TC_1174_1302.port_b.Q_flow + (TC_389_1302.port_b.Q_flow + (AIR0CabiA002005003.port.Q_flow + (TC_1302_1303.port_a.Q_flow + (TC_1302_1313.port_a.Q_flow + TC_1302_1464.port_a.Q_flow)))))) = 0.0; AIR0CabiA002005003.port.T = TC_1174_1302.port_b.T; AIR0CabiA002005003.port.T = TC_1291_1302.port_b.T; AIR0CabiA002005003.port.T = TC_1302_1303.port_a.T; AIR0CabiA002005003.port.T = TC_1302_1313.port_a.T; AIR0CabiA002005003.port.T = TC_1302_1464.port_a.T; AIR0CabiA002005003.port.T = TC_389_1302.port_b.T; AIR0CabiA002005003.port.T = TsAIR0CabiA002005003.port.T; TsAIR0CabiA012004003.port.Q_flow + (TC_1300_1301.port_b.Q_flow + (TC_1290_1301.port_b.Q_flow + (TC_1173_1301.port_b.Q_flow + (TC_388_1301.port_b.Q_flow + (AIR0CabiA012004003.port.Q_flow + (TC_1301_1312.port_a.Q_flow + TC_1301_1463.port_a.Q_flow)))))) = 0.0; AIR0CabiA012004003.port.T = TC_1173_1301.port_b.T; AIR0CabiA012004003.port.T = TC_1290_1301.port_b.T; AIR0CabiA012004003.port.T = TC_1300_1301.port_b.T; AIR0CabiA012004003.port.T = TC_1301_1312.port_a.T; AIR0CabiA012004003.port.T = TC_1301_1463.port_a.T; AIR0CabiA012004003.port.T = TC_388_1301.port_b.T; AIR0CabiA012004003.port.T = TsAIR0CabiA012004003.port.T; TsAIR0CabiA011004003.port.Q_flow + (TC_1299_1300.port_b.Q_flow + (TC_1289_1300.port_b.Q_flow + (TC_1172_1300.port_b.Q_flow + (TC_820_1300.port_b.Q_flow + (AIR0CabiA011004003.port.Q_flow + (TC_1300_1301.port_a.Q_flow + TC_1300_1311.port_a.Q_flow)))))) = 0.0; AIR0CabiA011004003.port.T = TC_1172_1300.port_b.T; AIR0CabiA011004003.port.T = TC_1289_1300.port_b.T; AIR0CabiA011004003.port.T = TC_1299_1300.port_b.T; AIR0CabiA011004003.port.T = TC_1300_1301.port_a.T; AIR0CabiA011004003.port.T = TC_1300_1311.port_a.T; AIR0CabiA011004003.port.T = TC_820_1300.port_b.T; AIR0CabiA011004003.port.T = TsAIR0CabiA011004003.port.T; TsAIR0CabiA010004003.port.Q_flow + (TC_1298_1299.port_b.Q_flow + (TC_1288_1299.port_b.Q_flow + (TC_1171_1299.port_b.Q_flow + (TC_819_1299.port_b.Q_flow + (AIR0CabiA010004003.port.Q_flow + (TC_1299_1300.port_a.Q_flow + TC_1299_1310.port_a.Q_flow)))))) = 0.0; AIR0CabiA010004003.port.T = TC_1171_1299.port_b.T; AIR0CabiA010004003.port.T = TC_1288_1299.port_b.T; AIR0CabiA010004003.port.T = TC_1298_1299.port_b.T; AIR0CabiA010004003.port.T = TC_1299_1300.port_a.T; AIR0CabiA010004003.port.T = TC_1299_1310.port_a.T; AIR0CabiA010004003.port.T = TC_819_1299.port_b.T; AIR0CabiA010004003.port.T = TsAIR0CabiA010004003.port.T; TsAIR0CabiA009004003.port.Q_flow + (TC_1297_1298.port_b.Q_flow + (TC_1287_1298.port_b.Q_flow + (TC_1170_1298.port_b.Q_flow + (TC_818_1298.port_b.Q_flow + (AIR0CabiA009004003.port.Q_flow + (TC_1298_1299.port_a.Q_flow + TC_1298_1309.port_a.Q_flow)))))) = 0.0; AIR0CabiA009004003.port.T = TC_1170_1298.port_b.T; AIR0CabiA009004003.port.T = TC_1287_1298.port_b.T; AIR0CabiA009004003.port.T = TC_1297_1298.port_b.T; AIR0CabiA009004003.port.T = TC_1298_1299.port_a.T; AIR0CabiA009004003.port.T = TC_1298_1309.port_a.T; AIR0CabiA009004003.port.T = TC_818_1298.port_b.T; AIR0CabiA009004003.port.T = TsAIR0CabiA009004003.port.T; TsAIR0CabiA008004003.port.Q_flow + (TC_1296_1297.port_b.Q_flow + (TC_1286_1297.port_b.Q_flow + (TC_1169_1297.port_b.Q_flow + (TC_817_1297.port_b.Q_flow + (AIR0CabiA008004003.port.Q_flow + (TC_1297_1298.port_a.Q_flow + TC_1297_1308.port_a.Q_flow)))))) = 0.0; AIR0CabiA008004003.port.T = TC_1169_1297.port_b.T; AIR0CabiA008004003.port.T = TC_1286_1297.port_b.T; AIR0CabiA008004003.port.T = TC_1296_1297.port_b.T; AIR0CabiA008004003.port.T = TC_1297_1298.port_a.T; AIR0CabiA008004003.port.T = TC_1297_1308.port_a.T; AIR0CabiA008004003.port.T = TC_817_1297.port_b.T; AIR0CabiA008004003.port.T = TsAIR0CabiA008004003.port.T; TsAIR0CabiA007004003.port.Q_flow + (TC_1295_1296.port_b.Q_flow + (TC_1285_1296.port_b.Q_flow + (TC_816_1296.port_b.Q_flow + (AIR0CabiA007004003.port.Q_flow + (TC_1296_1297.port_a.Q_flow + (TC_1296_1307.port_a.Q_flow + TC_1296_1500.port_a.Q_flow)))))) = 0.0; AIR0CabiA007004003.port.T = TC_1285_1296.port_b.T; AIR0CabiA007004003.port.T = TC_1295_1296.port_b.T; AIR0CabiA007004003.port.T = TC_1296_1297.port_a.T; AIR0CabiA007004003.port.T = TC_1296_1307.port_a.T; AIR0CabiA007004003.port.T = TC_1296_1500.port_a.T; AIR0CabiA007004003.port.T = TC_816_1296.port_b.T; AIR0CabiA007004003.port.T = TsAIR0CabiA007004003.port.T; TsAIR0CabiA006004003.port.Q_flow + (TC_1294_1295.port_b.Q_flow + (TC_1284_1295.port_b.Q_flow + (TC_815_1295.port_b.Q_flow + (AIR0CabiA006004003.port.Q_flow + (TC_1295_1296.port_a.Q_flow + (TC_1295_1306.port_a.Q_flow + TC_1295_1499.port_a.Q_flow)))))) = 0.0; AIR0CabiA006004003.port.T = TC_1284_1295.port_b.T; AIR0CabiA006004003.port.T = TC_1294_1295.port_b.T; AIR0CabiA006004003.port.T = TC_1295_1296.port_a.T; AIR0CabiA006004003.port.T = TC_1295_1306.port_a.T; AIR0CabiA006004003.port.T = TC_1295_1499.port_a.T; AIR0CabiA006004003.port.T = TC_815_1295.port_b.T; AIR0CabiA006004003.port.T = TsAIR0CabiA006004003.port.T; TsAIR0CabiA005004003.port.Q_flow + (TC_1293_1294.port_b.Q_flow + (TC_1283_1294.port_b.Q_flow + (TC_814_1294.port_b.Q_flow + (AIR0CabiA005004003.port.Q_flow + (TC_1294_1295.port_a.Q_flow + (TC_1294_1305.port_a.Q_flow + TC_1294_1498.port_a.Q_flow)))))) = 0.0; AIR0CabiA005004003.port.T = TC_1283_1294.port_b.T; AIR0CabiA005004003.port.T = TC_1293_1294.port_b.T; AIR0CabiA005004003.port.T = TC_1294_1295.port_a.T; AIR0CabiA005004003.port.T = TC_1294_1305.port_a.T; AIR0CabiA005004003.port.T = TC_1294_1498.port_a.T; AIR0CabiA005004003.port.T = TC_814_1294.port_b.T; AIR0CabiA005004003.port.T = TsAIR0CabiA005004003.port.T; TsAIR0CabiA004004003.port.Q_flow + (TC_1292_1293.port_b.Q_flow + (TC_1282_1293.port_b.Q_flow + (TC_813_1293.port_b.Q_flow + (AIR0CabiA004004003.port.Q_flow + (TC_1293_1294.port_a.Q_flow + (TC_1293_1304.port_a.Q_flow + TC_1293_1497.port_a.Q_flow)))))) = 0.0; AIR0CabiA004004003.port.T = TC_1282_1293.port_b.T; AIR0CabiA004004003.port.T = TC_1292_1293.port_b.T; AIR0CabiA004004003.port.T = TC_1293_1294.port_a.T; AIR0CabiA004004003.port.T = TC_1293_1304.port_a.T; AIR0CabiA004004003.port.T = TC_1293_1497.port_a.T; AIR0CabiA004004003.port.T = TC_813_1293.port_b.T; AIR0CabiA004004003.port.T = TsAIR0CabiA004004003.port.T; TsAIR0CabiA003004003.port.Q_flow + (TC_1291_1292.port_b.Q_flow + (TC_1281_1292.port_b.Q_flow + (TC_1168_1292.port_b.Q_flow + (AIR0CabiA003004003.port.Q_flow + (TC_1292_1293.port_a.Q_flow + (TC_1292_1303.port_a.Q_flow + TC_1292_1462.port_a.Q_flow)))))) = 0.0; AIR0CabiA003004003.port.T = TC_1168_1292.port_b.T; AIR0CabiA003004003.port.T = TC_1281_1292.port_b.T; AIR0CabiA003004003.port.T = TC_1291_1292.port_b.T; AIR0CabiA003004003.port.T = TC_1292_1293.port_a.T; AIR0CabiA003004003.port.T = TC_1292_1303.port_a.T; AIR0CabiA003004003.port.T = TC_1292_1462.port_a.T; AIR0CabiA003004003.port.T = TsAIR0CabiA003004003.port.T; TsAIR0CabiA002004003.port.Q_flow + (TC_1280_1291.port_b.Q_flow + (TC_1167_1291.port_b.Q_flow + (TC_387_1291.port_b.Q_flow + (AIR0CabiA002004003.port.Q_flow + (TC_1291_1292.port_a.Q_flow + (TC_1291_1302.port_a.Q_flow + TC_1291_1461.port_a.Q_flow)))))) = 0.0; AIR0CabiA002004003.port.T = TC_1167_1291.port_b.T; AIR0CabiA002004003.port.T = TC_1280_1291.port_b.T; AIR0CabiA002004003.port.T = TC_1291_1292.port_a.T; AIR0CabiA002004003.port.T = TC_1291_1302.port_a.T; AIR0CabiA002004003.port.T = TC_1291_1461.port_a.T; AIR0CabiA002004003.port.T = TC_387_1291.port_b.T; AIR0CabiA002004003.port.T = TsAIR0CabiA002004003.port.T; TsAIR0CabiA012003003.port.Q_flow + (TC_1289_1290.port_b.Q_flow + (TC_1279_1290.port_b.Q_flow + (TC_1166_1290.port_b.Q_flow + (TC_386_1290.port_b.Q_flow + (AIR0CabiA012003003.port.Q_flow + (TC_1290_1301.port_a.Q_flow + TC_1290_1476.port_a.Q_flow)))))) = 0.0; AIR0CabiA012003003.port.T = TC_1166_1290.port_b.T; AIR0CabiA012003003.port.T = TC_1279_1290.port_b.T; AIR0CabiA012003003.port.T = TC_1289_1290.port_b.T; AIR0CabiA012003003.port.T = TC_1290_1301.port_a.T; AIR0CabiA012003003.port.T = TC_1290_1476.port_a.T; AIR0CabiA012003003.port.T = TC_386_1290.port_b.T; AIR0CabiA012003003.port.T = TsAIR0CabiA012003003.port.T; TsAIR0CabiA011003003.port.Q_flow + (TC_1288_1289.port_b.Q_flow + (TC_1278_1289.port_b.Q_flow + (TC_1165_1289.port_b.Q_flow + (AIR0CabiA011003003.port.Q_flow + (TC_1289_1290.port_a.Q_flow + (TC_1289_1300.port_a.Q_flow + TC_1289_1475.port_a.Q_flow)))))) = 0.0; AIR0CabiA011003003.port.T = TC_1165_1289.port_b.T; AIR0CabiA011003003.port.T = TC_1278_1289.port_b.T; AIR0CabiA011003003.port.T = TC_1288_1289.port_b.T; AIR0CabiA011003003.port.T = TC_1289_1290.port_a.T; AIR0CabiA011003003.port.T = TC_1289_1300.port_a.T; AIR0CabiA011003003.port.T = TC_1289_1475.port_a.T; AIR0CabiA011003003.port.T = TsAIR0CabiA011003003.port.T; TsAIR0CabiA010003003.port.Q_flow + (TC_1287_1288.port_b.Q_flow + (TC_1277_1288.port_b.Q_flow + (TC_1164_1288.port_b.Q_flow + (AIR0CabiA010003003.port.Q_flow + (TC_1288_1289.port_a.Q_flow + (TC_1288_1299.port_a.Q_flow + TC_1288_1474.port_a.Q_flow)))))) = 0.0; AIR0CabiA010003003.port.T = TC_1164_1288.port_b.T; AIR0CabiA010003003.port.T = TC_1277_1288.port_b.T; AIR0CabiA010003003.port.T = TC_1287_1288.port_b.T; AIR0CabiA010003003.port.T = TC_1288_1289.port_a.T; AIR0CabiA010003003.port.T = TC_1288_1299.port_a.T; AIR0CabiA010003003.port.T = TC_1288_1474.port_a.T; AIR0CabiA010003003.port.T = TsAIR0CabiA010003003.port.T; TsAIR0CabiA009003003.port.Q_flow + (TC_1286_1287.port_b.Q_flow + (TC_1276_1287.port_b.Q_flow + (TC_1163_1287.port_b.Q_flow + (AIR0CabiA009003003.port.Q_flow + (TC_1287_1288.port_a.Q_flow + (TC_1287_1298.port_a.Q_flow + TC_1287_1473.port_a.Q_flow)))))) = 0.0; AIR0CabiA009003003.port.T = TC_1163_1287.port_b.T; AIR0CabiA009003003.port.T = TC_1276_1287.port_b.T; AIR0CabiA009003003.port.T = TC_1286_1287.port_b.T; AIR0CabiA009003003.port.T = TC_1287_1288.port_a.T; AIR0CabiA009003003.port.T = TC_1287_1298.port_a.T; AIR0CabiA009003003.port.T = TC_1287_1473.port_a.T; AIR0CabiA009003003.port.T = TsAIR0CabiA009003003.port.T; TsAIR0CabiA008003003.port.Q_flow + (TC_1285_1286.port_b.Q_flow + (TC_1275_1286.port_b.Q_flow + (TC_1162_1286.port_b.Q_flow + (AIR0CabiA008003003.port.Q_flow + (TC_1286_1287.port_a.Q_flow + (TC_1286_1297.port_a.Q_flow + TC_1286_1472.port_a.Q_flow)))))) = 0.0; AIR0CabiA008003003.port.T = TC_1162_1286.port_b.T; AIR0CabiA008003003.port.T = TC_1275_1286.port_b.T; AIR0CabiA008003003.port.T = TC_1285_1286.port_b.T; AIR0CabiA008003003.port.T = TC_1286_1287.port_a.T; AIR0CabiA008003003.port.T = TC_1286_1297.port_a.T; AIR0CabiA008003003.port.T = TC_1286_1472.port_a.T; AIR0CabiA008003003.port.T = TsAIR0CabiA008003003.port.T; TsAIR0CabiA007003003.port.Q_flow + (TC_1284_1285.port_b.Q_flow + (TC_1274_1285.port_b.Q_flow + (TC_1161_1285.port_b.Q_flow + (AIR0CabiA007003003.port.Q_flow + (TC_1285_1286.port_a.Q_flow + (TC_1285_1296.port_a.Q_flow + TC_1285_1471.port_a.Q_flow)))))) = 0.0; AIR0CabiA007003003.port.T = TC_1161_1285.port_b.T; AIR0CabiA007003003.port.T = TC_1274_1285.port_b.T; AIR0CabiA007003003.port.T = TC_1284_1285.port_b.T; AIR0CabiA007003003.port.T = TC_1285_1286.port_a.T; AIR0CabiA007003003.port.T = TC_1285_1296.port_a.T; AIR0CabiA007003003.port.T = TC_1285_1471.port_a.T; AIR0CabiA007003003.port.T = TsAIR0CabiA007003003.port.T; TsAIR0CabiA006003003.port.Q_flow + (TC_1283_1284.port_b.Q_flow + (TC_1273_1284.port_b.Q_flow + (TC_1160_1284.port_b.Q_flow + (AIR0CabiA006003003.port.Q_flow + (TC_1284_1285.port_a.Q_flow + (TC_1284_1295.port_a.Q_flow + TC_1284_1470.port_a.Q_flow)))))) = 0.0; AIR0CabiA006003003.port.T = TC_1160_1284.port_b.T; AIR0CabiA006003003.port.T = TC_1273_1284.port_b.T; AIR0CabiA006003003.port.T = TC_1283_1284.port_b.T; AIR0CabiA006003003.port.T = TC_1284_1285.port_a.T; AIR0CabiA006003003.port.T = TC_1284_1295.port_a.T; AIR0CabiA006003003.port.T = TC_1284_1470.port_a.T; AIR0CabiA006003003.port.T = TsAIR0CabiA006003003.port.T; TsAIR0CabiA005003003.port.Q_flow + (TC_1282_1283.port_b.Q_flow + (TC_1272_1283.port_b.Q_flow + (TC_1159_1283.port_b.Q_flow + (AIR0CabiA005003003.port.Q_flow + (TC_1283_1284.port_a.Q_flow + (TC_1283_1294.port_a.Q_flow + TC_1283_1469.port_a.Q_flow)))))) = 0.0; AIR0CabiA005003003.port.T = TC_1159_1283.port_b.T; AIR0CabiA005003003.port.T = TC_1272_1283.port_b.T; AIR0CabiA005003003.port.T = TC_1282_1283.port_b.T; AIR0CabiA005003003.port.T = TC_1283_1284.port_a.T; AIR0CabiA005003003.port.T = TC_1283_1294.port_a.T; AIR0CabiA005003003.port.T = TC_1283_1469.port_a.T; AIR0CabiA005003003.port.T = TsAIR0CabiA005003003.port.T; TsAIR0CabiA004003003.port.Q_flow + (TC_1281_1282.port_b.Q_flow + (TC_1271_1282.port_b.Q_flow + (TC_1158_1282.port_b.Q_flow + (AIR0CabiA004003003.port.Q_flow + (TC_1282_1283.port_a.Q_flow + (TC_1282_1293.port_a.Q_flow + TC_1282_1468.port_a.Q_flow)))))) = 0.0; AIR0CabiA004003003.port.T = TC_1158_1282.port_b.T; AIR0CabiA004003003.port.T = TC_1271_1282.port_b.T; AIR0CabiA004003003.port.T = TC_1281_1282.port_b.T; AIR0CabiA004003003.port.T = TC_1282_1283.port_a.T; AIR0CabiA004003003.port.T = TC_1282_1293.port_a.T; AIR0CabiA004003003.port.T = TC_1282_1468.port_a.T; AIR0CabiA004003003.port.T = TsAIR0CabiA004003003.port.T; TsAIR0CabiA003003003.port.Q_flow + (TC_1280_1281.port_b.Q_flow + (TC_1270_1281.port_b.Q_flow + (TC_1157_1281.port_b.Q_flow + (AIR0CabiA003003003.port.Q_flow + (TC_1281_1282.port_a.Q_flow + (TC_1281_1292.port_a.Q_flow + TC_1281_1467.port_a.Q_flow)))))) = 0.0; AIR0CabiA003003003.port.T = TC_1157_1281.port_b.T; AIR0CabiA003003003.port.T = TC_1270_1281.port_b.T; AIR0CabiA003003003.port.T = TC_1280_1281.port_b.T; AIR0CabiA003003003.port.T = TC_1281_1282.port_a.T; AIR0CabiA003003003.port.T = TC_1281_1292.port_a.T; AIR0CabiA003003003.port.T = TC_1281_1467.port_a.T; AIR0CabiA003003003.port.T = TsAIR0CabiA003003003.port.T; TsAIR0CabiA002003003.port.Q_flow + (TC_1269_1280.port_b.Q_flow + (TC_1156_1280.port_b.Q_flow + (TC_385_1280.port_b.Q_flow + (AIR0CabiA002003003.port.Q_flow + (TC_1280_1281.port_a.Q_flow + (TC_1280_1291.port_a.Q_flow + TC_1280_1466.port_a.Q_flow)))))) = 0.0; AIR0CabiA002003003.port.T = TC_1156_1280.port_b.T; AIR0CabiA002003003.port.T = TC_1269_1280.port_b.T; AIR0CabiA002003003.port.T = TC_1280_1281.port_a.T; AIR0CabiA002003003.port.T = TC_1280_1291.port_a.T; AIR0CabiA002003003.port.T = TC_1280_1466.port_a.T; AIR0CabiA002003003.port.T = TC_385_1280.port_b.T; AIR0CabiA002003003.port.T = TsAIR0CabiA002003003.port.T; TsAIR0CabiA012002003.port.Q_flow + (TC_1278_1279.port_b.Q_flow + (TC_1155_1279.port_b.Q_flow + (TC_384_1279.port_b.Q_flow + (TC_381_1279.port_b.Q_flow + (AIR0CabiA012002003.port.Q_flow + (TC_1279_1290.port_a.Q_flow + TC_1279_1487.port_a.Q_flow)))))) = 0.0; AIR0CabiA012002003.port.T = TC_1155_1279.port_b.T; AIR0CabiA012002003.port.T = TC_1278_1279.port_b.T; AIR0CabiA012002003.port.T = TC_1279_1290.port_a.T; AIR0CabiA012002003.port.T = TC_1279_1487.port_a.T; AIR0CabiA012002003.port.T = TC_381_1279.port_b.T; AIR0CabiA012002003.port.T = TC_384_1279.port_b.T; AIR0CabiA012002003.port.T = TsAIR0CabiA012002003.port.T; TsAIR0CabiA011002003.port.Q_flow + (TC_1277_1278.port_b.Q_flow + (TC_1154_1278.port_b.Q_flow + (TC_380_1278.port_b.Q_flow + (AIR0CabiA011002003.port.Q_flow + (TC_1278_1279.port_a.Q_flow + (TC_1278_1289.port_a.Q_flow + TC_1278_1486.port_a.Q_flow)))))) = 0.0; AIR0CabiA011002003.port.T = TC_1154_1278.port_b.T; AIR0CabiA011002003.port.T = TC_1277_1278.port_b.T; AIR0CabiA011002003.port.T = TC_1278_1279.port_a.T; AIR0CabiA011002003.port.T = TC_1278_1289.port_a.T; AIR0CabiA011002003.port.T = TC_1278_1486.port_a.T; AIR0CabiA011002003.port.T = TC_380_1278.port_b.T; AIR0CabiA011002003.port.T = TsAIR0CabiA011002003.port.T; TsAIR0CabiA010002003.port.Q_flow + (TC_1276_1277.port_b.Q_flow + (TC_1153_1277.port_b.Q_flow + (TC_379_1277.port_b.Q_flow + (AIR0CabiA010002003.port.Q_flow + (TC_1277_1278.port_a.Q_flow + (TC_1277_1288.port_a.Q_flow + TC_1277_1485.port_a.Q_flow)))))) = 0.0; AIR0CabiA010002003.port.T = TC_1153_1277.port_b.T; AIR0CabiA010002003.port.T = TC_1276_1277.port_b.T; AIR0CabiA010002003.port.T = TC_1277_1278.port_a.T; AIR0CabiA010002003.port.T = TC_1277_1288.port_a.T; AIR0CabiA010002003.port.T = TC_1277_1485.port_a.T; AIR0CabiA010002003.port.T = TC_379_1277.port_b.T; AIR0CabiA010002003.port.T = TsAIR0CabiA010002003.port.T; TsAIR0CabiA009002003.port.Q_flow + (TC_1275_1276.port_b.Q_flow + (TC_1152_1276.port_b.Q_flow + (TC_378_1276.port_b.Q_flow + (AIR0CabiA009002003.port.Q_flow + (TC_1276_1277.port_a.Q_flow + (TC_1276_1287.port_a.Q_flow + TC_1276_1484.port_a.Q_flow)))))) = 0.0; AIR0CabiA009002003.port.T = TC_1152_1276.port_b.T; AIR0CabiA009002003.port.T = TC_1275_1276.port_b.T; AIR0CabiA009002003.port.T = TC_1276_1277.port_a.T; AIR0CabiA009002003.port.T = TC_1276_1287.port_a.T; AIR0CabiA009002003.port.T = TC_1276_1484.port_a.T; AIR0CabiA009002003.port.T = TC_378_1276.port_b.T; AIR0CabiA009002003.port.T = TsAIR0CabiA009002003.port.T; TsAIR0CabiA008002003.port.Q_flow + (TC_1274_1275.port_b.Q_flow + (TC_1151_1275.port_b.Q_flow + (TC_377_1275.port_b.Q_flow + (AIR0CabiA008002003.port.Q_flow + (TC_1275_1276.port_a.Q_flow + (TC_1275_1286.port_a.Q_flow + TC_1275_1483.port_a.Q_flow)))))) = 0.0; AIR0CabiA008002003.port.T = TC_1151_1275.port_b.T; AIR0CabiA008002003.port.T = TC_1274_1275.port_b.T; AIR0CabiA008002003.port.T = TC_1275_1276.port_a.T; AIR0CabiA008002003.port.T = TC_1275_1286.port_a.T; AIR0CabiA008002003.port.T = TC_1275_1483.port_a.T; AIR0CabiA008002003.port.T = TC_377_1275.port_b.T; AIR0CabiA008002003.port.T = TsAIR0CabiA008002003.port.T; TsAIR0CabiA007002003.port.Q_flow + (TC_1273_1274.port_b.Q_flow + (TC_1150_1274.port_b.Q_flow + (TC_376_1274.port_b.Q_flow + (AIR0CabiA007002003.port.Q_flow + (TC_1274_1275.port_a.Q_flow + (TC_1274_1285.port_a.Q_flow + TC_1274_1482.port_a.Q_flow)))))) = 0.0; AIR0CabiA007002003.port.T = TC_1150_1274.port_b.T; AIR0CabiA007002003.port.T = TC_1273_1274.port_b.T; AIR0CabiA007002003.port.T = TC_1274_1275.port_a.T; AIR0CabiA007002003.port.T = TC_1274_1285.port_a.T; AIR0CabiA007002003.port.T = TC_1274_1482.port_a.T; AIR0CabiA007002003.port.T = TC_376_1274.port_b.T; AIR0CabiA007002003.port.T = TsAIR0CabiA007002003.port.T; TsAIR0CabiA006002003.port.Q_flow + (TC_1272_1273.port_b.Q_flow + (TC_1149_1273.port_b.Q_flow + (TC_375_1273.port_b.Q_flow + (AIR0CabiA006002003.port.Q_flow + (TC_1273_1274.port_a.Q_flow + (TC_1273_1284.port_a.Q_flow + TC_1273_1481.port_a.Q_flow)))))) = 0.0; AIR0CabiA006002003.port.T = TC_1149_1273.port_b.T; AIR0CabiA006002003.port.T = TC_1272_1273.port_b.T; AIR0CabiA006002003.port.T = TC_1273_1274.port_a.T; AIR0CabiA006002003.port.T = TC_1273_1284.port_a.T; AIR0CabiA006002003.port.T = TC_1273_1481.port_a.T; AIR0CabiA006002003.port.T = TC_375_1273.port_b.T; AIR0CabiA006002003.port.T = TsAIR0CabiA006002003.port.T; TsAIR0CabiA005002003.port.Q_flow + (TC_1271_1272.port_b.Q_flow + (TC_1148_1272.port_b.Q_flow + (TC_374_1272.port_b.Q_flow + (AIR0CabiA005002003.port.Q_flow + (TC_1272_1273.port_a.Q_flow + (TC_1272_1283.port_a.Q_flow + TC_1272_1480.port_a.Q_flow)))))) = 0.0; AIR0CabiA005002003.port.T = TC_1148_1272.port_b.T; AIR0CabiA005002003.port.T = TC_1271_1272.port_b.T; AIR0CabiA005002003.port.T = TC_1272_1273.port_a.T; AIR0CabiA005002003.port.T = TC_1272_1283.port_a.T; AIR0CabiA005002003.port.T = TC_1272_1480.port_a.T; AIR0CabiA005002003.port.T = TC_374_1272.port_b.T; AIR0CabiA005002003.port.T = TsAIR0CabiA005002003.port.T; TsAIR0CabiA004002003.port.Q_flow + (TC_1270_1271.port_b.Q_flow + (TC_1147_1271.port_b.Q_flow + (TC_373_1271.port_b.Q_flow + (AIR0CabiA004002003.port.Q_flow + (TC_1271_1272.port_a.Q_flow + (TC_1271_1282.port_a.Q_flow + TC_1271_1479.port_a.Q_flow)))))) = 0.0; AIR0CabiA004002003.port.T = TC_1147_1271.port_b.T; AIR0CabiA004002003.port.T = TC_1270_1271.port_b.T; AIR0CabiA004002003.port.T = TC_1271_1272.port_a.T; AIR0CabiA004002003.port.T = TC_1271_1282.port_a.T; AIR0CabiA004002003.port.T = TC_1271_1479.port_a.T; AIR0CabiA004002003.port.T = TC_373_1271.port_b.T; AIR0CabiA004002003.port.T = TsAIR0CabiA004002003.port.T; TsAIR0CabiA003002003.port.Q_flow + (TC_1269_1270.port_b.Q_flow + (TC_1146_1270.port_b.Q_flow + (TC_372_1270.port_b.Q_flow + (AIR0CabiA003002003.port.Q_flow + (TC_1270_1271.port_a.Q_flow + (TC_1270_1281.port_a.Q_flow + TC_1270_1478.port_a.Q_flow)))))) = 0.0; AIR0CabiA003002003.port.T = TC_1146_1270.port_b.T; AIR0CabiA003002003.port.T = TC_1269_1270.port_b.T; AIR0CabiA003002003.port.T = TC_1270_1271.port_a.T; AIR0CabiA003002003.port.T = TC_1270_1281.port_a.T; AIR0CabiA003002003.port.T = TC_1270_1478.port_a.T; AIR0CabiA003002003.port.T = TC_372_1270.port_b.T; AIR0CabiA003002003.port.T = TsAIR0CabiA003002003.port.T; TsAIR0CabiA002002003.port.Q_flow + (TC_1145_1269.port_b.Q_flow + (TC_383_1269.port_b.Q_flow + (TC_371_1269.port_b.Q_flow + (AIR0CabiA002002003.port.Q_flow + (TC_1269_1270.port_a.Q_flow + (TC_1269_1280.port_a.Q_flow + TC_1269_1477.port_a.Q_flow)))))) = 0.0; AIR0CabiA002002003.port.T = TC_1145_1269.port_b.T; AIR0CabiA002002003.port.T = TC_1269_1270.port_a.T; AIR0CabiA002002003.port.T = TC_1269_1280.port_a.T; AIR0CabiA002002003.port.T = TC_1269_1477.port_a.T; AIR0CabiA002002003.port.T = TC_371_1269.port_b.T; AIR0CabiA002002003.port.T = TC_383_1269.port_b.T; AIR0CabiA002002003.port.T = TsAIR0CabiA002002003.port.T; TsAIR0CabiA012015004.port.Q_flow + (TC_1267_1268.port_b.Q_flow + (TC_1257_1268.port_b.Q_flow + (TC_1144_1268.port_b.Q_flow + (TC_368_1268.port_b.Q_flow + (TC_356_1268.port_b.Q_flow + (AIR0CabiA012015004.port.Q_flow + TC_1268_1413.port_a.Q_flow)))))) = 0.0; AIR0CabiA012015004.port.T = TC_1144_1268.port_b.T; AIR0CabiA012015004.port.T = TC_1257_1268.port_b.T; AIR0CabiA012015004.port.T = TC_1267_1268.port_b.T; AIR0CabiA012015004.port.T = TC_1268_1413.port_a.T; AIR0CabiA012015004.port.T = TC_356_1268.port_b.T; AIR0CabiA012015004.port.T = TC_368_1268.port_b.T; AIR0CabiA012015004.port.T = TsAIR0CabiA012015004.port.T; TsAIR0CabiA011015004.port.Q_flow + (TC_1266_1267.port_b.Q_flow + (TC_1256_1267.port_b.Q_flow + (TC_1143_1267.port_b.Q_flow + (TC_367_1267.port_b.Q_flow + (AIR0CabiA011015004.port.Q_flow + (TC_1267_1268.port_a.Q_flow + TC_1267_1412.port_a.Q_flow)))))) = 0.0; AIR0CabiA011015004.port.T = TC_1143_1267.port_b.T; AIR0CabiA011015004.port.T = TC_1256_1267.port_b.T; AIR0CabiA011015004.port.T = TC_1266_1267.port_b.T; AIR0CabiA011015004.port.T = TC_1267_1268.port_a.T; AIR0CabiA011015004.port.T = TC_1267_1412.port_a.T; AIR0CabiA011015004.port.T = TC_367_1267.port_b.T; AIR0CabiA011015004.port.T = TsAIR0CabiA011015004.port.T; TsAIR0CabiA010015004.port.Q_flow + (TC_1265_1266.port_b.Q_flow + (TC_1255_1266.port_b.Q_flow + (TC_1142_1266.port_b.Q_flow + (TC_366_1266.port_b.Q_flow + (AIR0CabiA010015004.port.Q_flow + (TC_1266_1267.port_a.Q_flow + TC_1266_1411.port_a.Q_flow)))))) = 0.0; AIR0CabiA010015004.port.T = TC_1142_1266.port_b.T; AIR0CabiA010015004.port.T = TC_1255_1266.port_b.T; AIR0CabiA010015004.port.T = TC_1265_1266.port_b.T; AIR0CabiA010015004.port.T = TC_1266_1267.port_a.T; AIR0CabiA010015004.port.T = TC_1266_1411.port_a.T; AIR0CabiA010015004.port.T = TC_366_1266.port_b.T; AIR0CabiA010015004.port.T = TsAIR0CabiA010015004.port.T; TsAIR0CabiA009015004.port.Q_flow + (TC_1264_1265.port_b.Q_flow + (TC_1254_1265.port_b.Q_flow + (TC_1141_1265.port_b.Q_flow + (TC_365_1265.port_b.Q_flow + (AIR0CabiA009015004.port.Q_flow + (TC_1265_1266.port_a.Q_flow + TC_1265_1410.port_a.Q_flow)))))) = 0.0; AIR0CabiA009015004.port.T = TC_1141_1265.port_b.T; AIR0CabiA009015004.port.T = TC_1254_1265.port_b.T; AIR0CabiA009015004.port.T = TC_1264_1265.port_b.T; AIR0CabiA009015004.port.T = TC_1265_1266.port_a.T; AIR0CabiA009015004.port.T = TC_1265_1410.port_a.T; AIR0CabiA009015004.port.T = TC_365_1265.port_b.T; AIR0CabiA009015004.port.T = TsAIR0CabiA009015004.port.T; TsAIR0CabiA008015004.port.Q_flow + (TC_1263_1264.port_b.Q_flow + (TC_1253_1264.port_b.Q_flow + (TC_1140_1264.port_b.Q_flow + (TC_364_1264.port_b.Q_flow + (AIR0CabiA008015004.port.Q_flow + (TC_1264_1265.port_a.Q_flow + TC_1264_1409.port_a.Q_flow)))))) = 0.0; AIR0CabiA008015004.port.T = TC_1140_1264.port_b.T; AIR0CabiA008015004.port.T = TC_1253_1264.port_b.T; AIR0CabiA008015004.port.T = TC_1263_1264.port_b.T; AIR0CabiA008015004.port.T = TC_1264_1265.port_a.T; AIR0CabiA008015004.port.T = TC_1264_1409.port_a.T; AIR0CabiA008015004.port.T = TC_364_1264.port_b.T; AIR0CabiA008015004.port.T = TsAIR0CabiA008015004.port.T; TsAIR0CabiA007015004.port.Q_flow + (TC_1262_1263.port_b.Q_flow + (TC_1252_1263.port_b.Q_flow + (TC_1139_1263.port_b.Q_flow + (TC_363_1263.port_b.Q_flow + (AIR0CabiA007015004.port.Q_flow + (TC_1263_1264.port_a.Q_flow + TC_1263_1408.port_a.Q_flow)))))) = 0.0; AIR0CabiA007015004.port.T = TC_1139_1263.port_b.T; AIR0CabiA007015004.port.T = TC_1252_1263.port_b.T; AIR0CabiA007015004.port.T = TC_1262_1263.port_b.T; AIR0CabiA007015004.port.T = TC_1263_1264.port_a.T; AIR0CabiA007015004.port.T = TC_1263_1408.port_a.T; AIR0CabiA007015004.port.T = TC_363_1263.port_b.T; AIR0CabiA007015004.port.T = TsAIR0CabiA007015004.port.T; TsAIR0CabiA006015004.port.Q_flow + (TC_1261_1262.port_b.Q_flow + (TC_1251_1262.port_b.Q_flow + (TC_1138_1262.port_b.Q_flow + (TC_362_1262.port_b.Q_flow + (AIR0CabiA006015004.port.Q_flow + (TC_1262_1263.port_a.Q_flow + TC_1262_1407.port_a.Q_flow)))))) = 0.0; AIR0CabiA006015004.port.T = TC_1138_1262.port_b.T; AIR0CabiA006015004.port.T = TC_1251_1262.port_b.T; AIR0CabiA006015004.port.T = TC_1261_1262.port_b.T; AIR0CabiA006015004.port.T = TC_1262_1263.port_a.T; AIR0CabiA006015004.port.T = TC_1262_1407.port_a.T; AIR0CabiA006015004.port.T = TC_362_1262.port_b.T; AIR0CabiA006015004.port.T = TsAIR0CabiA006015004.port.T; TsAIR0CabiA005015004.port.Q_flow + (TC_1260_1261.port_b.Q_flow + (TC_1250_1261.port_b.Q_flow + (TC_1137_1261.port_b.Q_flow + (TC_361_1261.port_b.Q_flow + (AIR0CabiA005015004.port.Q_flow + (TC_1261_1262.port_a.Q_flow + TC_1261_1406.port_a.Q_flow)))))) = 0.0; AIR0CabiA005015004.port.T = TC_1137_1261.port_b.T; AIR0CabiA005015004.port.T = TC_1250_1261.port_b.T; AIR0CabiA005015004.port.T = TC_1260_1261.port_b.T; AIR0CabiA005015004.port.T = TC_1261_1262.port_a.T; AIR0CabiA005015004.port.T = TC_1261_1406.port_a.T; AIR0CabiA005015004.port.T = TC_361_1261.port_b.T; AIR0CabiA005015004.port.T = TsAIR0CabiA005015004.port.T; TsAIR0CabiA004015004.port.Q_flow + (TC_1259_1260.port_b.Q_flow + (TC_1249_1260.port_b.Q_flow + (TC_1136_1260.port_b.Q_flow + (TC_360_1260.port_b.Q_flow + (AIR0CabiA004015004.port.Q_flow + (TC_1260_1261.port_a.Q_flow + TC_1260_1405.port_a.Q_flow)))))) = 0.0; AIR0CabiA004015004.port.T = TC_1136_1260.port_b.T; AIR0CabiA004015004.port.T = TC_1249_1260.port_b.T; AIR0CabiA004015004.port.T = TC_1259_1260.port_b.T; AIR0CabiA004015004.port.T = TC_1260_1261.port_a.T; AIR0CabiA004015004.port.T = TC_1260_1405.port_a.T; AIR0CabiA004015004.port.T = TC_360_1260.port_b.T; AIR0CabiA004015004.port.T = TsAIR0CabiA004015004.port.T; TsAIR0CabiA003015004.port.Q_flow + (TC_1258_1259.port_b.Q_flow + (TC_1248_1259.port_b.Q_flow + (TC_1135_1259.port_b.Q_flow + (TC_359_1259.port_b.Q_flow + (AIR0CabiA003015004.port.Q_flow + (TC_1259_1260.port_a.Q_flow + TC_1259_1404.port_a.Q_flow)))))) = 0.0; AIR0CabiA003015004.port.T = TC_1135_1259.port_b.T; AIR0CabiA003015004.port.T = TC_1248_1259.port_b.T; AIR0CabiA003015004.port.T = TC_1258_1259.port_b.T; AIR0CabiA003015004.port.T = TC_1259_1260.port_a.T; AIR0CabiA003015004.port.T = TC_1259_1404.port_a.T; AIR0CabiA003015004.port.T = TC_359_1259.port_b.T; AIR0CabiA003015004.port.T = TsAIR0CabiA003015004.port.T; TsAIR0CabiA002015004.port.Q_flow + (TC_1247_1258.port_b.Q_flow + (TC_1134_1258.port_b.Q_flow + (TC_358_1258.port_b.Q_flow + (TC_355_1258.port_b.Q_flow + (AIR0CabiA002015004.port.Q_flow + (TC_1258_1259.port_a.Q_flow + TC_1258_1403.port_a.Q_flow)))))) = 0.0; AIR0CabiA002015004.port.T = TC_1134_1258.port_b.T; AIR0CabiA002015004.port.T = TC_1247_1258.port_b.T; AIR0CabiA002015004.port.T = TC_1258_1259.port_a.T; AIR0CabiA002015004.port.T = TC_1258_1403.port_a.T; AIR0CabiA002015004.port.T = TC_355_1258.port_b.T; AIR0CabiA002015004.port.T = TC_358_1258.port_b.T; AIR0CabiA002015004.port.T = TsAIR0CabiA002015004.port.T; TsAIR0CabiA012014004.port.Q_flow + (TC_1256_1257.port_b.Q_flow + (TC_1246_1257.port_b.Q_flow + (TC_1133_1257.port_b.Q_flow + (TC_354_1257.port_b.Q_flow + (AIR0CabiA012014004.port.Q_flow + (TC_1257_1268.port_a.Q_flow + TC_1257_1402.port_a.Q_flow)))))) = 0.0; AIR0CabiA012014004.port.T = TC_1133_1257.port_b.T; AIR0CabiA012014004.port.T = TC_1246_1257.port_b.T; AIR0CabiA012014004.port.T = TC_1256_1257.port_b.T; AIR0CabiA012014004.port.T = TC_1257_1268.port_a.T; AIR0CabiA012014004.port.T = TC_1257_1402.port_a.T; AIR0CabiA012014004.port.T = TC_354_1257.port_b.T; AIR0CabiA012014004.port.T = TsAIR0CabiA012014004.port.T; TsAIR0CabiA011014004.port.Q_flow + (TC_1255_1256.port_b.Q_flow + (TC_1245_1256.port_b.Q_flow + (AIR0CabiA011014004.port.Q_flow + (TC_1256_1257.port_a.Q_flow + (TC_1256_1267.port_a.Q_flow + (TC_1256_1401.port_a.Q_flow + TC_1256_1562.port_a.Q_flow)))))) = 0.0; AIR0CabiA011014004.port.T = TC_1245_1256.port_b.T; AIR0CabiA011014004.port.T = TC_1255_1256.port_b.T; AIR0CabiA011014004.port.T = TC_1256_1257.port_a.T; AIR0CabiA011014004.port.T = TC_1256_1267.port_a.T; AIR0CabiA011014004.port.T = TC_1256_1401.port_a.T; AIR0CabiA011014004.port.T = TC_1256_1562.port_a.T; AIR0CabiA011014004.port.T = TsAIR0CabiA011014004.port.T; TsAIR0CabiA010014004.port.Q_flow + (TC_1254_1255.port_b.Q_flow + (TC_1244_1255.port_b.Q_flow + (AIR0CabiA010014004.port.Q_flow + (TC_1255_1256.port_a.Q_flow + (TC_1255_1266.port_a.Q_flow + (TC_1255_1400.port_a.Q_flow + TC_1255_1561.port_a.Q_flow)))))) = 0.0; AIR0CabiA010014004.port.T = TC_1244_1255.port_b.T; AIR0CabiA010014004.port.T = TC_1254_1255.port_b.T; AIR0CabiA010014004.port.T = TC_1255_1256.port_a.T; AIR0CabiA010014004.port.T = TC_1255_1266.port_a.T; AIR0CabiA010014004.port.T = TC_1255_1400.port_a.T; AIR0CabiA010014004.port.T = TC_1255_1561.port_a.T; AIR0CabiA010014004.port.T = TsAIR0CabiA010014004.port.T; TsAIR0CabiA009014004.port.Q_flow + (TC_1253_1254.port_b.Q_flow + (TC_1243_1254.port_b.Q_flow + (AIR0CabiA009014004.port.Q_flow + (TC_1254_1255.port_a.Q_flow + (TC_1254_1265.port_a.Q_flow + (TC_1254_1399.port_a.Q_flow + TC_1254_1560.port_a.Q_flow)))))) = 0.0; AIR0CabiA009014004.port.T = TC_1243_1254.port_b.T; AIR0CabiA009014004.port.T = TC_1253_1254.port_b.T; AIR0CabiA009014004.port.T = TC_1254_1255.port_a.T; AIR0CabiA009014004.port.T = TC_1254_1265.port_a.T; AIR0CabiA009014004.port.T = TC_1254_1399.port_a.T; AIR0CabiA009014004.port.T = TC_1254_1560.port_a.T; AIR0CabiA009014004.port.T = TsAIR0CabiA009014004.port.T; TsAIR0CabiA008014004.port.Q_flow + (TC_1252_1253.port_b.Q_flow + (TC_1242_1253.port_b.Q_flow + (AIR0CabiA008014004.port.Q_flow + (TC_1253_1254.port_a.Q_flow + (TC_1253_1264.port_a.Q_flow + (TC_1253_1398.port_a.Q_flow + TC_1253_1559.port_a.Q_flow)))))) = 0.0; AIR0CabiA008014004.port.T = TC_1242_1253.port_b.T; AIR0CabiA008014004.port.T = TC_1252_1253.port_b.T; AIR0CabiA008014004.port.T = TC_1253_1254.port_a.T; AIR0CabiA008014004.port.T = TC_1253_1264.port_a.T; AIR0CabiA008014004.port.T = TC_1253_1398.port_a.T; AIR0CabiA008014004.port.T = TC_1253_1559.port_a.T; AIR0CabiA008014004.port.T = TsAIR0CabiA008014004.port.T; TsAIR0CabiA007014004.port.Q_flow + (TC_1251_1252.port_b.Q_flow + (TC_1241_1252.port_b.Q_flow + (AIR0CabiA007014004.port.Q_flow + (TC_1252_1253.port_a.Q_flow + (TC_1252_1263.port_a.Q_flow + (TC_1252_1397.port_a.Q_flow + TC_1252_1558.port_a.Q_flow)))))) = 0.0; AIR0CabiA007014004.port.T = TC_1241_1252.port_b.T; AIR0CabiA007014004.port.T = TC_1251_1252.port_b.T; AIR0CabiA007014004.port.T = TC_1252_1253.port_a.T; AIR0CabiA007014004.port.T = TC_1252_1263.port_a.T; AIR0CabiA007014004.port.T = TC_1252_1397.port_a.T; AIR0CabiA007014004.port.T = TC_1252_1558.port_a.T; AIR0CabiA007014004.port.T = TsAIR0CabiA007014004.port.T; TsAIR0CabiA006014004.port.Q_flow + (TC_1250_1251.port_b.Q_flow + (AIR0CabiA006014004.port.Q_flow + (TC_1251_1252.port_a.Q_flow + (TC_1251_1262.port_a.Q_flow + (TC_1251_1396.port_a.Q_flow + (TC_1251_1526.port_a.Q_flow + TC_1251_1557.port_a.Q_flow)))))) = 0.0; AIR0CabiA006014004.port.T = TC_1250_1251.port_b.T; AIR0CabiA006014004.port.T = TC_1251_1252.port_a.T; AIR0CabiA006014004.port.T = TC_1251_1262.port_a.T; AIR0CabiA006014004.port.T = TC_1251_1396.port_a.T; AIR0CabiA006014004.port.T = TC_1251_1526.port_a.T; AIR0CabiA006014004.port.T = TC_1251_1557.port_a.T; AIR0CabiA006014004.port.T = TsAIR0CabiA006014004.port.T; TsAIR0CabiA005014004.port.Q_flow + (TC_1249_1250.port_b.Q_flow + (AIR0CabiA005014004.port.Q_flow + (TC_1250_1251.port_a.Q_flow + (TC_1250_1261.port_a.Q_flow + (TC_1250_1395.port_a.Q_flow + (TC_1250_1525.port_a.Q_flow + TC_1250_1556.port_a.Q_flow)))))) = 0.0; AIR0CabiA005014004.port.T = TC_1249_1250.port_b.T; AIR0CabiA005014004.port.T = TC_1250_1251.port_a.T; AIR0CabiA005014004.port.T = TC_1250_1261.port_a.T; AIR0CabiA005014004.port.T = TC_1250_1395.port_a.T; AIR0CabiA005014004.port.T = TC_1250_1525.port_a.T; AIR0CabiA005014004.port.T = TC_1250_1556.port_a.T; AIR0CabiA005014004.port.T = TsAIR0CabiA005014004.port.T; TsAIR0CabiA004014004.port.Q_flow + (TC_1248_1249.port_b.Q_flow + (AIR0CabiA004014004.port.Q_flow + (TC_1249_1250.port_a.Q_flow + (TC_1249_1260.port_a.Q_flow + (TC_1249_1394.port_a.Q_flow + (TC_1249_1524.port_a.Q_flow + TC_1249_1555.port_a.Q_flow)))))) = 0.0; AIR0CabiA004014004.port.T = TC_1248_1249.port_b.T; AIR0CabiA004014004.port.T = TC_1249_1250.port_a.T; AIR0CabiA004014004.port.T = TC_1249_1260.port_a.T; AIR0CabiA004014004.port.T = TC_1249_1394.port_a.T; AIR0CabiA004014004.port.T = TC_1249_1524.port_a.T; AIR0CabiA004014004.port.T = TC_1249_1555.port_a.T; AIR0CabiA004014004.port.T = TsAIR0CabiA004014004.port.T; TsAIR0CabiA003014004.port.Q_flow + (TC_1247_1248.port_b.Q_flow + (TC_1240_1248.port_b.Q_flow + (AIR0CabiA003014004.port.Q_flow + (TC_1248_1249.port_a.Q_flow + (TC_1248_1259.port_a.Q_flow + (TC_1248_1393.port_a.Q_flow + TC_1248_1554.port_a.Q_flow)))))) = 0.0; AIR0CabiA003014004.port.T = TC_1240_1248.port_b.T; AIR0CabiA003014004.port.T = TC_1247_1248.port_b.T; AIR0CabiA003014004.port.T = TC_1248_1249.port_a.T; AIR0CabiA003014004.port.T = TC_1248_1259.port_a.T; AIR0CabiA003014004.port.T = TC_1248_1393.port_a.T; AIR0CabiA003014004.port.T = TC_1248_1554.port_a.T; AIR0CabiA003014004.port.T = TsAIR0CabiA003014004.port.T; TsAIR0CabiA002014004.port.Q_flow + (TC_1239_1247.port_b.Q_flow + (TC_1132_1247.port_b.Q_flow + (TC_353_1247.port_b.Q_flow + (AIR0CabiA002014004.port.Q_flow + (TC_1247_1248.port_a.Q_flow + (TC_1247_1258.port_a.Q_flow + TC_1247_1392.port_a.Q_flow)))))) = 0.0; AIR0CabiA002014004.port.T = TC_1132_1247.port_b.T; AIR0CabiA002014004.port.T = TC_1239_1247.port_b.T; AIR0CabiA002014004.port.T = TC_1247_1248.port_a.T; AIR0CabiA002014004.port.T = TC_1247_1258.port_a.T; AIR0CabiA002014004.port.T = TC_1247_1392.port_a.T; AIR0CabiA002014004.port.T = TC_353_1247.port_b.T; AIR0CabiA002014004.port.T = TsAIR0CabiA002014004.port.T; TsAIR0CabiA012013004.port.Q_flow + (TC_1245_1246.port_b.Q_flow + (TC_1238_1246.port_b.Q_flow + (TC_1131_1246.port_b.Q_flow + (TC_352_1246.port_b.Q_flow + (AIR0CabiA012013004.port.Q_flow + (TC_1246_1257.port_a.Q_flow + TC_1246_1391.port_a.Q_flow)))))) = 0.0; AIR0CabiA012013004.port.T = TC_1131_1246.port_b.T; AIR0CabiA012013004.port.T = TC_1238_1246.port_b.T; AIR0CabiA012013004.port.T = TC_1245_1246.port_b.T; AIR0CabiA012013004.port.T = TC_1246_1257.port_a.T; AIR0CabiA012013004.port.T = TC_1246_1391.port_a.T; AIR0CabiA012013004.port.T = TC_352_1246.port_b.T; AIR0CabiA012013004.port.T = TsAIR0CabiA012013004.port.T; TsAIR0CabiA011013004.port.Q_flow + (TC_1244_1245.port_b.Q_flow + (TC_1237_1245.port_b.Q_flow + (AIR0CabiA011013004.port.Q_flow + (TC_1245_1246.port_a.Q_flow + (TC_1245_1256.port_a.Q_flow + (TC_1245_1390.port_a.Q_flow + TC_1245_1553.port_a.Q_flow)))))) = 0.0; AIR0CabiA011013004.port.T = TC_1237_1245.port_b.T; AIR0CabiA011013004.port.T = TC_1244_1245.port_b.T; AIR0CabiA011013004.port.T = TC_1245_1246.port_a.T; AIR0CabiA011013004.port.T = TC_1245_1256.port_a.T; AIR0CabiA011013004.port.T = TC_1245_1390.port_a.T; AIR0CabiA011013004.port.T = TC_1245_1553.port_a.T; AIR0CabiA011013004.port.T = TsAIR0CabiA011013004.port.T; TsAIR0CabiA010013004.port.Q_flow + (TC_1243_1244.port_b.Q_flow + (TC_1236_1244.port_b.Q_flow + (AIR0CabiA010013004.port.Q_flow + (TC_1244_1245.port_a.Q_flow + (TC_1244_1255.port_a.Q_flow + (TC_1244_1389.port_a.Q_flow + TC_1244_1552.port_a.Q_flow)))))) = 0.0; AIR0CabiA010013004.port.T = TC_1236_1244.port_b.T; AIR0CabiA010013004.port.T = TC_1243_1244.port_b.T; AIR0CabiA010013004.port.T = TC_1244_1245.port_a.T; AIR0CabiA010013004.port.T = TC_1244_1255.port_a.T; AIR0CabiA010013004.port.T = TC_1244_1389.port_a.T; AIR0CabiA010013004.port.T = TC_1244_1552.port_a.T; AIR0CabiA010013004.port.T = TsAIR0CabiA010013004.port.T; TsAIR0CabiA009013004.port.Q_flow + (TC_1242_1243.port_b.Q_flow + (TC_1235_1243.port_b.Q_flow + (AIR0CabiA009013004.port.Q_flow + (TC_1243_1244.port_a.Q_flow + (TC_1243_1254.port_a.Q_flow + (TC_1243_1388.port_a.Q_flow + TC_1243_1551.port_a.Q_flow)))))) = 0.0; AIR0CabiA009013004.port.T = TC_1235_1243.port_b.T; AIR0CabiA009013004.port.T = TC_1242_1243.port_b.T; AIR0CabiA009013004.port.T = TC_1243_1244.port_a.T; AIR0CabiA009013004.port.T = TC_1243_1254.port_a.T; AIR0CabiA009013004.port.T = TC_1243_1388.port_a.T; AIR0CabiA009013004.port.T = TC_1243_1551.port_a.T; AIR0CabiA009013004.port.T = TsAIR0CabiA009013004.port.T; TsAIR0CabiA008013004.port.Q_flow + (TC_1241_1242.port_b.Q_flow + (TC_1234_1242.port_b.Q_flow + (AIR0CabiA008013004.port.Q_flow + (TC_1242_1243.port_a.Q_flow + (TC_1242_1253.port_a.Q_flow + (TC_1242_1387.port_a.Q_flow + TC_1242_1550.port_a.Q_flow)))))) = 0.0; AIR0CabiA008013004.port.T = TC_1234_1242.port_b.T; AIR0CabiA008013004.port.T = TC_1241_1242.port_b.T; AIR0CabiA008013004.port.T = TC_1242_1243.port_a.T; AIR0CabiA008013004.port.T = TC_1242_1253.port_a.T; AIR0CabiA008013004.port.T = TC_1242_1387.port_a.T; AIR0CabiA008013004.port.T = TC_1242_1550.port_a.T; AIR0CabiA008013004.port.T = TsAIR0CabiA008013004.port.T; TsAIR0CabiA007013004.port.Q_flow + (TC_1233_1241.port_b.Q_flow + (AIR0CabiA007013004.port.Q_flow + (TC_1241_1242.port_a.Q_flow + (TC_1241_1252.port_a.Q_flow + (TC_1241_1386.port_a.Q_flow + (TC_1241_1526.port_a.Q_flow + TC_1241_1549.port_a.Q_flow)))))) = 0.0; AIR0CabiA007013004.port.T = TC_1233_1241.port_b.T; AIR0CabiA007013004.port.T = TC_1241_1242.port_a.T; AIR0CabiA007013004.port.T = TC_1241_1252.port_a.T; AIR0CabiA007013004.port.T = TC_1241_1386.port_a.T; AIR0CabiA007013004.port.T = TC_1241_1526.port_a.T; AIR0CabiA007013004.port.T = TC_1241_1549.port_a.T; AIR0CabiA007013004.port.T = TsAIR0CabiA007013004.port.T; TsAIR0CabiA003013004.port.Q_flow + (TC_1239_1240.port_b.Q_flow + (TC_1232_1240.port_b.Q_flow + (AIR0CabiA003013004.port.Q_flow + (TC_1240_1248.port_a.Q_flow + (TC_1240_1382.port_a.Q_flow + (TC_1240_1524.port_a.Q_flow + TC_1240_1545.port_a.Q_flow)))))) = 0.0; AIR0CabiA003013004.port.T = TC_1232_1240.port_b.T; AIR0CabiA003013004.port.T = TC_1239_1240.port_b.T; AIR0CabiA003013004.port.T = TC_1240_1248.port_a.T; AIR0CabiA003013004.port.T = TC_1240_1382.port_a.T; AIR0CabiA003013004.port.T = TC_1240_1524.port_a.T; AIR0CabiA003013004.port.T = TC_1240_1545.port_a.T; AIR0CabiA003013004.port.T = TsAIR0CabiA003013004.port.T; TsAIR0CabiA002013004.port.Q_flow + (TC_1231_1239.port_b.Q_flow + (TC_1130_1239.port_b.Q_flow + (TC_351_1239.port_b.Q_flow + (AIR0CabiA002013004.port.Q_flow + (TC_1239_1240.port_a.Q_flow + (TC_1239_1247.port_a.Q_flow + TC_1239_1381.port_a.Q_flow)))))) = 0.0; AIR0CabiA002013004.port.T = TC_1130_1239.port_b.T; AIR0CabiA002013004.port.T = TC_1231_1239.port_b.T; AIR0CabiA002013004.port.T = TC_1239_1240.port_a.T; AIR0CabiA002013004.port.T = TC_1239_1247.port_a.T; AIR0CabiA002013004.port.T = TC_1239_1381.port_a.T; AIR0CabiA002013004.port.T = TC_351_1239.port_b.T; AIR0CabiA002013004.port.T = TsAIR0CabiA002013004.port.T; TsAIR0CabiA012012004.port.Q_flow + (TC_1237_1238.port_b.Q_flow + (TC_1230_1238.port_b.Q_flow + (TC_1129_1238.port_b.Q_flow + (TC_350_1238.port_b.Q_flow + (AIR0CabiA012012004.port.Q_flow + (TC_1238_1246.port_a.Q_flow + TC_1238_1380.port_a.Q_flow)))))) = 0.0; AIR0CabiA012012004.port.T = TC_1129_1238.port_b.T; AIR0CabiA012012004.port.T = TC_1230_1238.port_b.T; AIR0CabiA012012004.port.T = TC_1237_1238.port_b.T; AIR0CabiA012012004.port.T = TC_1238_1246.port_a.T; AIR0CabiA012012004.port.T = TC_1238_1380.port_a.T; AIR0CabiA012012004.port.T = TC_350_1238.port_b.T; AIR0CabiA012012004.port.T = TsAIR0CabiA012012004.port.T; TsAIR0CabiA011012004.port.Q_flow + (TC_1236_1237.port_b.Q_flow + (TC_1229_1237.port_b.Q_flow + (AIR0CabiA011012004.port.Q_flow + (TC_1237_1238.port_a.Q_flow + (TC_1237_1245.port_a.Q_flow + (TC_1237_1379.port_a.Q_flow + TC_1237_1544.port_a.Q_flow)))))) = 0.0; AIR0CabiA011012004.port.T = TC_1229_1237.port_b.T; AIR0CabiA011012004.port.T = TC_1236_1237.port_b.T; AIR0CabiA011012004.port.T = TC_1237_1238.port_a.T; AIR0CabiA011012004.port.T = TC_1237_1245.port_a.T; AIR0CabiA011012004.port.T = TC_1237_1379.port_a.T; AIR0CabiA011012004.port.T = TC_1237_1544.port_a.T; AIR0CabiA011012004.port.T = TsAIR0CabiA011012004.port.T; TsAIR0CabiA010012004.port.Q_flow + (TC_1235_1236.port_b.Q_flow + (TC_1228_1236.port_b.Q_flow + (AIR0CabiA010012004.port.Q_flow + (TC_1236_1237.port_a.Q_flow + (TC_1236_1244.port_a.Q_flow + (TC_1236_1378.port_a.Q_flow + TC_1236_1543.port_a.Q_flow)))))) = 0.0; AIR0CabiA010012004.port.T = TC_1228_1236.port_b.T; AIR0CabiA010012004.port.T = TC_1235_1236.port_b.T; AIR0CabiA010012004.port.T = TC_1236_1237.port_a.T; AIR0CabiA010012004.port.T = TC_1236_1244.port_a.T; AIR0CabiA010012004.port.T = TC_1236_1378.port_a.T; AIR0CabiA010012004.port.T = TC_1236_1543.port_a.T; AIR0CabiA010012004.port.T = TsAIR0CabiA010012004.port.T; TsAIR0CabiA009012004.port.Q_flow + (TC_1234_1235.port_b.Q_flow + (TC_1227_1235.port_b.Q_flow + (AIR0CabiA009012004.port.Q_flow + (TC_1235_1236.port_a.Q_flow + (TC_1235_1243.port_a.Q_flow + (TC_1235_1377.port_a.Q_flow + TC_1235_1542.port_a.Q_flow)))))) = 0.0; AIR0CabiA009012004.port.T = TC_1227_1235.port_b.T; AIR0CabiA009012004.port.T = TC_1234_1235.port_b.T; AIR0CabiA009012004.port.T = TC_1235_1236.port_a.T; AIR0CabiA009012004.port.T = TC_1235_1243.port_a.T; AIR0CabiA009012004.port.T = TC_1235_1377.port_a.T; AIR0CabiA009012004.port.T = TC_1235_1542.port_a.T; AIR0CabiA009012004.port.T = TsAIR0CabiA009012004.port.T; TsAIR0CabiA008012004.port.Q_flow + (TC_1233_1234.port_b.Q_flow + (TC_1226_1234.port_b.Q_flow + (AIR0CabiA008012004.port.Q_flow + (TC_1234_1235.port_a.Q_flow + (TC_1234_1242.port_a.Q_flow + (TC_1234_1376.port_a.Q_flow + TC_1234_1541.port_a.Q_flow)))))) = 0.0; AIR0CabiA008012004.port.T = TC_1226_1234.port_b.T; AIR0CabiA008012004.port.T = TC_1233_1234.port_b.T; AIR0CabiA008012004.port.T = TC_1234_1235.port_a.T; AIR0CabiA008012004.port.T = TC_1234_1242.port_a.T; AIR0CabiA008012004.port.T = TC_1234_1376.port_a.T; AIR0CabiA008012004.port.T = TC_1234_1541.port_a.T; AIR0CabiA008012004.port.T = TsAIR0CabiA008012004.port.T; TsAIR0CabiA007012004.port.Q_flow + (TC_1225_1233.port_b.Q_flow + (AIR0CabiA007012004.port.Q_flow + (TC_1233_1234.port_a.Q_flow + (TC_1233_1241.port_a.Q_flow + (TC_1233_1375.port_a.Q_flow + (TC_1233_1523.port_a.Q_flow + TC_1233_1540.port_a.Q_flow)))))) = 0.0; AIR0CabiA007012004.port.T = TC_1225_1233.port_b.T; AIR0CabiA007012004.port.T = TC_1233_1234.port_a.T; AIR0CabiA007012004.port.T = TC_1233_1241.port_a.T; AIR0CabiA007012004.port.T = TC_1233_1375.port_a.T; AIR0CabiA007012004.port.T = TC_1233_1523.port_a.T; AIR0CabiA007012004.port.T = TC_1233_1540.port_a.T; AIR0CabiA007012004.port.T = TsAIR0CabiA007012004.port.T; TsAIR0CabiA003012004.port.Q_flow + (TC_1231_1232.port_b.Q_flow + (TC_1224_1232.port_b.Q_flow + (AIR0CabiA003012004.port.Q_flow + (TC_1232_1240.port_a.Q_flow + (TC_1232_1371.port_a.Q_flow + (TC_1232_1521.port_a.Q_flow + TC_1232_1536.port_a.Q_flow)))))) = 0.0; AIR0CabiA003012004.port.T = TC_1224_1232.port_b.T; AIR0CabiA003012004.port.T = TC_1231_1232.port_b.T; AIR0CabiA003012004.port.T = TC_1232_1240.port_a.T; AIR0CabiA003012004.port.T = TC_1232_1371.port_a.T; AIR0CabiA003012004.port.T = TC_1232_1521.port_a.T; AIR0CabiA003012004.port.T = TC_1232_1536.port_a.T; AIR0CabiA003012004.port.T = TsAIR0CabiA003012004.port.T; TsAIR0CabiA002012004.port.Q_flow + (TC_1223_1231.port_b.Q_flow + (TC_1128_1231.port_b.Q_flow + (TC_349_1231.port_b.Q_flow + (AIR0CabiA002012004.port.Q_flow + (TC_1231_1232.port_a.Q_flow + (TC_1231_1239.port_a.Q_flow + TC_1231_1370.port_a.Q_flow)))))) = 0.0; AIR0CabiA002012004.port.T = TC_1128_1231.port_b.T; AIR0CabiA002012004.port.T = TC_1223_1231.port_b.T; AIR0CabiA002012004.port.T = TC_1231_1232.port_a.T; AIR0CabiA002012004.port.T = TC_1231_1239.port_a.T; AIR0CabiA002012004.port.T = TC_1231_1370.port_a.T; AIR0CabiA002012004.port.T = TC_349_1231.port_b.T; AIR0CabiA002012004.port.T = TsAIR0CabiA002012004.port.T; TsAIR0CabiA012011004.port.Q_flow + (TC_1229_1230.port_b.Q_flow + (TC_1222_1230.port_b.Q_flow + (TC_1127_1230.port_b.Q_flow + (TC_348_1230.port_b.Q_flow + (AIR0CabiA012011004.port.Q_flow + (TC_1230_1238.port_a.Q_flow + TC_1230_1369.port_a.Q_flow)))))) = 0.0; AIR0CabiA012011004.port.T = TC_1127_1230.port_b.T; AIR0CabiA012011004.port.T = TC_1222_1230.port_b.T; AIR0CabiA012011004.port.T = TC_1229_1230.port_b.T; AIR0CabiA012011004.port.T = TC_1230_1238.port_a.T; AIR0CabiA012011004.port.T = TC_1230_1369.port_a.T; AIR0CabiA012011004.port.T = TC_348_1230.port_b.T; AIR0CabiA012011004.port.T = TsAIR0CabiA012011004.port.T; TsAIR0CabiA011011004.port.Q_flow + (TC_1228_1229.port_b.Q_flow + (TC_1221_1229.port_b.Q_flow + (AIR0CabiA011011004.port.Q_flow + (TC_1229_1230.port_a.Q_flow + (TC_1229_1237.port_a.Q_flow + (TC_1229_1368.port_a.Q_flow + TC_1229_1535.port_a.Q_flow)))))) = 0.0; AIR0CabiA011011004.port.T = TC_1221_1229.port_b.T; AIR0CabiA011011004.port.T = TC_1228_1229.port_b.T; AIR0CabiA011011004.port.T = TC_1229_1230.port_a.T; AIR0CabiA011011004.port.T = TC_1229_1237.port_a.T; AIR0CabiA011011004.port.T = TC_1229_1368.port_a.T; AIR0CabiA011011004.port.T = TC_1229_1535.port_a.T; AIR0CabiA011011004.port.T = TsAIR0CabiA011011004.port.T; TsAIR0CabiA010011004.port.Q_flow + (TC_1227_1228.port_b.Q_flow + (AIR0CabiA010011004.port.Q_flow + (TC_1228_1229.port_a.Q_flow + (TC_1228_1236.port_a.Q_flow + (TC_1228_1367.port_a.Q_flow + (TC_1228_1517.port_a.Q_flow + TC_1228_1534.port_a.Q_flow)))))) = 0.0; AIR0CabiA010011004.port.T = TC_1227_1228.port_b.T; AIR0CabiA010011004.port.T = TC_1228_1229.port_a.T; AIR0CabiA010011004.port.T = TC_1228_1236.port_a.T; AIR0CabiA010011004.port.T = TC_1228_1367.port_a.T; AIR0CabiA010011004.port.T = TC_1228_1517.port_a.T; AIR0CabiA010011004.port.T = TC_1228_1534.port_a.T; AIR0CabiA010011004.port.T = TsAIR0CabiA010011004.port.T; TsAIR0CabiA009011004.port.Q_flow + (TC_1226_1227.port_b.Q_flow + (AIR0CabiA009011004.port.Q_flow + (TC_1227_1228.port_a.Q_flow + (TC_1227_1235.port_a.Q_flow + (TC_1227_1366.port_a.Q_flow + (TC_1227_1516.port_a.Q_flow + TC_1227_1533.port_a.Q_flow)))))) = 0.0; AIR0CabiA009011004.port.T = TC_1226_1227.port_b.T; AIR0CabiA009011004.port.T = TC_1227_1228.port_a.T; AIR0CabiA009011004.port.T = TC_1227_1235.port_a.T; AIR0CabiA009011004.port.T = TC_1227_1366.port_a.T; AIR0CabiA009011004.port.T = TC_1227_1516.port_a.T; AIR0CabiA009011004.port.T = TC_1227_1533.port_a.T; AIR0CabiA009011004.port.T = TsAIR0CabiA009011004.port.T; TsAIR0CabiA008011004.port.Q_flow + (TC_1225_1226.port_b.Q_flow + (AIR0CabiA008011004.port.Q_flow + (TC_1226_1227.port_a.Q_flow + (TC_1226_1234.port_a.Q_flow + (TC_1226_1365.port_a.Q_flow + (TC_1226_1515.port_a.Q_flow + TC_1226_1532.port_a.Q_flow)))))) = 0.0; AIR0CabiA008011004.port.T = TC_1225_1226.port_b.T; AIR0CabiA008011004.port.T = TC_1226_1227.port_a.T; AIR0CabiA008011004.port.T = TC_1226_1234.port_a.T; AIR0CabiA008011004.port.T = TC_1226_1365.port_a.T; AIR0CabiA008011004.port.T = TC_1226_1515.port_a.T; AIR0CabiA008011004.port.T = TC_1226_1532.port_a.T; AIR0CabiA008011004.port.T = TsAIR0CabiA008011004.port.T; TsAIR0CabiA007011004.port.Q_flow + (TC_1220_1225.port_b.Q_flow + (AIR0CabiA007011004.port.Q_flow + (TC_1225_1226.port_a.Q_flow + (TC_1225_1233.port_a.Q_flow + (TC_1225_1364.port_a.Q_flow + (TC_1225_1520.port_a.Q_flow + TC_1225_1531.port_a.Q_flow)))))) = 0.0; AIR0CabiA007011004.port.T = TC_1220_1225.port_b.T; AIR0CabiA007011004.port.T = TC_1225_1226.port_a.T; AIR0CabiA007011004.port.T = TC_1225_1233.port_a.T; AIR0CabiA007011004.port.T = TC_1225_1364.port_a.T; AIR0CabiA007011004.port.T = TC_1225_1520.port_a.T; AIR0CabiA007011004.port.T = TC_1225_1531.port_a.T; AIR0CabiA007011004.port.T = TsAIR0CabiA007011004.port.T; TsAIR0CabiA003011004.port.Q_flow + (TC_1223_1224.port_b.Q_flow + (TC_1216_1224.port_b.Q_flow + (AIR0CabiA003011004.port.Q_flow + (TC_1224_1232.port_a.Q_flow + (TC_1224_1360.port_a.Q_flow + (TC_1224_1518.port_a.Q_flow + TC_1224_1527.port_a.Q_flow)))))) = 0.0; AIR0CabiA003011004.port.T = TC_1216_1224.port_b.T; AIR0CabiA003011004.port.T = TC_1223_1224.port_b.T; AIR0CabiA003011004.port.T = TC_1224_1232.port_a.T; AIR0CabiA003011004.port.T = TC_1224_1360.port_a.T; AIR0CabiA003011004.port.T = TC_1224_1518.port_a.T; AIR0CabiA003011004.port.T = TC_1224_1527.port_a.T; AIR0CabiA003011004.port.T = TsAIR0CabiA003011004.port.T; TsAIR0CabiA002011004.port.Q_flow + (TC_1215_1223.port_b.Q_flow + (TC_1126_1223.port_b.Q_flow + (TC_347_1223.port_b.Q_flow + (AIR0CabiA002011004.port.Q_flow + (TC_1223_1224.port_a.Q_flow + (TC_1223_1231.port_a.Q_flow + TC_1223_1359.port_a.Q_flow)))))) = 0.0; AIR0CabiA002011004.port.T = TC_1126_1223.port_b.T; AIR0CabiA002011004.port.T = TC_1215_1223.port_b.T; AIR0CabiA002011004.port.T = TC_1223_1224.port_a.T; AIR0CabiA002011004.port.T = TC_1223_1231.port_a.T; AIR0CabiA002011004.port.T = TC_1223_1359.port_a.T; AIR0CabiA002011004.port.T = TC_347_1223.port_b.T; AIR0CabiA002011004.port.T = TsAIR0CabiA002011004.port.T; TsAIR0CabiA012010004.port.Q_flow + (TC_1221_1222.port_b.Q_flow + (TC_1214_1222.port_b.Q_flow + (TC_1125_1222.port_b.Q_flow + (TC_346_1222.port_b.Q_flow + (AIR0CabiA012010004.port.Q_flow + (TC_1222_1230.port_a.Q_flow + TC_1222_1358.port_a.Q_flow)))))) = 0.0; AIR0CabiA012010004.port.T = TC_1125_1222.port_b.T; AIR0CabiA012010004.port.T = TC_1214_1222.port_b.T; AIR0CabiA012010004.port.T = TC_1221_1222.port_b.T; AIR0CabiA012010004.port.T = TC_1222_1230.port_a.T; AIR0CabiA012010004.port.T = TC_1222_1358.port_a.T; AIR0CabiA012010004.port.T = TC_346_1222.port_b.T; AIR0CabiA012010004.port.T = TsAIR0CabiA012010004.port.T; TsAIR0CabiA011010004.port.Q_flow + (TC_1213_1221.port_b.Q_flow + (AIR0CabiA011010004.port.Q_flow + (TC_1221_1222.port_a.Q_flow + (TC_1221_1229.port_a.Q_flow + (TC_1221_1357.port_a.Q_flow + (TC_1221_1517.port_a.Q_flow + TC_1221_1607.port_a.Q_flow)))))) = 0.0; AIR0CabiA011010004.port.T = TC_1213_1221.port_b.T; AIR0CabiA011010004.port.T = TC_1221_1222.port_a.T; AIR0CabiA011010004.port.T = TC_1221_1229.port_a.T; AIR0CabiA011010004.port.T = TC_1221_1357.port_a.T; AIR0CabiA011010004.port.T = TC_1221_1517.port_a.T; AIR0CabiA011010004.port.T = TC_1221_1607.port_a.T; AIR0CabiA011010004.port.T = TsAIR0CabiA011010004.port.T; TsAIR0CabiA007010004.port.Q_flow + (TC_1219_1220.port_b.Q_flow + (TC_1212_1220.port_b.Q_flow + (AIR0CabiA007010004.port.Q_flow + (TC_1220_1225.port_a.Q_flow + (TC_1220_1356.port_a.Q_flow + (TC_1220_1515.port_a.Q_flow + TC_1220_1603.port_a.Q_flow)))))) = 0.0; AIR0CabiA007010004.port.T = TC_1212_1220.port_b.T; AIR0CabiA007010004.port.T = TC_1219_1220.port_b.T; AIR0CabiA007010004.port.T = TC_1220_1225.port_a.T; AIR0CabiA007010004.port.T = TC_1220_1356.port_a.T; AIR0CabiA007010004.port.T = TC_1220_1515.port_a.T; AIR0CabiA007010004.port.T = TC_1220_1603.port_a.T; AIR0CabiA007010004.port.T = TsAIR0CabiA007010004.port.T; TsAIR0CabiA006010004.port.Q_flow + (TC_1218_1219.port_b.Q_flow + (TC_1211_1219.port_b.Q_flow + (AIR0CabiA006010004.port.Q_flow + (TC_1219_1220.port_a.Q_flow + (TC_1219_1355.port_a.Q_flow + (TC_1219_1520.port_a.Q_flow + TC_1219_1602.port_a.Q_flow)))))) = 0.0; AIR0CabiA006010004.port.T = TC_1211_1219.port_b.T; AIR0CabiA006010004.port.T = TC_1218_1219.port_b.T; AIR0CabiA006010004.port.T = TC_1219_1220.port_a.T; AIR0CabiA006010004.port.T = TC_1219_1355.port_a.T; AIR0CabiA006010004.port.T = TC_1219_1520.port_a.T; AIR0CabiA006010004.port.T = TC_1219_1602.port_a.T; AIR0CabiA006010004.port.T = TsAIR0CabiA006010004.port.T; TsAIR0CabiA005010004.port.Q_flow + (TC_1217_1218.port_b.Q_flow + (TC_1210_1218.port_b.Q_flow + (AIR0CabiA005010004.port.Q_flow + (TC_1218_1219.port_a.Q_flow + (TC_1218_1354.port_a.Q_flow + (TC_1218_1519.port_a.Q_flow + TC_1218_1601.port_a.Q_flow)))))) = 0.0; AIR0CabiA005010004.port.T = TC_1210_1218.port_b.T; AIR0CabiA005010004.port.T = TC_1217_1218.port_b.T; AIR0CabiA005010004.port.T = TC_1218_1219.port_a.T; AIR0CabiA005010004.port.T = TC_1218_1354.port_a.T; AIR0CabiA005010004.port.T = TC_1218_1519.port_a.T; AIR0CabiA005010004.port.T = TC_1218_1601.port_a.T; AIR0CabiA005010004.port.T = TsAIR0CabiA005010004.port.T; TsAIR0CabiA004010004.port.Q_flow + (TC_1216_1217.port_b.Q_flow + (TC_1209_1217.port_b.Q_flow + (AIR0CabiA004010004.port.Q_flow + (TC_1217_1218.port_a.Q_flow + (TC_1217_1353.port_a.Q_flow + (TC_1217_1518.port_a.Q_flow + TC_1217_1600.port_a.Q_flow)))))) = 0.0; AIR0CabiA004010004.port.T = TC_1209_1217.port_b.T; AIR0CabiA004010004.port.T = TC_1216_1217.port_b.T; AIR0CabiA004010004.port.T = TC_1217_1218.port_a.T; AIR0CabiA004010004.port.T = TC_1217_1353.port_a.T; AIR0CabiA004010004.port.T = TC_1217_1518.port_a.T; AIR0CabiA004010004.port.T = TC_1217_1600.port_a.T; AIR0CabiA004010004.port.T = TsAIR0CabiA004010004.port.T; TsAIR0CabiA003010004.port.Q_flow + (TC_1215_1216.port_b.Q_flow + (TC_1208_1216.port_b.Q_flow + (AIR0CabiA003010004.port.Q_flow + (TC_1216_1217.port_a.Q_flow + (TC_1216_1224.port_a.Q_flow + (TC_1216_1352.port_a.Q_flow + TC_1216_1599.port_a.Q_flow)))))) = 0.0; AIR0CabiA003010004.port.T = TC_1208_1216.port_b.T; AIR0CabiA003010004.port.T = TC_1215_1216.port_b.T; AIR0CabiA003010004.port.T = TC_1216_1217.port_a.T; AIR0CabiA003010004.port.T = TC_1216_1224.port_a.T; AIR0CabiA003010004.port.T = TC_1216_1352.port_a.T; AIR0CabiA003010004.port.T = TC_1216_1599.port_a.T; AIR0CabiA003010004.port.T = TsAIR0CabiA003010004.port.T; TsAIR0CabiA002010004.port.Q_flow + (TC_1207_1215.port_b.Q_flow + (TC_1124_1215.port_b.Q_flow + (TC_345_1215.port_b.Q_flow + (AIR0CabiA002010004.port.Q_flow + (TC_1215_1216.port_a.Q_flow + (TC_1215_1223.port_a.Q_flow + TC_1215_1351.port_a.Q_flow)))))) = 0.0; AIR0CabiA002010004.port.T = TC_1124_1215.port_b.T; AIR0CabiA002010004.port.T = TC_1207_1215.port_b.T; AIR0CabiA002010004.port.T = TC_1215_1216.port_a.T; AIR0CabiA002010004.port.T = TC_1215_1223.port_a.T; AIR0CabiA002010004.port.T = TC_1215_1351.port_a.T; AIR0CabiA002010004.port.T = TC_345_1215.port_b.T; AIR0CabiA002010004.port.T = TsAIR0CabiA002010004.port.T; TsAIR0CabiA012009004.port.Q_flow + (TC_1213_1214.port_b.Q_flow + (TC_1206_1214.port_b.Q_flow + (TC_1123_1214.port_b.Q_flow + (TC_344_1214.port_b.Q_flow + (AIR0CabiA012009004.port.Q_flow + (TC_1214_1222.port_a.Q_flow + TC_1214_1350.port_a.Q_flow)))))) = 0.0; AIR0CabiA012009004.port.T = TC_1123_1214.port_b.T; AIR0CabiA012009004.port.T = TC_1206_1214.port_b.T; AIR0CabiA012009004.port.T = TC_1213_1214.port_b.T; AIR0CabiA012009004.port.T = TC_1214_1222.port_a.T; AIR0CabiA012009004.port.T = TC_1214_1350.port_a.T; AIR0CabiA012009004.port.T = TC_344_1214.port_b.T; AIR0CabiA012009004.port.T = TsAIR0CabiA012009004.port.T; TsAIR0CabiA011009004.port.Q_flow + (TC_1205_1213.port_b.Q_flow + (AIR0CabiA011009004.port.Q_flow + (TC_1213_1214.port_a.Q_flow + (TC_1213_1221.port_a.Q_flow + (TC_1213_1349.port_a.Q_flow + (TC_1213_1514.port_a.Q_flow + TC_1213_1598.port_a.Q_flow)))))) = 0.0; AIR0CabiA011009004.port.T = TC_1205_1213.port_b.T; AIR0CabiA011009004.port.T = TC_1213_1214.port_a.T; AIR0CabiA011009004.port.T = TC_1213_1221.port_a.T; AIR0CabiA011009004.port.T = TC_1213_1349.port_a.T; AIR0CabiA011009004.port.T = TC_1213_1514.port_a.T; AIR0CabiA011009004.port.T = TC_1213_1598.port_a.T; AIR0CabiA011009004.port.T = TsAIR0CabiA011009004.port.T; TsAIR0CabiA007009004.port.Q_flow + (TC_1211_1212.port_b.Q_flow + (TC_1204_1212.port_b.Q_flow + (AIR0CabiA007009004.port.Q_flow + (TC_1212_1220.port_a.Q_flow + (TC_1212_1348.port_a.Q_flow + (TC_1212_1512.port_a.Q_flow + TC_1212_1594.port_a.Q_flow)))))) = 0.0; AIR0CabiA007009004.port.T = TC_1204_1212.port_b.T; AIR0CabiA007009004.port.T = TC_1211_1212.port_b.T; AIR0CabiA007009004.port.T = TC_1212_1220.port_a.T; AIR0CabiA007009004.port.T = TC_1212_1348.port_a.T; AIR0CabiA007009004.port.T = TC_1212_1512.port_a.T; AIR0CabiA007009004.port.T = TC_1212_1594.port_a.T; AIR0CabiA007009004.port.T = TsAIR0CabiA007009004.port.T; TsAIR0CabiA006009004.port.Q_flow + (TC_1210_1211.port_b.Q_flow + (TC_1203_1211.port_b.Q_flow + (AIR0CabiA006009004.port.Q_flow + (TC_1211_1212.port_a.Q_flow + (TC_1211_1219.port_a.Q_flow + (TC_1211_1347.port_a.Q_flow + TC_1211_1593.port_a.Q_flow)))))) = 0.0; AIR0CabiA006009004.port.T = TC_1203_1211.port_b.T; AIR0CabiA006009004.port.T = TC_1210_1211.port_b.T; AIR0CabiA006009004.port.T = TC_1211_1212.port_a.T; AIR0CabiA006009004.port.T = TC_1211_1219.port_a.T; AIR0CabiA006009004.port.T = TC_1211_1347.port_a.T; AIR0CabiA006009004.port.T = TC_1211_1593.port_a.T; AIR0CabiA006009004.port.T = TsAIR0CabiA006009004.port.T; TsAIR0CabiA005009004.port.Q_flow + (TC_1209_1210.port_b.Q_flow + (TC_1202_1210.port_b.Q_flow + (AIR0CabiA005009004.port.Q_flow + (TC_1210_1211.port_a.Q_flow + (TC_1210_1218.port_a.Q_flow + (TC_1210_1346.port_a.Q_flow + TC_1210_1592.port_a.Q_flow)))))) = 0.0; AIR0CabiA005009004.port.T = TC_1202_1210.port_b.T; AIR0CabiA005009004.port.T = TC_1209_1210.port_b.T; AIR0CabiA005009004.port.T = TC_1210_1211.port_a.T; AIR0CabiA005009004.port.T = TC_1210_1218.port_a.T; AIR0CabiA005009004.port.T = TC_1210_1346.port_a.T; AIR0CabiA005009004.port.T = TC_1210_1592.port_a.T; AIR0CabiA005009004.port.T = TsAIR0CabiA005009004.port.T; TsAIR0CabiA004009004.port.Q_flow + (TC_1208_1209.port_b.Q_flow + (TC_1201_1209.port_b.Q_flow + (AIR0CabiA004009004.port.Q_flow + (TC_1209_1210.port_a.Q_flow + (TC_1209_1217.port_a.Q_flow + (TC_1209_1345.port_a.Q_flow + TC_1209_1591.port_a.Q_flow)))))) = 0.0; AIR0CabiA004009004.port.T = TC_1201_1209.port_b.T; AIR0CabiA004009004.port.T = TC_1208_1209.port_b.T; AIR0CabiA004009004.port.T = TC_1209_1210.port_a.T; AIR0CabiA004009004.port.T = TC_1209_1217.port_a.T; AIR0CabiA004009004.port.T = TC_1209_1345.port_a.T; AIR0CabiA004009004.port.T = TC_1209_1591.port_a.T; AIR0CabiA004009004.port.T = TsAIR0CabiA004009004.port.T; TsAIR0CabiA003009004.port.Q_flow + (TC_1207_1208.port_b.Q_flow + (TC_1200_1208.port_b.Q_flow + (AIR0CabiA003009004.port.Q_flow + (TC_1208_1209.port_a.Q_flow + (TC_1208_1216.port_a.Q_flow + (TC_1208_1344.port_a.Q_flow + TC_1208_1590.port_a.Q_flow)))))) = 0.0; AIR0CabiA003009004.port.T = TC_1200_1208.port_b.T; AIR0CabiA003009004.port.T = TC_1207_1208.port_b.T; AIR0CabiA003009004.port.T = TC_1208_1209.port_a.T; AIR0CabiA003009004.port.T = TC_1208_1216.port_a.T; AIR0CabiA003009004.port.T = TC_1208_1344.port_a.T; AIR0CabiA003009004.port.T = TC_1208_1590.port_a.T; AIR0CabiA003009004.port.T = TsAIR0CabiA003009004.port.T; TsAIR0CabiA002009004.port.Q_flow + (TC_1199_1207.port_b.Q_flow + (TC_1122_1207.port_b.Q_flow + (TC_343_1207.port_b.Q_flow + (AIR0CabiA002009004.port.Q_flow + (TC_1207_1208.port_a.Q_flow + (TC_1207_1215.port_a.Q_flow + TC_1207_1343.port_a.Q_flow)))))) = 0.0; AIR0CabiA002009004.port.T = TC_1122_1207.port_b.T; AIR0CabiA002009004.port.T = TC_1199_1207.port_b.T; AIR0CabiA002009004.port.T = TC_1207_1208.port_a.T; AIR0CabiA002009004.port.T = TC_1207_1215.port_a.T; AIR0CabiA002009004.port.T = TC_1207_1343.port_a.T; AIR0CabiA002009004.port.T = TC_343_1207.port_b.T; AIR0CabiA002009004.port.T = TsAIR0CabiA002009004.port.T; TsAIR0CabiA012008004.port.Q_flow + (TC_1205_1206.port_b.Q_flow + (TC_1198_1206.port_b.Q_flow + (TC_1121_1206.port_b.Q_flow + (TC_342_1206.port_b.Q_flow + (AIR0CabiA012008004.port.Q_flow + (TC_1206_1214.port_a.Q_flow + TC_1206_1342.port_a.Q_flow)))))) = 0.0; AIR0CabiA012008004.port.T = TC_1121_1206.port_b.T; AIR0CabiA012008004.port.T = TC_1198_1206.port_b.T; AIR0CabiA012008004.port.T = TC_1205_1206.port_b.T; AIR0CabiA012008004.port.T = TC_1206_1214.port_a.T; AIR0CabiA012008004.port.T = TC_1206_1342.port_a.T; AIR0CabiA012008004.port.T = TC_342_1206.port_b.T; AIR0CabiA012008004.port.T = TsAIR0CabiA012008004.port.T; TsAIR0CabiA011008004.port.Q_flow + (TC_1197_1205.port_b.Q_flow + (AIR0CabiA011008004.port.Q_flow + (TC_1205_1206.port_a.Q_flow + (TC_1205_1213.port_a.Q_flow + (TC_1205_1341.port_a.Q_flow + (TC_1205_1511.port_a.Q_flow + TC_1205_1589.port_a.Q_flow)))))) = 0.0; AIR0CabiA011008004.port.T = TC_1197_1205.port_b.T; AIR0CabiA011008004.port.T = TC_1205_1206.port_a.T; AIR0CabiA011008004.port.T = TC_1205_1213.port_a.T; AIR0CabiA011008004.port.T = TC_1205_1341.port_a.T; AIR0CabiA011008004.port.T = TC_1205_1511.port_a.T; AIR0CabiA011008004.port.T = TC_1205_1589.port_a.T; AIR0CabiA011008004.port.T = TsAIR0CabiA011008004.port.T; TsAIR0CabiA007008004.port.Q_flow + (TC_1203_1204.port_b.Q_flow + (TC_1193_1204.port_b.Q_flow + (AIR0CabiA007008004.port.Q_flow + (TC_1204_1212.port_a.Q_flow + (TC_1204_1340.port_a.Q_flow + (TC_1204_1509.port_a.Q_flow + TC_1204_1585.port_a.Q_flow)))))) = 0.0; AIR0CabiA007008004.port.T = TC_1193_1204.port_b.T; AIR0CabiA007008004.port.T = TC_1203_1204.port_b.T; AIR0CabiA007008004.port.T = TC_1204_1212.port_a.T; AIR0CabiA007008004.port.T = TC_1204_1340.port_a.T; AIR0CabiA007008004.port.T = TC_1204_1509.port_a.T; AIR0CabiA007008004.port.T = TC_1204_1585.port_a.T; AIR0CabiA007008004.port.T = TsAIR0CabiA007008004.port.T; TsAIR0CabiA006008004.port.Q_flow + (TC_1202_1203.port_b.Q_flow + (TC_1192_1203.port_b.Q_flow + (AIR0CabiA006008004.port.Q_flow + (TC_1203_1204.port_a.Q_flow + (TC_1203_1211.port_a.Q_flow + (TC_1203_1339.port_a.Q_flow + TC_1203_1584.port_a.Q_flow)))))) = 0.0; AIR0CabiA006008004.port.T = TC_1192_1203.port_b.T; AIR0CabiA006008004.port.T = TC_1202_1203.port_b.T; AIR0CabiA006008004.port.T = TC_1203_1204.port_a.T; AIR0CabiA006008004.port.T = TC_1203_1211.port_a.T; AIR0CabiA006008004.port.T = TC_1203_1339.port_a.T; AIR0CabiA006008004.port.T = TC_1203_1584.port_a.T; AIR0CabiA006008004.port.T = TsAIR0CabiA006008004.port.T; TsAIR0CabiA005008004.port.Q_flow + (TC_1201_1202.port_b.Q_flow + (TC_1191_1202.port_b.Q_flow + (AIR0CabiA005008004.port.Q_flow + (TC_1202_1203.port_a.Q_flow + (TC_1202_1210.port_a.Q_flow + (TC_1202_1338.port_a.Q_flow + TC_1202_1583.port_a.Q_flow)))))) = 0.0; AIR0CabiA005008004.port.T = TC_1191_1202.port_b.T; AIR0CabiA005008004.port.T = TC_1201_1202.port_b.T; AIR0CabiA005008004.port.T = TC_1202_1203.port_a.T; AIR0CabiA005008004.port.T = TC_1202_1210.port_a.T; AIR0CabiA005008004.port.T = TC_1202_1338.port_a.T; AIR0CabiA005008004.port.T = TC_1202_1583.port_a.T; AIR0CabiA005008004.port.T = TsAIR0CabiA005008004.port.T; TsAIR0CabiA004008004.port.Q_flow + (TC_1200_1201.port_b.Q_flow + (TC_1190_1201.port_b.Q_flow + (AIR0CabiA004008004.port.Q_flow + (TC_1201_1202.port_a.Q_flow + (TC_1201_1209.port_a.Q_flow + (TC_1201_1337.port_a.Q_flow + TC_1201_1582.port_a.Q_flow)))))) = 0.0; AIR0CabiA004008004.port.T = TC_1190_1201.port_b.T; AIR0CabiA004008004.port.T = TC_1200_1201.port_b.T; AIR0CabiA004008004.port.T = TC_1201_1202.port_a.T; AIR0CabiA004008004.port.T = TC_1201_1209.port_a.T; AIR0CabiA004008004.port.T = TC_1201_1337.port_a.T; AIR0CabiA004008004.port.T = TC_1201_1582.port_a.T; AIR0CabiA004008004.port.T = TsAIR0CabiA004008004.port.T; TsAIR0CabiA003008004.port.Q_flow + (TC_1199_1200.port_b.Q_flow + (TC_1189_1200.port_b.Q_flow + (AIR0CabiA003008004.port.Q_flow + (TC_1200_1201.port_a.Q_flow + (TC_1200_1208.port_a.Q_flow + (TC_1200_1336.port_a.Q_flow + TC_1200_1581.port_a.Q_flow)))))) = 0.0; AIR0CabiA003008004.port.T = TC_1189_1200.port_b.T; AIR0CabiA003008004.port.T = TC_1199_1200.port_b.T; AIR0CabiA003008004.port.T = TC_1200_1201.port_a.T; AIR0CabiA003008004.port.T = TC_1200_1208.port_a.T; AIR0CabiA003008004.port.T = TC_1200_1336.port_a.T; AIR0CabiA003008004.port.T = TC_1200_1581.port_a.T; AIR0CabiA003008004.port.T = TsAIR0CabiA003008004.port.T; TsAIR0CabiA002008004.port.Q_flow + (TC_1188_1199.port_b.Q_flow + (TC_1120_1199.port_b.Q_flow + (TC_341_1199.port_b.Q_flow + (AIR0CabiA002008004.port.Q_flow + (TC_1199_1200.port_a.Q_flow + (TC_1199_1207.port_a.Q_flow + TC_1199_1335.port_a.Q_flow)))))) = 0.0; AIR0CabiA002008004.port.T = TC_1120_1199.port_b.T; AIR0CabiA002008004.port.T = TC_1188_1199.port_b.T; AIR0CabiA002008004.port.T = TC_1199_1200.port_a.T; AIR0CabiA002008004.port.T = TC_1199_1207.port_a.T; AIR0CabiA002008004.port.T = TC_1199_1335.port_a.T; AIR0CabiA002008004.port.T = TC_341_1199.port_b.T; AIR0CabiA002008004.port.T = TsAIR0CabiA002008004.port.T; TsAIR0CabiA012007004.port.Q_flow + (TC_1197_1198.port_b.Q_flow + (TC_1187_1198.port_b.Q_flow + (TC_1119_1198.port_b.Q_flow + (TC_340_1198.port_b.Q_flow + (AIR0CabiA012007004.port.Q_flow + (TC_1198_1206.port_a.Q_flow + TC_1198_1334.port_a.Q_flow)))))) = 0.0; AIR0CabiA012007004.port.T = TC_1119_1198.port_b.T; AIR0CabiA012007004.port.T = TC_1187_1198.port_b.T; AIR0CabiA012007004.port.T = TC_1197_1198.port_b.T; AIR0CabiA012007004.port.T = TC_1198_1206.port_a.T; AIR0CabiA012007004.port.T = TC_1198_1334.port_a.T; AIR0CabiA012007004.port.T = TC_340_1198.port_b.T; AIR0CabiA012007004.port.T = TsAIR0CabiA012007004.port.T; TsAIR0CabiA011007004.port.Q_flow + (TC_1196_1197.port_b.Q_flow + (TC_1186_1197.port_b.Q_flow + (AIR0CabiA011007004.port.Q_flow + (TC_1197_1198.port_a.Q_flow + (TC_1197_1205.port_a.Q_flow + (TC_1197_1333.port_a.Q_flow + TC_1197_1580.port_a.Q_flow)))))) = 0.0; AIR0CabiA011007004.port.T = TC_1186_1197.port_b.T; AIR0CabiA011007004.port.T = TC_1196_1197.port_b.T; AIR0CabiA011007004.port.T = TC_1197_1198.port_a.T; AIR0CabiA011007004.port.T = TC_1197_1205.port_a.T; AIR0CabiA011007004.port.T = TC_1197_1333.port_a.T; AIR0CabiA011007004.port.T = TC_1197_1580.port_a.T; AIR0CabiA011007004.port.T = TsAIR0CabiA011007004.port.T; TsAIR0CabiA010007004.port.Q_flow + (TC_1195_1196.port_b.Q_flow + (TC_1185_1196.port_b.Q_flow + (AIR0CabiA010007004.port.Q_flow + (TC_1196_1197.port_a.Q_flow + (TC_1196_1332.port_a.Q_flow + (TC_1196_1511.port_a.Q_flow + TC_1196_1579.port_a.Q_flow)))))) = 0.0; AIR0CabiA010007004.port.T = TC_1185_1196.port_b.T; AIR0CabiA010007004.port.T = TC_1195_1196.port_b.T; AIR0CabiA010007004.port.T = TC_1196_1197.port_a.T; AIR0CabiA010007004.port.T = TC_1196_1332.port_a.T; AIR0CabiA010007004.port.T = TC_1196_1511.port_a.T; AIR0CabiA010007004.port.T = TC_1196_1579.port_a.T; AIR0CabiA010007004.port.T = TsAIR0CabiA010007004.port.T; TsAIR0CabiA009007004.port.Q_flow + (TC_1194_1195.port_b.Q_flow + (TC_1184_1195.port_b.Q_flow + (AIR0CabiA009007004.port.Q_flow + (TC_1195_1196.port_a.Q_flow + (TC_1195_1331.port_a.Q_flow + (TC_1195_1510.port_a.Q_flow + TC_1195_1578.port_a.Q_flow)))))) = 0.0; AIR0CabiA009007004.port.T = TC_1184_1195.port_b.T; AIR0CabiA009007004.port.T = TC_1194_1195.port_b.T; AIR0CabiA009007004.port.T = TC_1195_1196.port_a.T; AIR0CabiA009007004.port.T = TC_1195_1331.port_a.T; AIR0CabiA009007004.port.T = TC_1195_1510.port_a.T; AIR0CabiA009007004.port.T = TC_1195_1578.port_a.T; AIR0CabiA009007004.port.T = TsAIR0CabiA009007004.port.T; TsAIR0CabiA008007004.port.Q_flow + (TC_1193_1194.port_b.Q_flow + (TC_1183_1194.port_b.Q_flow + (AIR0CabiA008007004.port.Q_flow + (TC_1194_1195.port_a.Q_flow + (TC_1194_1330.port_a.Q_flow + (TC_1194_1509.port_a.Q_flow + TC_1194_1577.port_a.Q_flow)))))) = 0.0; AIR0CabiA008007004.port.T = TC_1183_1194.port_b.T; AIR0CabiA008007004.port.T = TC_1193_1194.port_b.T; AIR0CabiA008007004.port.T = TC_1194_1195.port_a.T; AIR0CabiA008007004.port.T = TC_1194_1330.port_a.T; AIR0CabiA008007004.port.T = TC_1194_1509.port_a.T; AIR0CabiA008007004.port.T = TC_1194_1577.port_a.T; AIR0CabiA008007004.port.T = TsAIR0CabiA008007004.port.T; TsAIR0CabiA007007004.port.Q_flow + (TC_1192_1193.port_b.Q_flow + (AIR0CabiA007007004.port.Q_flow + (TC_1193_1194.port_a.Q_flow + (TC_1193_1204.port_a.Q_flow + (TC_1193_1329.port_a.Q_flow + (TC_1193_1508.port_a.Q_flow + TC_1193_1576.port_a.Q_flow)))))) = 0.0; AIR0CabiA007007004.port.T = TC_1192_1193.port_b.T; AIR0CabiA007007004.port.T = TC_1193_1194.port_a.T; AIR0CabiA007007004.port.T = TC_1193_1204.port_a.T; AIR0CabiA007007004.port.T = TC_1193_1329.port_a.T; AIR0CabiA007007004.port.T = TC_1193_1508.port_a.T; AIR0CabiA007007004.port.T = TC_1193_1576.port_a.T; AIR0CabiA007007004.port.T = TsAIR0CabiA007007004.port.T; TsAIR0CabiA006007004.port.Q_flow + (TC_1191_1192.port_b.Q_flow + (AIR0CabiA006007004.port.Q_flow + (TC_1192_1193.port_a.Q_flow + (TC_1192_1203.port_a.Q_flow + (TC_1192_1328.port_a.Q_flow + (TC_1192_1507.port_a.Q_flow + TC_1192_1575.port_a.Q_flow)))))) = 0.0; AIR0CabiA006007004.port.T = TC_1191_1192.port_b.T; AIR0CabiA006007004.port.T = TC_1192_1193.port_a.T; AIR0CabiA006007004.port.T = TC_1192_1203.port_a.T; AIR0CabiA006007004.port.T = TC_1192_1328.port_a.T; AIR0CabiA006007004.port.T = TC_1192_1507.port_a.T; AIR0CabiA006007004.port.T = TC_1192_1575.port_a.T; AIR0CabiA006007004.port.T = TsAIR0CabiA006007004.port.T; TsAIR0CabiA005007004.port.Q_flow + (TC_1190_1191.port_b.Q_flow + (AIR0CabiA005007004.port.Q_flow + (TC_1191_1192.port_a.Q_flow + (TC_1191_1202.port_a.Q_flow + (TC_1191_1327.port_a.Q_flow + (TC_1191_1506.port_a.Q_flow + TC_1191_1574.port_a.Q_flow)))))) = 0.0; AIR0CabiA005007004.port.T = TC_1190_1191.port_b.T; AIR0CabiA005007004.port.T = TC_1191_1192.port_a.T; AIR0CabiA005007004.port.T = TC_1191_1202.port_a.T; AIR0CabiA005007004.port.T = TC_1191_1327.port_a.T; AIR0CabiA005007004.port.T = TC_1191_1506.port_a.T; AIR0CabiA005007004.port.T = TC_1191_1574.port_a.T; AIR0CabiA005007004.port.T = TsAIR0CabiA005007004.port.T; TsAIR0CabiA004007004.port.Q_flow + (TC_1189_1190.port_b.Q_flow + (AIR0CabiA004007004.port.Q_flow + (TC_1190_1191.port_a.Q_flow + (TC_1190_1201.port_a.Q_flow + (TC_1190_1326.port_a.Q_flow + (TC_1190_1505.port_a.Q_flow + TC_1190_1573.port_a.Q_flow)))))) = 0.0; AIR0CabiA004007004.port.T = TC_1189_1190.port_b.T; AIR0CabiA004007004.port.T = TC_1190_1191.port_a.T; AIR0CabiA004007004.port.T = TC_1190_1201.port_a.T; AIR0CabiA004007004.port.T = TC_1190_1326.port_a.T; AIR0CabiA004007004.port.T = TC_1190_1505.port_a.T; AIR0CabiA004007004.port.T = TC_1190_1573.port_a.T; AIR0CabiA004007004.port.T = TsAIR0CabiA004007004.port.T; TsAIR0CabiA003007004.port.Q_flow + (TC_1188_1189.port_b.Q_flow + (TC_1182_1189.port_b.Q_flow + (AIR0CabiA003007004.port.Q_flow + (TC_1189_1190.port_a.Q_flow + (TC_1189_1200.port_a.Q_flow + (TC_1189_1325.port_a.Q_flow + TC_1189_1572.port_a.Q_flow)))))) = 0.0; AIR0CabiA003007004.port.T = TC_1182_1189.port_b.T; AIR0CabiA003007004.port.T = TC_1188_1189.port_b.T; AIR0CabiA003007004.port.T = TC_1189_1190.port_a.T; AIR0CabiA003007004.port.T = TC_1189_1200.port_a.T; AIR0CabiA003007004.port.T = TC_1189_1325.port_a.T; AIR0CabiA003007004.port.T = TC_1189_1572.port_a.T; AIR0CabiA003007004.port.T = TsAIR0CabiA003007004.port.T; TsAIR0CabiA002007004.port.Q_flow + (TC_1181_1188.port_b.Q_flow + (TC_1118_1188.port_b.Q_flow + (TC_339_1188.port_b.Q_flow + (AIR0CabiA002007004.port.Q_flow + (TC_1188_1189.port_a.Q_flow + (TC_1188_1199.port_a.Q_flow + TC_1188_1324.port_a.Q_flow)))))) = 0.0; AIR0CabiA002007004.port.T = TC_1118_1188.port_b.T; AIR0CabiA002007004.port.T = TC_1181_1188.port_b.T; AIR0CabiA002007004.port.T = TC_1188_1189.port_a.T; AIR0CabiA002007004.port.T = TC_1188_1199.port_a.T; AIR0CabiA002007004.port.T = TC_1188_1324.port_a.T; AIR0CabiA002007004.port.T = TC_339_1188.port_b.T; AIR0CabiA002007004.port.T = TsAIR0CabiA002007004.port.T; TsAIR0CabiA012006004.port.Q_flow + (TC_1186_1187.port_b.Q_flow + (TC_1180_1187.port_b.Q_flow + (TC_1117_1187.port_b.Q_flow + (TC_338_1187.port_b.Q_flow + (AIR0CabiA012006004.port.Q_flow + (TC_1187_1198.port_a.Q_flow + TC_1187_1323.port_a.Q_flow)))))) = 0.0; AIR0CabiA012006004.port.T = TC_1117_1187.port_b.T; AIR0CabiA012006004.port.T = TC_1180_1187.port_b.T; AIR0CabiA012006004.port.T = TC_1186_1187.port_b.T; AIR0CabiA012006004.port.T = TC_1187_1198.port_a.T; AIR0CabiA012006004.port.T = TC_1187_1323.port_a.T; AIR0CabiA012006004.port.T = TC_338_1187.port_b.T; AIR0CabiA012006004.port.T = TsAIR0CabiA012006004.port.T; TsAIR0CabiA011006004.port.Q_flow + (TC_1185_1186.port_b.Q_flow + (TC_1179_1186.port_b.Q_flow + (AIR0CabiA011006004.port.Q_flow + (TC_1186_1187.port_a.Q_flow + (TC_1186_1197.port_a.Q_flow + (TC_1186_1322.port_a.Q_flow + TC_1186_1571.port_a.Q_flow)))))) = 0.0; AIR0CabiA011006004.port.T = TC_1179_1186.port_b.T; AIR0CabiA011006004.port.T = TC_1185_1186.port_b.T; AIR0CabiA011006004.port.T = TC_1186_1187.port_a.T; AIR0CabiA011006004.port.T = TC_1186_1197.port_a.T; AIR0CabiA011006004.port.T = TC_1186_1322.port_a.T; AIR0CabiA011006004.port.T = TC_1186_1571.port_a.T; AIR0CabiA011006004.port.T = TsAIR0CabiA011006004.port.T; TsAIR0CabiA010006004.port.Q_flow + (TC_1184_1185.port_b.Q_flow + (TC_1178_1185.port_b.Q_flow + (AIR0CabiA010006004.port.Q_flow + (TC_1185_1186.port_a.Q_flow + (TC_1185_1196.port_a.Q_flow + (TC_1185_1321.port_a.Q_flow + TC_1185_1570.port_a.Q_flow)))))) = 0.0; AIR0CabiA010006004.port.T = TC_1178_1185.port_b.T; AIR0CabiA010006004.port.T = TC_1184_1185.port_b.T; AIR0CabiA010006004.port.T = TC_1185_1186.port_a.T; AIR0CabiA010006004.port.T = TC_1185_1196.port_a.T; AIR0CabiA010006004.port.T = TC_1185_1321.port_a.T; AIR0CabiA010006004.port.T = TC_1185_1570.port_a.T; AIR0CabiA010006004.port.T = TsAIR0CabiA010006004.port.T; TsAIR0CabiA009006004.port.Q_flow + (TC_1183_1184.port_b.Q_flow + (TC_1177_1184.port_b.Q_flow + (AIR0CabiA009006004.port.Q_flow + (TC_1184_1185.port_a.Q_flow + (TC_1184_1195.port_a.Q_flow + (TC_1184_1320.port_a.Q_flow + TC_1184_1569.port_a.Q_flow)))))) = 0.0; AIR0CabiA009006004.port.T = TC_1177_1184.port_b.T; AIR0CabiA009006004.port.T = TC_1183_1184.port_b.T; AIR0CabiA009006004.port.T = TC_1184_1185.port_a.T; AIR0CabiA009006004.port.T = TC_1184_1195.port_a.T; AIR0CabiA009006004.port.T = TC_1184_1320.port_a.T; AIR0CabiA009006004.port.T = TC_1184_1569.port_a.T; AIR0CabiA009006004.port.T = TsAIR0CabiA009006004.port.T; TsAIR0CabiA008006004.port.Q_flow + (TC_1176_1183.port_b.Q_flow + (AIR0CabiA008006004.port.Q_flow + (TC_1183_1184.port_a.Q_flow + (TC_1183_1194.port_a.Q_flow + (TC_1183_1319.port_a.Q_flow + (TC_1183_1508.port_a.Q_flow + TC_1183_1568.port_a.Q_flow)))))) = 0.0; AIR0CabiA008006004.port.T = TC_1176_1183.port_b.T; AIR0CabiA008006004.port.T = TC_1183_1184.port_a.T; AIR0CabiA008006004.port.T = TC_1183_1194.port_a.T; AIR0CabiA008006004.port.T = TC_1183_1319.port_a.T; AIR0CabiA008006004.port.T = TC_1183_1508.port_a.T; AIR0CabiA008006004.port.T = TC_1183_1568.port_a.T; AIR0CabiA008006004.port.T = TsAIR0CabiA008006004.port.T; TsAIR0CabiA003006004.port.Q_flow + (TC_1181_1182.port_b.Q_flow + (TC_1175_1182.port_b.Q_flow + (AIR0CabiA003006004.port.Q_flow + (TC_1182_1189.port_a.Q_flow + (TC_1182_1314.port_a.Q_flow + (TC_1182_1505.port_a.Q_flow + TC_1182_1563.port_a.Q_flow)))))) = 0.0; AIR0CabiA003006004.port.T = TC_1175_1182.port_b.T; AIR0CabiA003006004.port.T = TC_1181_1182.port_b.T; AIR0CabiA003006004.port.T = TC_1182_1189.port_a.T; AIR0CabiA003006004.port.T = TC_1182_1314.port_a.T; AIR0CabiA003006004.port.T = TC_1182_1505.port_a.T; AIR0CabiA003006004.port.T = TC_1182_1563.port_a.T; AIR0CabiA003006004.port.T = TsAIR0CabiA003006004.port.T; TsAIR0CabiA002006004.port.Q_flow + (TC_1174_1181.port_b.Q_flow + (TC_1116_1181.port_b.Q_flow + (TC_337_1181.port_b.Q_flow + (AIR0CabiA002006004.port.Q_flow + (TC_1181_1182.port_a.Q_flow + (TC_1181_1188.port_a.Q_flow + TC_1181_1313.port_a.Q_flow)))))) = 0.0; AIR0CabiA002006004.port.T = TC_1116_1181.port_b.T; AIR0CabiA002006004.port.T = TC_1174_1181.port_b.T; AIR0CabiA002006004.port.T = TC_1181_1182.port_a.T; AIR0CabiA002006004.port.T = TC_1181_1188.port_a.T; AIR0CabiA002006004.port.T = TC_1181_1313.port_a.T; AIR0CabiA002006004.port.T = TC_337_1181.port_b.T; AIR0CabiA002006004.port.T = TsAIR0CabiA002006004.port.T; TsAIR0CabiA012005004.port.Q_flow + (TC_1179_1180.port_b.Q_flow + (TC_1173_1180.port_b.Q_flow + (TC_1115_1180.port_b.Q_flow + (TC_336_1180.port_b.Q_flow + (AIR0CabiA012005004.port.Q_flow + (TC_1180_1187.port_a.Q_flow + TC_1180_1312.port_a.Q_flow)))))) = 0.0; AIR0CabiA012005004.port.T = TC_1115_1180.port_b.T; AIR0CabiA012005004.port.T = TC_1173_1180.port_b.T; AIR0CabiA012005004.port.T = TC_1179_1180.port_b.T; AIR0CabiA012005004.port.T = TC_1180_1187.port_a.T; AIR0CabiA012005004.port.T = TC_1180_1312.port_a.T; AIR0CabiA012005004.port.T = TC_336_1180.port_b.T; AIR0CabiA012005004.port.T = TsAIR0CabiA012005004.port.T; TsAIR0CabiA011005004.port.Q_flow + (TC_1178_1179.port_b.Q_flow + (TC_1172_1179.port_b.Q_flow + (AIR0CabiA011005004.port.Q_flow + (TC_1179_1180.port_a.Q_flow + (TC_1179_1186.port_a.Q_flow + (TC_1179_1311.port_a.Q_flow + TC_1179_1634.port_a.Q_flow)))))) = 0.0; AIR0CabiA011005004.port.T = TC_1172_1179.port_b.T; AIR0CabiA011005004.port.T = TC_1178_1179.port_b.T; AIR0CabiA011005004.port.T = TC_1179_1180.port_a.T; AIR0CabiA011005004.port.T = TC_1179_1186.port_a.T; AIR0CabiA011005004.port.T = TC_1179_1311.port_a.T; AIR0CabiA011005004.port.T = TC_1179_1634.port_a.T; AIR0CabiA011005004.port.T = TsAIR0CabiA011005004.port.T; TsAIR0CabiA010005004.port.Q_flow + (TC_1177_1178.port_b.Q_flow + (TC_1171_1178.port_b.Q_flow + (AIR0CabiA010005004.port.Q_flow + (TC_1178_1179.port_a.Q_flow + (TC_1178_1185.port_a.Q_flow + (TC_1178_1310.port_a.Q_flow + TC_1178_1633.port_a.Q_flow)))))) = 0.0; AIR0CabiA010005004.port.T = TC_1171_1178.port_b.T; AIR0CabiA010005004.port.T = TC_1177_1178.port_b.T; AIR0CabiA010005004.port.T = TC_1178_1179.port_a.T; AIR0CabiA010005004.port.T = TC_1178_1185.port_a.T; AIR0CabiA010005004.port.T = TC_1178_1310.port_a.T; AIR0CabiA010005004.port.T = TC_1178_1633.port_a.T; AIR0CabiA010005004.port.T = TsAIR0CabiA010005004.port.T; TsAIR0CabiA009005004.port.Q_flow + (TC_1176_1177.port_b.Q_flow + (TC_1170_1177.port_b.Q_flow + (AIR0CabiA009005004.port.Q_flow + (TC_1177_1178.port_a.Q_flow + (TC_1177_1184.port_a.Q_flow + (TC_1177_1309.port_a.Q_flow + TC_1177_1632.port_a.Q_flow)))))) = 0.0; AIR0CabiA009005004.port.T = TC_1170_1177.port_b.T; AIR0CabiA009005004.port.T = TC_1176_1177.port_b.T; AIR0CabiA009005004.port.T = TC_1177_1178.port_a.T; AIR0CabiA009005004.port.T = TC_1177_1184.port_a.T; AIR0CabiA009005004.port.T = TC_1177_1309.port_a.T; AIR0CabiA009005004.port.T = TC_1177_1632.port_a.T; AIR0CabiA009005004.port.T = TsAIR0CabiA009005004.port.T; TsAIR0CabiA008005004.port.Q_flow + (TC_1169_1176.port_b.Q_flow + (AIR0CabiA008005004.port.Q_flow + (TC_1176_1177.port_a.Q_flow + (TC_1176_1183.port_a.Q_flow + (TC_1176_1308.port_a.Q_flow + (TC_1176_1504.port_a.Q_flow + TC_1176_1631.port_a.Q_flow)))))) = 0.0; AIR0CabiA008005004.port.T = TC_1169_1176.port_b.T; AIR0CabiA008005004.port.T = TC_1176_1177.port_a.T; AIR0CabiA008005004.port.T = TC_1176_1183.port_a.T; AIR0CabiA008005004.port.T = TC_1176_1308.port_a.T; AIR0CabiA008005004.port.T = TC_1176_1504.port_a.T; AIR0CabiA008005004.port.T = TC_1176_1631.port_a.T; AIR0CabiA008005004.port.T = TsAIR0CabiA008005004.port.T; TsAIR0CabiA003005004.port.Q_flow + (TC_1174_1175.port_b.Q_flow + (TC_1168_1175.port_b.Q_flow + (AIR0CabiA003005004.port.Q_flow + (TC_1175_1182.port_a.Q_flow + (TC_1175_1303.port_a.Q_flow + (TC_1175_1501.port_a.Q_flow + TC_1175_1626.port_a.Q_flow)))))) = 0.0; AIR0CabiA003005004.port.T = TC_1168_1175.port_b.T; AIR0CabiA003005004.port.T = TC_1174_1175.port_b.T; AIR0CabiA003005004.port.T = TC_1175_1182.port_a.T; AIR0CabiA003005004.port.T = TC_1175_1303.port_a.T; AIR0CabiA003005004.port.T = TC_1175_1501.port_a.T; AIR0CabiA003005004.port.T = TC_1175_1626.port_a.T; AIR0CabiA003005004.port.T = TsAIR0CabiA003005004.port.T; TsAIR0CabiA002005004.port.Q_flow + (TC_1167_1174.port_b.Q_flow + (TC_1114_1174.port_b.Q_flow + (TC_335_1174.port_b.Q_flow + (AIR0CabiA002005004.port.Q_flow + (TC_1174_1175.port_a.Q_flow + (TC_1174_1181.port_a.Q_flow + TC_1174_1302.port_a.Q_flow)))))) = 0.0; AIR0CabiA002005004.port.T = TC_1114_1174.port_b.T; AIR0CabiA002005004.port.T = TC_1167_1174.port_b.T; AIR0CabiA002005004.port.T = TC_1174_1175.port_a.T; AIR0CabiA002005004.port.T = TC_1174_1181.port_a.T; AIR0CabiA002005004.port.T = TC_1174_1302.port_a.T; AIR0CabiA002005004.port.T = TC_335_1174.port_b.T; AIR0CabiA002005004.port.T = TsAIR0CabiA002005004.port.T; TsAIR0CabiA012004004.port.Q_flow + (TC_1172_1173.port_b.Q_flow + (TC_1166_1173.port_b.Q_flow + (TC_1113_1173.port_b.Q_flow + (TC_334_1173.port_b.Q_flow + (AIR0CabiA012004004.port.Q_flow + (TC_1173_1180.port_a.Q_flow + TC_1173_1301.port_a.Q_flow)))))) = 0.0; AIR0CabiA012004004.port.T = TC_1113_1173.port_b.T; AIR0CabiA012004004.port.T = TC_1166_1173.port_b.T; AIR0CabiA012004004.port.T = TC_1172_1173.port_b.T; AIR0CabiA012004004.port.T = TC_1173_1180.port_a.T; AIR0CabiA012004004.port.T = TC_1173_1301.port_a.T; AIR0CabiA012004004.port.T = TC_334_1173.port_b.T; AIR0CabiA012004004.port.T = TsAIR0CabiA012004004.port.T; TsAIR0CabiA011004004.port.Q_flow + (TC_1171_1172.port_b.Q_flow + (TC_1165_1172.port_b.Q_flow + (AIR0CabiA011004004.port.Q_flow + (TC_1172_1173.port_a.Q_flow + (TC_1172_1179.port_a.Q_flow + (TC_1172_1300.port_a.Q_flow + TC_1172_1625.port_a.Q_flow)))))) = 0.0; AIR0CabiA011004004.port.T = TC_1165_1172.port_b.T; AIR0CabiA011004004.port.T = TC_1171_1172.port_b.T; AIR0CabiA011004004.port.T = TC_1172_1173.port_a.T; AIR0CabiA011004004.port.T = TC_1172_1179.port_a.T; AIR0CabiA011004004.port.T = TC_1172_1300.port_a.T; AIR0CabiA011004004.port.T = TC_1172_1625.port_a.T; AIR0CabiA011004004.port.T = TsAIR0CabiA011004004.port.T; TsAIR0CabiA010004004.port.Q_flow + (TC_1170_1171.port_b.Q_flow + (TC_1164_1171.port_b.Q_flow + (AIR0CabiA010004004.port.Q_flow + (TC_1171_1172.port_a.Q_flow + (TC_1171_1178.port_a.Q_flow + (TC_1171_1299.port_a.Q_flow + TC_1171_1624.port_a.Q_flow)))))) = 0.0; AIR0CabiA010004004.port.T = TC_1164_1171.port_b.T; AIR0CabiA010004004.port.T = TC_1170_1171.port_b.T; AIR0CabiA010004004.port.T = TC_1171_1172.port_a.T; AIR0CabiA010004004.port.T = TC_1171_1178.port_a.T; AIR0CabiA010004004.port.T = TC_1171_1299.port_a.T; AIR0CabiA010004004.port.T = TC_1171_1624.port_a.T; AIR0CabiA010004004.port.T = TsAIR0CabiA010004004.port.T; TsAIR0CabiA009004004.port.Q_flow + (TC_1169_1170.port_b.Q_flow + (TC_1163_1170.port_b.Q_flow + (AIR0CabiA009004004.port.Q_flow + (TC_1170_1171.port_a.Q_flow + (TC_1170_1177.port_a.Q_flow + (TC_1170_1298.port_a.Q_flow + TC_1170_1623.port_a.Q_flow)))))) = 0.0; AIR0CabiA009004004.port.T = TC_1163_1170.port_b.T; AIR0CabiA009004004.port.T = TC_1169_1170.port_b.T; AIR0CabiA009004004.port.T = TC_1170_1171.port_a.T; AIR0CabiA009004004.port.T = TC_1170_1177.port_a.T; AIR0CabiA009004004.port.T = TC_1170_1298.port_a.T; AIR0CabiA009004004.port.T = TC_1170_1623.port_a.T; AIR0CabiA009004004.port.T = TsAIR0CabiA009004004.port.T; TsAIR0CabiA008004004.port.Q_flow + (TC_1162_1169.port_b.Q_flow + (AIR0CabiA008004004.port.Q_flow + (TC_1169_1170.port_a.Q_flow + (TC_1169_1176.port_a.Q_flow + (TC_1169_1297.port_a.Q_flow + (TC_1169_1500.port_a.Q_flow + TC_1169_1622.port_a.Q_flow)))))) = 0.0; AIR0CabiA008004004.port.T = TC_1162_1169.port_b.T; AIR0CabiA008004004.port.T = TC_1169_1170.port_a.T; AIR0CabiA008004004.port.T = TC_1169_1176.port_a.T; AIR0CabiA008004004.port.T = TC_1169_1297.port_a.T; AIR0CabiA008004004.port.T = TC_1169_1500.port_a.T; AIR0CabiA008004004.port.T = TC_1169_1622.port_a.T; AIR0CabiA008004004.port.T = TsAIR0CabiA008004004.port.T; TsAIR0CabiA003004004.port.Q_flow + (TC_1167_1168.port_b.Q_flow + (TC_1157_1168.port_b.Q_flow + (AIR0CabiA003004004.port.Q_flow + (TC_1168_1175.port_a.Q_flow + (TC_1168_1292.port_a.Q_flow + (TC_1168_1497.port_a.Q_flow + TC_1168_1617.port_a.Q_flow)))))) = 0.0; AIR0CabiA003004004.port.T = TC_1157_1168.port_b.T; AIR0CabiA003004004.port.T = TC_1167_1168.port_b.T; AIR0CabiA003004004.port.T = TC_1168_1175.port_a.T; AIR0CabiA003004004.port.T = TC_1168_1292.port_a.T; AIR0CabiA003004004.port.T = TC_1168_1497.port_a.T; AIR0CabiA003004004.port.T = TC_1168_1617.port_a.T; AIR0CabiA003004004.port.T = TsAIR0CabiA003004004.port.T; TsAIR0CabiA002004004.port.Q_flow + (TC_1156_1167.port_b.Q_flow + (TC_1112_1167.port_b.Q_flow + (TC_333_1167.port_b.Q_flow + (AIR0CabiA002004004.port.Q_flow + (TC_1167_1168.port_a.Q_flow + (TC_1167_1174.port_a.Q_flow + TC_1167_1291.port_a.Q_flow)))))) = 0.0; AIR0CabiA002004004.port.T = TC_1112_1167.port_b.T; AIR0CabiA002004004.port.T = TC_1156_1167.port_b.T; AIR0CabiA002004004.port.T = TC_1167_1168.port_a.T; AIR0CabiA002004004.port.T = TC_1167_1174.port_a.T; AIR0CabiA002004004.port.T = TC_1167_1291.port_a.T; AIR0CabiA002004004.port.T = TC_333_1167.port_b.T; AIR0CabiA002004004.port.T = TsAIR0CabiA002004004.port.T; TsAIR0CabiA012003004.port.Q_flow + (TC_1165_1166.port_b.Q_flow + (TC_1155_1166.port_b.Q_flow + (TC_1111_1166.port_b.Q_flow + (TC_332_1166.port_b.Q_flow + (AIR0CabiA012003004.port.Q_flow + (TC_1166_1173.port_a.Q_flow + TC_1166_1290.port_a.Q_flow)))))) = 0.0; AIR0CabiA012003004.port.T = TC_1111_1166.port_b.T; AIR0CabiA012003004.port.T = TC_1155_1166.port_b.T; AIR0CabiA012003004.port.T = TC_1165_1166.port_b.T; AIR0CabiA012003004.port.T = TC_1166_1173.port_a.T; AIR0CabiA012003004.port.T = TC_1166_1290.port_a.T; AIR0CabiA012003004.port.T = TC_332_1166.port_b.T; AIR0CabiA012003004.port.T = TsAIR0CabiA012003004.port.T; TsAIR0CabiA011003004.port.Q_flow + (TC_1164_1165.port_b.Q_flow + (TC_1154_1165.port_b.Q_flow + (AIR0CabiA011003004.port.Q_flow + (TC_1165_1166.port_a.Q_flow + (TC_1165_1172.port_a.Q_flow + (TC_1165_1289.port_a.Q_flow + TC_1165_1616.port_a.Q_flow)))))) = 0.0; AIR0CabiA011003004.port.T = TC_1154_1165.port_b.T; AIR0CabiA011003004.port.T = TC_1164_1165.port_b.T; AIR0CabiA011003004.port.T = TC_1165_1166.port_a.T; AIR0CabiA011003004.port.T = TC_1165_1172.port_a.T; AIR0CabiA011003004.port.T = TC_1165_1289.port_a.T; AIR0CabiA011003004.port.T = TC_1165_1616.port_a.T; AIR0CabiA011003004.port.T = TsAIR0CabiA011003004.port.T; TsAIR0CabiA010003004.port.Q_flow + (TC_1163_1164.port_b.Q_flow + (TC_1153_1164.port_b.Q_flow + (AIR0CabiA010003004.port.Q_flow + (TC_1164_1165.port_a.Q_flow + (TC_1164_1171.port_a.Q_flow + (TC_1164_1288.port_a.Q_flow + TC_1164_1615.port_a.Q_flow)))))) = 0.0; AIR0CabiA010003004.port.T = TC_1153_1164.port_b.T; AIR0CabiA010003004.port.T = TC_1163_1164.port_b.T; AIR0CabiA010003004.port.T = TC_1164_1165.port_a.T; AIR0CabiA010003004.port.T = TC_1164_1171.port_a.T; AIR0CabiA010003004.port.T = TC_1164_1288.port_a.T; AIR0CabiA010003004.port.T = TC_1164_1615.port_a.T; AIR0CabiA010003004.port.T = TsAIR0CabiA010003004.port.T; TsAIR0CabiA009003004.port.Q_flow + (TC_1162_1163.port_b.Q_flow + (TC_1152_1163.port_b.Q_flow + (AIR0CabiA009003004.port.Q_flow + (TC_1163_1164.port_a.Q_flow + (TC_1163_1170.port_a.Q_flow + (TC_1163_1287.port_a.Q_flow + TC_1163_1614.port_a.Q_flow)))))) = 0.0; AIR0CabiA009003004.port.T = TC_1152_1163.port_b.T; AIR0CabiA009003004.port.T = TC_1162_1163.port_b.T; AIR0CabiA009003004.port.T = TC_1163_1164.port_a.T; AIR0CabiA009003004.port.T = TC_1163_1170.port_a.T; AIR0CabiA009003004.port.T = TC_1163_1287.port_a.T; AIR0CabiA009003004.port.T = TC_1163_1614.port_a.T; AIR0CabiA009003004.port.T = TsAIR0CabiA009003004.port.T; TsAIR0CabiA008003004.port.Q_flow + (TC_1161_1162.port_b.Q_flow + (TC_1151_1162.port_b.Q_flow + (AIR0CabiA008003004.port.Q_flow + (TC_1162_1163.port_a.Q_flow + (TC_1162_1169.port_a.Q_flow + (TC_1162_1286.port_a.Q_flow + TC_1162_1613.port_a.Q_flow)))))) = 0.0; AIR0CabiA008003004.port.T = TC_1151_1162.port_b.T; AIR0CabiA008003004.port.T = TC_1161_1162.port_b.T; AIR0CabiA008003004.port.T = TC_1162_1163.port_a.T; AIR0CabiA008003004.port.T = TC_1162_1169.port_a.T; AIR0CabiA008003004.port.T = TC_1162_1286.port_a.T; AIR0CabiA008003004.port.T = TC_1162_1613.port_a.T; AIR0CabiA008003004.port.T = TsAIR0CabiA008003004.port.T; TsAIR0CabiA007003004.port.Q_flow + (TC_1160_1161.port_b.Q_flow + (TC_1150_1161.port_b.Q_flow + (AIR0CabiA007003004.port.Q_flow + (TC_1161_1162.port_a.Q_flow + (TC_1161_1285.port_a.Q_flow + (TC_1161_1500.port_a.Q_flow + TC_1161_1612.port_a.Q_flow)))))) = 0.0; AIR0CabiA007003004.port.T = TC_1150_1161.port_b.T; AIR0CabiA007003004.port.T = TC_1160_1161.port_b.T; AIR0CabiA007003004.port.T = TC_1161_1162.port_a.T; AIR0CabiA007003004.port.T = TC_1161_1285.port_a.T; AIR0CabiA007003004.port.T = TC_1161_1500.port_a.T; AIR0CabiA007003004.port.T = TC_1161_1612.port_a.T; AIR0CabiA007003004.port.T = TsAIR0CabiA007003004.port.T; TsAIR0CabiA006003004.port.Q_flow + (TC_1159_1160.port_b.Q_flow + (TC_1149_1160.port_b.Q_flow + (AIR0CabiA006003004.port.Q_flow + (TC_1160_1161.port_a.Q_flow + (TC_1160_1284.port_a.Q_flow + (TC_1160_1499.port_a.Q_flow + TC_1160_1611.port_a.Q_flow)))))) = 0.0; AIR0CabiA006003004.port.T = TC_1149_1160.port_b.T; AIR0CabiA006003004.port.T = TC_1159_1160.port_b.T; AIR0CabiA006003004.port.T = TC_1160_1161.port_a.T; AIR0CabiA006003004.port.T = TC_1160_1284.port_a.T; AIR0CabiA006003004.port.T = TC_1160_1499.port_a.T; AIR0CabiA006003004.port.T = TC_1160_1611.port_a.T; AIR0CabiA006003004.port.T = TsAIR0CabiA006003004.port.T; TsAIR0CabiA005003004.port.Q_flow + (TC_1158_1159.port_b.Q_flow + (TC_1148_1159.port_b.Q_flow + (AIR0CabiA005003004.port.Q_flow + (TC_1159_1160.port_a.Q_flow + (TC_1159_1283.port_a.Q_flow + (TC_1159_1498.port_a.Q_flow + TC_1159_1610.port_a.Q_flow)))))) = 0.0; AIR0CabiA005003004.port.T = TC_1148_1159.port_b.T; AIR0CabiA005003004.port.T = TC_1158_1159.port_b.T; AIR0CabiA005003004.port.T = TC_1159_1160.port_a.T; AIR0CabiA005003004.port.T = TC_1159_1283.port_a.T; AIR0CabiA005003004.port.T = TC_1159_1498.port_a.T; AIR0CabiA005003004.port.T = TC_1159_1610.port_a.T; AIR0CabiA005003004.port.T = TsAIR0CabiA005003004.port.T; TsAIR0CabiA004003004.port.Q_flow + (TC_1157_1158.port_b.Q_flow + (TC_1147_1158.port_b.Q_flow + (AIR0CabiA004003004.port.Q_flow + (TC_1158_1159.port_a.Q_flow + (TC_1158_1282.port_a.Q_flow + (TC_1158_1497.port_a.Q_flow + TC_1158_1609.port_a.Q_flow)))))) = 0.0; AIR0CabiA004003004.port.T = TC_1147_1158.port_b.T; AIR0CabiA004003004.port.T = TC_1157_1158.port_b.T; AIR0CabiA004003004.port.T = TC_1158_1159.port_a.T; AIR0CabiA004003004.port.T = TC_1158_1282.port_a.T; AIR0CabiA004003004.port.T = TC_1158_1497.port_a.T; AIR0CabiA004003004.port.T = TC_1158_1609.port_a.T; AIR0CabiA004003004.port.T = TsAIR0CabiA004003004.port.T; TsAIR0CabiA003003004.port.Q_flow + (TC_1156_1157.port_b.Q_flow + (TC_1146_1157.port_b.Q_flow + (AIR0CabiA003003004.port.Q_flow + (TC_1157_1158.port_a.Q_flow + (TC_1157_1168.port_a.Q_flow + (TC_1157_1281.port_a.Q_flow + TC_1157_1608.port_a.Q_flow)))))) = 0.0; AIR0CabiA003003004.port.T = TC_1146_1157.port_b.T; AIR0CabiA003003004.port.T = TC_1156_1157.port_b.T; AIR0CabiA003003004.port.T = TC_1157_1158.port_a.T; AIR0CabiA003003004.port.T = TC_1157_1168.port_a.T; AIR0CabiA003003004.port.T = TC_1157_1281.port_a.T; AIR0CabiA003003004.port.T = TC_1157_1608.port_a.T; AIR0CabiA003003004.port.T = TsAIR0CabiA003003004.port.T; TsAIR0CabiA002003004.port.Q_flow + (TC_1145_1156.port_b.Q_flow + (TC_1110_1156.port_b.Q_flow + (TC_331_1156.port_b.Q_flow + (AIR0CabiA002003004.port.Q_flow + (TC_1156_1157.port_a.Q_flow + (TC_1156_1167.port_a.Q_flow + TC_1156_1280.port_a.Q_flow)))))) = 0.0; AIR0CabiA002003004.port.T = TC_1110_1156.port_b.T; AIR0CabiA002003004.port.T = TC_1145_1156.port_b.T; AIR0CabiA002003004.port.T = TC_1156_1157.port_a.T; AIR0CabiA002003004.port.T = TC_1156_1167.port_a.T; AIR0CabiA002003004.port.T = TC_1156_1280.port_a.T; AIR0CabiA002003004.port.T = TC_331_1156.port_b.T; AIR0CabiA002003004.port.T = TsAIR0CabiA002003004.port.T; TsAIR0CabiA012002004.port.Q_flow + (TC_1154_1155.port_b.Q_flow + (TC_1109_1155.port_b.Q_flow + (TC_330_1155.port_b.Q_flow + (TC_327_1155.port_b.Q_flow + (AIR0CabiA012002004.port.Q_flow + (TC_1155_1166.port_a.Q_flow + TC_1155_1279.port_a.Q_flow)))))) = 0.0; AIR0CabiA012002004.port.T = TC_1109_1155.port_b.T; AIR0CabiA012002004.port.T = TC_1154_1155.port_b.T; AIR0CabiA012002004.port.T = TC_1155_1166.port_a.T; AIR0CabiA012002004.port.T = TC_1155_1279.port_a.T; AIR0CabiA012002004.port.T = TC_327_1155.port_b.T; AIR0CabiA012002004.port.T = TC_330_1155.port_b.T; AIR0CabiA012002004.port.T = TsAIR0CabiA012002004.port.T; TsAIR0CabiA011002004.port.Q_flow + (TC_1153_1154.port_b.Q_flow + (TC_1108_1154.port_b.Q_flow + (TC_326_1154.port_b.Q_flow + (AIR0CabiA011002004.port.Q_flow + (TC_1154_1155.port_a.Q_flow + (TC_1154_1165.port_a.Q_flow + TC_1154_1278.port_a.Q_flow)))))) = 0.0; AIR0CabiA011002004.port.T = TC_1108_1154.port_b.T; AIR0CabiA011002004.port.T = TC_1153_1154.port_b.T; AIR0CabiA011002004.port.T = TC_1154_1155.port_a.T; AIR0CabiA011002004.port.T = TC_1154_1165.port_a.T; AIR0CabiA011002004.port.T = TC_1154_1278.port_a.T; AIR0CabiA011002004.port.T = TC_326_1154.port_b.T; AIR0CabiA011002004.port.T = TsAIR0CabiA011002004.port.T; TsAIR0CabiA010002004.port.Q_flow + (TC_1152_1153.port_b.Q_flow + (TC_1107_1153.port_b.Q_flow + (TC_325_1153.port_b.Q_flow + (AIR0CabiA010002004.port.Q_flow + (TC_1153_1154.port_a.Q_flow + (TC_1153_1164.port_a.Q_flow + TC_1153_1277.port_a.Q_flow)))))) = 0.0; AIR0CabiA010002004.port.T = TC_1107_1153.port_b.T; AIR0CabiA010002004.port.T = TC_1152_1153.port_b.T; AIR0CabiA010002004.port.T = TC_1153_1154.port_a.T; AIR0CabiA010002004.port.T = TC_1153_1164.port_a.T; AIR0CabiA010002004.port.T = TC_1153_1277.port_a.T; AIR0CabiA010002004.port.T = TC_325_1153.port_b.T; AIR0CabiA010002004.port.T = TsAIR0CabiA010002004.port.T; TsAIR0CabiA009002004.port.Q_flow + (TC_1151_1152.port_b.Q_flow + (TC_1106_1152.port_b.Q_flow + (TC_324_1152.port_b.Q_flow + (AIR0CabiA009002004.port.Q_flow + (TC_1152_1153.port_a.Q_flow + (TC_1152_1163.port_a.Q_flow + TC_1152_1276.port_a.Q_flow)))))) = 0.0; AIR0CabiA009002004.port.T = TC_1106_1152.port_b.T; AIR0CabiA009002004.port.T = TC_1151_1152.port_b.T; AIR0CabiA009002004.port.T = TC_1152_1153.port_a.T; AIR0CabiA009002004.port.T = TC_1152_1163.port_a.T; AIR0CabiA009002004.port.T = TC_1152_1276.port_a.T; AIR0CabiA009002004.port.T = TC_324_1152.port_b.T; AIR0CabiA009002004.port.T = TsAIR0CabiA009002004.port.T; TsAIR0CabiA008002004.port.Q_flow + (TC_1150_1151.port_b.Q_flow + (TC_1105_1151.port_b.Q_flow + (TC_323_1151.port_b.Q_flow + (AIR0CabiA008002004.port.Q_flow + (TC_1151_1152.port_a.Q_flow + (TC_1151_1162.port_a.Q_flow + TC_1151_1275.port_a.Q_flow)))))) = 0.0; AIR0CabiA008002004.port.T = TC_1105_1151.port_b.T; AIR0CabiA008002004.port.T = TC_1150_1151.port_b.T; AIR0CabiA008002004.port.T = TC_1151_1152.port_a.T; AIR0CabiA008002004.port.T = TC_1151_1162.port_a.T; AIR0CabiA008002004.port.T = TC_1151_1275.port_a.T; AIR0CabiA008002004.port.T = TC_323_1151.port_b.T; AIR0CabiA008002004.port.T = TsAIR0CabiA008002004.port.T; TsAIR0CabiA007002004.port.Q_flow + (TC_1149_1150.port_b.Q_flow + (TC_1104_1150.port_b.Q_flow + (TC_322_1150.port_b.Q_flow + (AIR0CabiA007002004.port.Q_flow + (TC_1150_1151.port_a.Q_flow + (TC_1150_1161.port_a.Q_flow + TC_1150_1274.port_a.Q_flow)))))) = 0.0; AIR0CabiA007002004.port.T = TC_1104_1150.port_b.T; AIR0CabiA007002004.port.T = TC_1149_1150.port_b.T; AIR0CabiA007002004.port.T = TC_1150_1151.port_a.T; AIR0CabiA007002004.port.T = TC_1150_1161.port_a.T; AIR0CabiA007002004.port.T = TC_1150_1274.port_a.T; AIR0CabiA007002004.port.T = TC_322_1150.port_b.T; AIR0CabiA007002004.port.T = TsAIR0CabiA007002004.port.T; TsAIR0CabiA006002004.port.Q_flow + (TC_1148_1149.port_b.Q_flow + (TC_1103_1149.port_b.Q_flow + (TC_321_1149.port_b.Q_flow + (AIR0CabiA006002004.port.Q_flow + (TC_1149_1150.port_a.Q_flow + (TC_1149_1160.port_a.Q_flow + TC_1149_1273.port_a.Q_flow)))))) = 0.0; AIR0CabiA006002004.port.T = TC_1103_1149.port_b.T; AIR0CabiA006002004.port.T = TC_1148_1149.port_b.T; AIR0CabiA006002004.port.T = TC_1149_1150.port_a.T; AIR0CabiA006002004.port.T = TC_1149_1160.port_a.T; AIR0CabiA006002004.port.T = TC_1149_1273.port_a.T; AIR0CabiA006002004.port.T = TC_321_1149.port_b.T; AIR0CabiA006002004.port.T = TsAIR0CabiA006002004.port.T; TsAIR0CabiA005002004.port.Q_flow + (TC_1147_1148.port_b.Q_flow + (TC_1102_1148.port_b.Q_flow + (TC_320_1148.port_b.Q_flow + (AIR0CabiA005002004.port.Q_flow + (TC_1148_1149.port_a.Q_flow + (TC_1148_1159.port_a.Q_flow + TC_1148_1272.port_a.Q_flow)))))) = 0.0; AIR0CabiA005002004.port.T = TC_1102_1148.port_b.T; AIR0CabiA005002004.port.T = TC_1147_1148.port_b.T; AIR0CabiA005002004.port.T = TC_1148_1149.port_a.T; AIR0CabiA005002004.port.T = TC_1148_1159.port_a.T; AIR0CabiA005002004.port.T = TC_1148_1272.port_a.T; AIR0CabiA005002004.port.T = TC_320_1148.port_b.T; AIR0CabiA005002004.port.T = TsAIR0CabiA005002004.port.T; TsAIR0CabiA004002004.port.Q_flow + (TC_1146_1147.port_b.Q_flow + (TC_1101_1147.port_b.Q_flow + (TC_319_1147.port_b.Q_flow + (AIR0CabiA004002004.port.Q_flow + (TC_1147_1148.port_a.Q_flow + (TC_1147_1158.port_a.Q_flow + TC_1147_1271.port_a.Q_flow)))))) = 0.0; AIR0CabiA004002004.port.T = TC_1101_1147.port_b.T; AIR0CabiA004002004.port.T = TC_1146_1147.port_b.T; AIR0CabiA004002004.port.T = TC_1147_1148.port_a.T; AIR0CabiA004002004.port.T = TC_1147_1158.port_a.T; AIR0CabiA004002004.port.T = TC_1147_1271.port_a.T; AIR0CabiA004002004.port.T = TC_319_1147.port_b.T; AIR0CabiA004002004.port.T = TsAIR0CabiA004002004.port.T; TsAIR0CabiA003002004.port.Q_flow + (TC_1145_1146.port_b.Q_flow + (TC_1100_1146.port_b.Q_flow + (TC_318_1146.port_b.Q_flow + (AIR0CabiA003002004.port.Q_flow + (TC_1146_1147.port_a.Q_flow + (TC_1146_1157.port_a.Q_flow + TC_1146_1270.port_a.Q_flow)))))) = 0.0; AIR0CabiA003002004.port.T = TC_1100_1146.port_b.T; AIR0CabiA003002004.port.T = TC_1145_1146.port_b.T; AIR0CabiA003002004.port.T = TC_1146_1147.port_a.T; AIR0CabiA003002004.port.T = TC_1146_1157.port_a.T; AIR0CabiA003002004.port.T = TC_1146_1270.port_a.T; AIR0CabiA003002004.port.T = TC_318_1146.port_b.T; AIR0CabiA003002004.port.T = TsAIR0CabiA003002004.port.T; TsAIR0CabiA002002004.port.Q_flow + (TC_1099_1145.port_b.Q_flow + (TC_329_1145.port_b.Q_flow + (TC_317_1145.port_b.Q_flow + (AIR0CabiA002002004.port.Q_flow + (TC_1145_1146.port_a.Q_flow + (TC_1145_1156.port_a.Q_flow + TC_1145_1269.port_a.Q_flow)))))) = 0.0; AIR0CabiA002002004.port.T = TC_1099_1145.port_b.T; AIR0CabiA002002004.port.T = TC_1145_1146.port_a.T; AIR0CabiA002002004.port.T = TC_1145_1156.port_a.T; AIR0CabiA002002004.port.T = TC_1145_1269.port_a.T; AIR0CabiA002002004.port.T = TC_317_1145.port_b.T; AIR0CabiA002002004.port.T = TC_329_1145.port_b.T; AIR0CabiA002002004.port.T = TsAIR0CabiA002002004.port.T; TsAIR0CabiA012015005.port.Q_flow + (TC_1143_1144.port_b.Q_flow + (TC_1133_1144.port_b.Q_flow + (TC_1027_1144.port_b.Q_flow + (TC_314_1144.port_b.Q_flow + (TC_302_1144.port_b.Q_flow + (AIR0CabiA012015005.port.Q_flow + TC_1144_1268.port_a.Q_flow)))))) = 0.0; AIR0CabiA012015005.port.T = TC_1027_1144.port_b.T; AIR0CabiA012015005.port.T = TC_1133_1144.port_b.T; AIR0CabiA012015005.port.T = TC_1143_1144.port_b.T; AIR0CabiA012015005.port.T = TC_1144_1268.port_a.T; AIR0CabiA012015005.port.T = TC_302_1144.port_b.T; AIR0CabiA012015005.port.T = TC_314_1144.port_b.T; AIR0CabiA012015005.port.T = TsAIR0CabiA012015005.port.T; TsAIR0CabiA011015005.port.Q_flow + (TC_1142_1143.port_b.Q_flow + (TC_1026_1143.port_b.Q_flow + (TC_313_1143.port_b.Q_flow + (AIR0CabiA011015005.port.Q_flow + (TC_1143_1144.port_a.Q_flow + (TC_1143_1267.port_a.Q_flow + TC_1143_1562.port_a.Q_flow)))))) = 0.0; AIR0CabiA011015005.port.T = TC_1026_1143.port_b.T; AIR0CabiA011015005.port.T = TC_1142_1143.port_b.T; AIR0CabiA011015005.port.T = TC_1143_1144.port_a.T; AIR0CabiA011015005.port.T = TC_1143_1267.port_a.T; AIR0CabiA011015005.port.T = TC_1143_1562.port_a.T; AIR0CabiA011015005.port.T = TC_313_1143.port_b.T; AIR0CabiA011015005.port.T = TsAIR0CabiA011015005.port.T; TsAIR0CabiA010015005.port.Q_flow + (TC_1141_1142.port_b.Q_flow + (TC_1025_1142.port_b.Q_flow + (TC_312_1142.port_b.Q_flow + (AIR0CabiA010015005.port.Q_flow + (TC_1142_1143.port_a.Q_flow + (TC_1142_1266.port_a.Q_flow + TC_1142_1561.port_a.Q_flow)))))) = 0.0; AIR0CabiA010015005.port.T = TC_1025_1142.port_b.T; AIR0CabiA010015005.port.T = TC_1141_1142.port_b.T; AIR0CabiA010015005.port.T = TC_1142_1143.port_a.T; AIR0CabiA010015005.port.T = TC_1142_1266.port_a.T; AIR0CabiA010015005.port.T = TC_1142_1561.port_a.T; AIR0CabiA010015005.port.T = TC_312_1142.port_b.T; AIR0CabiA010015005.port.T = TsAIR0CabiA010015005.port.T; TsAIR0CabiA009015005.port.Q_flow + (TC_1140_1141.port_b.Q_flow + (TC_1024_1141.port_b.Q_flow + (TC_311_1141.port_b.Q_flow + (AIR0CabiA009015005.port.Q_flow + (TC_1141_1142.port_a.Q_flow + (TC_1141_1265.port_a.Q_flow + TC_1141_1560.port_a.Q_flow)))))) = 0.0; AIR0CabiA009015005.port.T = TC_1024_1141.port_b.T; AIR0CabiA009015005.port.T = TC_1140_1141.port_b.T; AIR0CabiA009015005.port.T = TC_1141_1142.port_a.T; AIR0CabiA009015005.port.T = TC_1141_1265.port_a.T; AIR0CabiA009015005.port.T = TC_1141_1560.port_a.T; AIR0CabiA009015005.port.T = TC_311_1141.port_b.T; AIR0CabiA009015005.port.T = TsAIR0CabiA009015005.port.T; TsAIR0CabiA008015005.port.Q_flow + (TC_1139_1140.port_b.Q_flow + (TC_1023_1140.port_b.Q_flow + (TC_310_1140.port_b.Q_flow + (AIR0CabiA008015005.port.Q_flow + (TC_1140_1141.port_a.Q_flow + (TC_1140_1264.port_a.Q_flow + TC_1140_1559.port_a.Q_flow)))))) = 0.0; AIR0CabiA008015005.port.T = TC_1023_1140.port_b.T; AIR0CabiA008015005.port.T = TC_1139_1140.port_b.T; AIR0CabiA008015005.port.T = TC_1140_1141.port_a.T; AIR0CabiA008015005.port.T = TC_1140_1264.port_a.T; AIR0CabiA008015005.port.T = TC_1140_1559.port_a.T; AIR0CabiA008015005.port.T = TC_310_1140.port_b.T; AIR0CabiA008015005.port.T = TsAIR0CabiA008015005.port.T; TsAIR0CabiA007015005.port.Q_flow + (TC_1138_1139.port_b.Q_flow + (TC_1022_1139.port_b.Q_flow + (TC_309_1139.port_b.Q_flow + (AIR0CabiA007015005.port.Q_flow + (TC_1139_1140.port_a.Q_flow + (TC_1139_1263.port_a.Q_flow + TC_1139_1558.port_a.Q_flow)))))) = 0.0; AIR0CabiA007015005.port.T = TC_1022_1139.port_b.T; AIR0CabiA007015005.port.T = TC_1138_1139.port_b.T; AIR0CabiA007015005.port.T = TC_1139_1140.port_a.T; AIR0CabiA007015005.port.T = TC_1139_1263.port_a.T; AIR0CabiA007015005.port.T = TC_1139_1558.port_a.T; AIR0CabiA007015005.port.T = TC_309_1139.port_b.T; AIR0CabiA007015005.port.T = TsAIR0CabiA007015005.port.T; TsAIR0CabiA006015005.port.Q_flow + (TC_1137_1138.port_b.Q_flow + (TC_1021_1138.port_b.Q_flow + (TC_308_1138.port_b.Q_flow + (AIR0CabiA006015005.port.Q_flow + (TC_1138_1139.port_a.Q_flow + (TC_1138_1262.port_a.Q_flow + TC_1138_1557.port_a.Q_flow)))))) = 0.0; AIR0CabiA006015005.port.T = TC_1021_1138.port_b.T; AIR0CabiA006015005.port.T = TC_1137_1138.port_b.T; AIR0CabiA006015005.port.T = TC_1138_1139.port_a.T; AIR0CabiA006015005.port.T = TC_1138_1262.port_a.T; AIR0CabiA006015005.port.T = TC_1138_1557.port_a.T; AIR0CabiA006015005.port.T = TC_308_1138.port_b.T; AIR0CabiA006015005.port.T = TsAIR0CabiA006015005.port.T; TsAIR0CabiA005015005.port.Q_flow + (TC_1136_1137.port_b.Q_flow + (TC_1020_1137.port_b.Q_flow + (TC_307_1137.port_b.Q_flow + (AIR0CabiA005015005.port.Q_flow + (TC_1137_1138.port_a.Q_flow + (TC_1137_1261.port_a.Q_flow + TC_1137_1556.port_a.Q_flow)))))) = 0.0; AIR0CabiA005015005.port.T = TC_1020_1137.port_b.T; AIR0CabiA005015005.port.T = TC_1136_1137.port_b.T; AIR0CabiA005015005.port.T = TC_1137_1138.port_a.T; AIR0CabiA005015005.port.T = TC_1137_1261.port_a.T; AIR0CabiA005015005.port.T = TC_1137_1556.port_a.T; AIR0CabiA005015005.port.T = TC_307_1137.port_b.T; AIR0CabiA005015005.port.T = TsAIR0CabiA005015005.port.T; TsAIR0CabiA004015005.port.Q_flow + (TC_1135_1136.port_b.Q_flow + (TC_1019_1136.port_b.Q_flow + (TC_306_1136.port_b.Q_flow + (AIR0CabiA004015005.port.Q_flow + (TC_1136_1137.port_a.Q_flow + (TC_1136_1260.port_a.Q_flow + TC_1136_1555.port_a.Q_flow)))))) = 0.0; AIR0CabiA004015005.port.T = TC_1019_1136.port_b.T; AIR0CabiA004015005.port.T = TC_1135_1136.port_b.T; AIR0CabiA004015005.port.T = TC_1136_1137.port_a.T; AIR0CabiA004015005.port.T = TC_1136_1260.port_a.T; AIR0CabiA004015005.port.T = TC_1136_1555.port_a.T; AIR0CabiA004015005.port.T = TC_306_1136.port_b.T; AIR0CabiA004015005.port.T = TsAIR0CabiA004015005.port.T; TsAIR0CabiA003015005.port.Q_flow + (TC_1134_1135.port_b.Q_flow + (TC_1018_1135.port_b.Q_flow + (TC_305_1135.port_b.Q_flow + (AIR0CabiA003015005.port.Q_flow + (TC_1135_1136.port_a.Q_flow + (TC_1135_1259.port_a.Q_flow + TC_1135_1554.port_a.Q_flow)))))) = 0.0; AIR0CabiA003015005.port.T = TC_1018_1135.port_b.T; AIR0CabiA003015005.port.T = TC_1134_1135.port_b.T; AIR0CabiA003015005.port.T = TC_1135_1136.port_a.T; AIR0CabiA003015005.port.T = TC_1135_1259.port_a.T; AIR0CabiA003015005.port.T = TC_1135_1554.port_a.T; AIR0CabiA003015005.port.T = TC_305_1135.port_b.T; AIR0CabiA003015005.port.T = TsAIR0CabiA003015005.port.T; TsAIR0CabiA002015005.port.Q_flow + (TC_1132_1134.port_b.Q_flow + (TC_1017_1134.port_b.Q_flow + (TC_304_1134.port_b.Q_flow + (TC_301_1134.port_b.Q_flow + (AIR0CabiA002015005.port.Q_flow + (TC_1134_1135.port_a.Q_flow + TC_1134_1258.port_a.Q_flow)))))) = 0.0; AIR0CabiA002015005.port.T = TC_1017_1134.port_b.T; AIR0CabiA002015005.port.T = TC_1132_1134.port_b.T; AIR0CabiA002015005.port.T = TC_1134_1135.port_a.T; AIR0CabiA002015005.port.T = TC_1134_1258.port_a.T; AIR0CabiA002015005.port.T = TC_301_1134.port_b.T; AIR0CabiA002015005.port.T = TC_304_1134.port_b.T; AIR0CabiA002015005.port.T = TsAIR0CabiA002015005.port.T; TsAIR0CabiA012014005.port.Q_flow + (TC_1131_1133.port_b.Q_flow + (TC_1016_1133.port_b.Q_flow + (TC_300_1133.port_b.Q_flow + (AIR0CabiA012014005.port.Q_flow + (TC_1133_1144.port_a.Q_flow + (TC_1133_1257.port_a.Q_flow + TC_1133_1562.port_a.Q_flow)))))) = 0.0; AIR0CabiA012014005.port.T = TC_1016_1133.port_b.T; AIR0CabiA012014005.port.T = TC_1131_1133.port_b.T; AIR0CabiA012014005.port.T = TC_1133_1144.port_a.T; AIR0CabiA012014005.port.T = TC_1133_1257.port_a.T; AIR0CabiA012014005.port.T = TC_1133_1562.port_a.T; AIR0CabiA012014005.port.T = TC_300_1133.port_b.T; AIR0CabiA012014005.port.T = TsAIR0CabiA012014005.port.T; TsAIR0CabiA002014005.port.Q_flow + (TC_1130_1132.port_b.Q_flow + (TC_1006_1132.port_b.Q_flow + (TC_299_1132.port_b.Q_flow + (AIR0CabiA002014005.port.Q_flow + (TC_1132_1134.port_a.Q_flow + (TC_1132_1247.port_a.Q_flow + TC_1132_1554.port_a.Q_flow)))))) = 0.0; AIR0CabiA002014005.port.T = TC_1006_1132.port_b.T; AIR0CabiA002014005.port.T = TC_1130_1132.port_b.T; AIR0CabiA002014005.port.T = TC_1132_1134.port_a.T; AIR0CabiA002014005.port.T = TC_1132_1247.port_a.T; AIR0CabiA002014005.port.T = TC_1132_1554.port_a.T; AIR0CabiA002014005.port.T = TC_299_1132.port_b.T; AIR0CabiA002014005.port.T = TsAIR0CabiA002014005.port.T; TsAIR0CabiA012013005.port.Q_flow + (TC_1129_1131.port_b.Q_flow + (TC_1005_1131.port_b.Q_flow + (TC_298_1131.port_b.Q_flow + (AIR0CabiA012013005.port.Q_flow + (TC_1131_1133.port_a.Q_flow + (TC_1131_1246.port_a.Q_flow + TC_1131_1553.port_a.Q_flow)))))) = 0.0; AIR0CabiA012013005.port.T = TC_1005_1131.port_b.T; AIR0CabiA012013005.port.T = TC_1129_1131.port_b.T; AIR0CabiA012013005.port.T = TC_1131_1133.port_a.T; AIR0CabiA012013005.port.T = TC_1131_1246.port_a.T; AIR0CabiA012013005.port.T = TC_1131_1553.port_a.T; AIR0CabiA012013005.port.T = TC_298_1131.port_b.T; AIR0CabiA012013005.port.T = TsAIR0CabiA012013005.port.T; TsAIR0CabiA002013005.port.Q_flow + (TC_1128_1130.port_b.Q_flow + (TC_998_1130.port_b.Q_flow + (TC_297_1130.port_b.Q_flow + (AIR0CabiA002013005.port.Q_flow + (TC_1130_1132.port_a.Q_flow + (TC_1130_1239.port_a.Q_flow + TC_1130_1545.port_a.Q_flow)))))) = 0.0; AIR0CabiA002013005.port.T = TC_1128_1130.port_b.T; AIR0CabiA002013005.port.T = TC_1130_1132.port_a.T; AIR0CabiA002013005.port.T = TC_1130_1239.port_a.T; AIR0CabiA002013005.port.T = TC_1130_1545.port_a.T; AIR0CabiA002013005.port.T = TC_297_1130.port_b.T; AIR0CabiA002013005.port.T = TC_998_1130.port_b.T; AIR0CabiA002013005.port.T = TsAIR0CabiA002013005.port.T; TsAIR0CabiA012012005.port.Q_flow + (TC_1127_1129.port_b.Q_flow + (TC_997_1129.port_b.Q_flow + (TC_296_1129.port_b.Q_flow + (AIR0CabiA012012005.port.Q_flow + (TC_1129_1131.port_a.Q_flow + (TC_1129_1238.port_a.Q_flow + TC_1129_1544.port_a.Q_flow)))))) = 0.0; AIR0CabiA012012005.port.T = TC_1127_1129.port_b.T; AIR0CabiA012012005.port.T = TC_1129_1131.port_a.T; AIR0CabiA012012005.port.T = TC_1129_1238.port_a.T; AIR0CabiA012012005.port.T = TC_1129_1544.port_a.T; AIR0CabiA012012005.port.T = TC_296_1129.port_b.T; AIR0CabiA012012005.port.T = TC_997_1129.port_b.T; AIR0CabiA012012005.port.T = TsAIR0CabiA012012005.port.T; TsAIR0CabiA002012005.port.Q_flow + (TC_1126_1128.port_b.Q_flow + (TC_990_1128.port_b.Q_flow + (TC_295_1128.port_b.Q_flow + (AIR0CabiA002012005.port.Q_flow + (TC_1128_1130.port_a.Q_flow + (TC_1128_1231.port_a.Q_flow + TC_1128_1536.port_a.Q_flow)))))) = 0.0; AIR0CabiA002012005.port.T = TC_1126_1128.port_b.T; AIR0CabiA002012005.port.T = TC_1128_1130.port_a.T; AIR0CabiA002012005.port.T = TC_1128_1231.port_a.T; AIR0CabiA002012005.port.T = TC_1128_1536.port_a.T; AIR0CabiA002012005.port.T = TC_295_1128.port_b.T; AIR0CabiA002012005.port.T = TC_990_1128.port_b.T; AIR0CabiA002012005.port.T = TsAIR0CabiA002012005.port.T; TsAIR0CabiA012011005.port.Q_flow + (TC_1125_1127.port_b.Q_flow + (TC_989_1127.port_b.Q_flow + (TC_294_1127.port_b.Q_flow + (AIR0CabiA012011005.port.Q_flow + (TC_1127_1129.port_a.Q_flow + (TC_1127_1230.port_a.Q_flow + TC_1127_1535.port_a.Q_flow)))))) = 0.0; AIR0CabiA012011005.port.T = TC_1125_1127.port_b.T; AIR0CabiA012011005.port.T = TC_1127_1129.port_a.T; AIR0CabiA012011005.port.T = TC_1127_1230.port_a.T; AIR0CabiA012011005.port.T = TC_1127_1535.port_a.T; AIR0CabiA012011005.port.T = TC_294_1127.port_b.T; AIR0CabiA012011005.port.T = TC_989_1127.port_b.T; AIR0CabiA012011005.port.T = TsAIR0CabiA012011005.port.T; TsAIR0CabiA002011005.port.Q_flow + (TC_1124_1126.port_b.Q_flow + (TC_985_1126.port_b.Q_flow + (TC_293_1126.port_b.Q_flow + (AIR0CabiA002011005.port.Q_flow + (TC_1126_1128.port_a.Q_flow + (TC_1126_1223.port_a.Q_flow + TC_1126_1527.port_a.Q_flow)))))) = 0.0; AIR0CabiA002011005.port.T = TC_1124_1126.port_b.T; AIR0CabiA002011005.port.T = TC_1126_1128.port_a.T; AIR0CabiA002011005.port.T = TC_1126_1223.port_a.T; AIR0CabiA002011005.port.T = TC_1126_1527.port_a.T; AIR0CabiA002011005.port.T = TC_293_1126.port_b.T; AIR0CabiA002011005.port.T = TC_985_1126.port_b.T; AIR0CabiA002011005.port.T = TsAIR0CabiA002011005.port.T; TsAIR0CabiA012010005.port.Q_flow + (TC_1123_1125.port_b.Q_flow + (TC_984_1125.port_b.Q_flow + (TC_292_1125.port_b.Q_flow + (AIR0CabiA012010005.port.Q_flow + (TC_1125_1127.port_a.Q_flow + (TC_1125_1222.port_a.Q_flow + TC_1125_1607.port_a.Q_flow)))))) = 0.0; AIR0CabiA012010005.port.T = TC_1123_1125.port_b.T; AIR0CabiA012010005.port.T = TC_1125_1127.port_a.T; AIR0CabiA012010005.port.T = TC_1125_1222.port_a.T; AIR0CabiA012010005.port.T = TC_1125_1607.port_a.T; AIR0CabiA012010005.port.T = TC_292_1125.port_b.T; AIR0CabiA012010005.port.T = TC_984_1125.port_b.T; AIR0CabiA012010005.port.T = TsAIR0CabiA012010005.port.T; TsAIR0CabiA002010005.port.Q_flow + (TC_1122_1124.port_b.Q_flow + (TC_977_1124.port_b.Q_flow + (TC_291_1124.port_b.Q_flow + (AIR0CabiA002010005.port.Q_flow + (TC_1124_1126.port_a.Q_flow + (TC_1124_1215.port_a.Q_flow + TC_1124_1599.port_a.Q_flow)))))) = 0.0; AIR0CabiA002010005.port.T = TC_1122_1124.port_b.T; AIR0CabiA002010005.port.T = TC_1124_1126.port_a.T; AIR0CabiA002010005.port.T = TC_1124_1215.port_a.T; AIR0CabiA002010005.port.T = TC_1124_1599.port_a.T; AIR0CabiA002010005.port.T = TC_291_1124.port_b.T; AIR0CabiA002010005.port.T = TC_977_1124.port_b.T; AIR0CabiA002010005.port.T = TsAIR0CabiA002010005.port.T; TsAIR0CabiA012009005.port.Q_flow + (TC_1121_1123.port_b.Q_flow + (TC_976_1123.port_b.Q_flow + (TC_290_1123.port_b.Q_flow + (AIR0CabiA012009005.port.Q_flow + (TC_1123_1125.port_a.Q_flow + (TC_1123_1214.port_a.Q_flow + TC_1123_1598.port_a.Q_flow)))))) = 0.0; AIR0CabiA012009005.port.T = TC_1121_1123.port_b.T; AIR0CabiA012009005.port.T = TC_1123_1125.port_a.T; AIR0CabiA012009005.port.T = TC_1123_1214.port_a.T; AIR0CabiA012009005.port.T = TC_1123_1598.port_a.T; AIR0CabiA012009005.port.T = TC_290_1123.port_b.T; AIR0CabiA012009005.port.T = TC_976_1123.port_b.T; AIR0CabiA012009005.port.T = TsAIR0CabiA012009005.port.T; TsAIR0CabiA002009005.port.Q_flow + (TC_1120_1122.port_b.Q_flow + (TC_1060_1122.port_b.Q_flow + (TC_289_1122.port_b.Q_flow + (AIR0CabiA002009005.port.Q_flow + (TC_1122_1124.port_a.Q_flow + (TC_1122_1207.port_a.Q_flow + TC_1122_1590.port_a.Q_flow)))))) = 0.0; AIR0CabiA002009005.port.T = TC_1060_1122.port_b.T; AIR0CabiA002009005.port.T = TC_1120_1122.port_b.T; AIR0CabiA002009005.port.T = TC_1122_1124.port_a.T; AIR0CabiA002009005.port.T = TC_1122_1207.port_a.T; AIR0CabiA002009005.port.T = TC_1122_1590.port_a.T; AIR0CabiA002009005.port.T = TC_289_1122.port_b.T; AIR0CabiA002009005.port.T = TsAIR0CabiA002009005.port.T; TsAIR0CabiA012008005.port.Q_flow + (TC_1119_1121.port_b.Q_flow + (TC_1059_1121.port_b.Q_flow + (TC_288_1121.port_b.Q_flow + (AIR0CabiA012008005.port.Q_flow + (TC_1121_1123.port_a.Q_flow + (TC_1121_1206.port_a.Q_flow + TC_1121_1589.port_a.Q_flow)))))) = 0.0; AIR0CabiA012008005.port.T = TC_1059_1121.port_b.T; AIR0CabiA012008005.port.T = TC_1119_1121.port_b.T; AIR0CabiA012008005.port.T = TC_1121_1123.port_a.T; AIR0CabiA012008005.port.T = TC_1121_1206.port_a.T; AIR0CabiA012008005.port.T = TC_1121_1589.port_a.T; AIR0CabiA012008005.port.T = TC_288_1121.port_b.T; AIR0CabiA012008005.port.T = TsAIR0CabiA012008005.port.T; TsAIR0CabiA002008005.port.Q_flow + (TC_1118_1120.port_b.Q_flow + (TC_1049_1120.port_b.Q_flow + (TC_287_1120.port_b.Q_flow + (AIR0CabiA002008005.port.Q_flow + (TC_1120_1122.port_a.Q_flow + (TC_1120_1199.port_a.Q_flow + TC_1120_1581.port_a.Q_flow)))))) = 0.0; AIR0CabiA002008005.port.T = TC_1049_1120.port_b.T; AIR0CabiA002008005.port.T = TC_1118_1120.port_b.T; AIR0CabiA002008005.port.T = TC_1120_1122.port_a.T; AIR0CabiA002008005.port.T = TC_1120_1199.port_a.T; AIR0CabiA002008005.port.T = TC_1120_1581.port_a.T; AIR0CabiA002008005.port.T = TC_287_1120.port_b.T; AIR0CabiA002008005.port.T = TsAIR0CabiA002008005.port.T; TsAIR0CabiA012007005.port.Q_flow + (TC_1117_1119.port_b.Q_flow + (TC_1048_1119.port_b.Q_flow + (TC_286_1119.port_b.Q_flow + (AIR0CabiA012007005.port.Q_flow + (TC_1119_1121.port_a.Q_flow + (TC_1119_1198.port_a.Q_flow + TC_1119_1580.port_a.Q_flow)))))) = 0.0; AIR0CabiA012007005.port.T = TC_1048_1119.port_b.T; AIR0CabiA012007005.port.T = TC_1117_1119.port_b.T; AIR0CabiA012007005.port.T = TC_1119_1121.port_a.T; AIR0CabiA012007005.port.T = TC_1119_1198.port_a.T; AIR0CabiA012007005.port.T = TC_1119_1580.port_a.T; AIR0CabiA012007005.port.T = TC_286_1119.port_b.T; AIR0CabiA012007005.port.T = TsAIR0CabiA012007005.port.T; TsAIR0CabiA002007005.port.Q_flow + (TC_1116_1118.port_b.Q_flow + (TC_1038_1118.port_b.Q_flow + (TC_285_1118.port_b.Q_flow + (AIR0CabiA002007005.port.Q_flow + (TC_1118_1120.port_a.Q_flow + (TC_1118_1188.port_a.Q_flow + TC_1118_1572.port_a.Q_flow)))))) = 0.0; AIR0CabiA002007005.port.T = TC_1038_1118.port_b.T; AIR0CabiA002007005.port.T = TC_1116_1118.port_b.T; AIR0CabiA002007005.port.T = TC_1118_1120.port_a.T; AIR0CabiA002007005.port.T = TC_1118_1188.port_a.T; AIR0CabiA002007005.port.T = TC_1118_1572.port_a.T; AIR0CabiA002007005.port.T = TC_285_1118.port_b.T; AIR0CabiA002007005.port.T = TsAIR0CabiA002007005.port.T; TsAIR0CabiA012006005.port.Q_flow + (TC_1115_1117.port_b.Q_flow + (TC_1037_1117.port_b.Q_flow + (TC_284_1117.port_b.Q_flow + (AIR0CabiA012006005.port.Q_flow + (TC_1117_1119.port_a.Q_flow + (TC_1117_1187.port_a.Q_flow + TC_1117_1571.port_a.Q_flow)))))) = 0.0; AIR0CabiA012006005.port.T = TC_1037_1117.port_b.T; AIR0CabiA012006005.port.T = TC_1115_1117.port_b.T; AIR0CabiA012006005.port.T = TC_1117_1119.port_a.T; AIR0CabiA012006005.port.T = TC_1117_1187.port_a.T; AIR0CabiA012006005.port.T = TC_1117_1571.port_a.T; AIR0CabiA012006005.port.T = TC_284_1117.port_b.T; AIR0CabiA012006005.port.T = TsAIR0CabiA012006005.port.T; TsAIR0CabiA002006005.port.Q_flow + (TC_1114_1116.port_b.Q_flow + (TC_1031_1116.port_b.Q_flow + (TC_283_1116.port_b.Q_flow + (AIR0CabiA002006005.port.Q_flow + (TC_1116_1118.port_a.Q_flow + (TC_1116_1181.port_a.Q_flow + TC_1116_1563.port_a.Q_flow)))))) = 0.0; AIR0CabiA002006005.port.T = TC_1031_1116.port_b.T; AIR0CabiA002006005.port.T = TC_1114_1116.port_b.T; AIR0CabiA002006005.port.T = TC_1116_1118.port_a.T; AIR0CabiA002006005.port.T = TC_1116_1181.port_a.T; AIR0CabiA002006005.port.T = TC_1116_1563.port_a.T; AIR0CabiA002006005.port.T = TC_283_1116.port_b.T; AIR0CabiA002006005.port.T = TsAIR0CabiA002006005.port.T; TsAIR0CabiA012005005.port.Q_flow + (TC_1113_1115.port_b.Q_flow + (TC_1030_1115.port_b.Q_flow + (TC_282_1115.port_b.Q_flow + (AIR0CabiA012005005.port.Q_flow + (TC_1115_1117.port_a.Q_flow + (TC_1115_1180.port_a.Q_flow + TC_1115_1634.port_a.Q_flow)))))) = 0.0; AIR0CabiA012005005.port.T = TC_1030_1115.port_b.T; AIR0CabiA012005005.port.T = TC_1113_1115.port_b.T; AIR0CabiA012005005.port.T = TC_1115_1117.port_a.T; AIR0CabiA012005005.port.T = TC_1115_1180.port_a.T; AIR0CabiA012005005.port.T = TC_1115_1634.port_a.T; AIR0CabiA012005005.port.T = TC_282_1115.port_b.T; AIR0CabiA012005005.port.T = TsAIR0CabiA012005005.port.T; TsAIR0CabiA002005005.port.Q_flow + (TC_1112_1114.port_b.Q_flow + (TC_1095_1114.port_b.Q_flow + (TC_281_1114.port_b.Q_flow + (AIR0CabiA002005005.port.Q_flow + (TC_1114_1116.port_a.Q_flow + (TC_1114_1174.port_a.Q_flow + TC_1114_1626.port_a.Q_flow)))))) = 0.0; AIR0CabiA002005005.port.T = TC_1095_1114.port_b.T; AIR0CabiA002005005.port.T = TC_1112_1114.port_b.T; AIR0CabiA002005005.port.T = TC_1114_1116.port_a.T; AIR0CabiA002005005.port.T = TC_1114_1174.port_a.T; AIR0CabiA002005005.port.T = TC_1114_1626.port_a.T; AIR0CabiA002005005.port.T = TC_281_1114.port_b.T; AIR0CabiA002005005.port.T = TsAIR0CabiA002005005.port.T; TsAIR0CabiA012004005.port.Q_flow + (TC_1111_1113.port_b.Q_flow + (TC_1094_1113.port_b.Q_flow + (TC_280_1113.port_b.Q_flow + (AIR0CabiA012004005.port.Q_flow + (TC_1113_1115.port_a.Q_flow + (TC_1113_1173.port_a.Q_flow + TC_1113_1625.port_a.Q_flow)))))) = 0.0; AIR0CabiA012004005.port.T = TC_1094_1113.port_b.T; AIR0CabiA012004005.port.T = TC_1111_1113.port_b.T; AIR0CabiA012004005.port.T = TC_1113_1115.port_a.T; AIR0CabiA012004005.port.T = TC_1113_1173.port_a.T; AIR0CabiA012004005.port.T = TC_1113_1625.port_a.T; AIR0CabiA012004005.port.T = TC_280_1113.port_b.T; AIR0CabiA012004005.port.T = TsAIR0CabiA012004005.port.T; TsAIR0CabiA002004005.port.Q_flow + (TC_1110_1112.port_b.Q_flow + (TC_1088_1112.port_b.Q_flow + (TC_279_1112.port_b.Q_flow + (AIR0CabiA002004005.port.Q_flow + (TC_1112_1114.port_a.Q_flow + (TC_1112_1167.port_a.Q_flow + TC_1112_1617.port_a.Q_flow)))))) = 0.0; AIR0CabiA002004005.port.T = TC_1088_1112.port_b.T; AIR0CabiA002004005.port.T = TC_1110_1112.port_b.T; AIR0CabiA002004005.port.T = TC_1112_1114.port_a.T; AIR0CabiA002004005.port.T = TC_1112_1167.port_a.T; AIR0CabiA002004005.port.T = TC_1112_1617.port_a.T; AIR0CabiA002004005.port.T = TC_279_1112.port_b.T; AIR0CabiA002004005.port.T = TsAIR0CabiA002004005.port.T; TsAIR0CabiA012003005.port.Q_flow + (TC_1109_1111.port_b.Q_flow + (TC_1087_1111.port_b.Q_flow + (TC_278_1111.port_b.Q_flow + (AIR0CabiA012003005.port.Q_flow + (TC_1111_1113.port_a.Q_flow + (TC_1111_1166.port_a.Q_flow + TC_1111_1616.port_a.Q_flow)))))) = 0.0; AIR0CabiA012003005.port.T = TC_1087_1111.port_b.T; AIR0CabiA012003005.port.T = TC_1109_1111.port_b.T; AIR0CabiA012003005.port.T = TC_1111_1113.port_a.T; AIR0CabiA012003005.port.T = TC_1111_1166.port_a.T; AIR0CabiA012003005.port.T = TC_1111_1616.port_a.T; AIR0CabiA012003005.port.T = TC_278_1111.port_b.T; AIR0CabiA012003005.port.T = TsAIR0CabiA012003005.port.T; TsAIR0CabiA002003005.port.Q_flow + (TC_1099_1110.port_b.Q_flow + (TC_1077_1110.port_b.Q_flow + (TC_277_1110.port_b.Q_flow + (AIR0CabiA002003005.port.Q_flow + (TC_1110_1112.port_a.Q_flow + (TC_1110_1156.port_a.Q_flow + TC_1110_1608.port_a.Q_flow)))))) = 0.0; AIR0CabiA002003005.port.T = TC_1077_1110.port_b.T; AIR0CabiA002003005.port.T = TC_1099_1110.port_b.T; AIR0CabiA002003005.port.T = TC_1110_1112.port_a.T; AIR0CabiA002003005.port.T = TC_1110_1156.port_a.T; AIR0CabiA002003005.port.T = TC_1110_1608.port_a.T; AIR0CabiA002003005.port.T = TC_277_1110.port_b.T; AIR0CabiA002003005.port.T = TsAIR0CabiA002003005.port.T; TsAIR0CabiA012002005.port.Q_flow + (TC_1108_1109.port_b.Q_flow + (TC_1076_1109.port_b.Q_flow + (TC_276_1109.port_b.Q_flow + (TC_273_1109.port_b.Q_flow + (AIR0CabiA012002005.port.Q_flow + (TC_1109_1111.port_a.Q_flow + TC_1109_1155.port_a.Q_flow)))))) = 0.0; AIR0CabiA012002005.port.T = TC_1076_1109.port_b.T; AIR0CabiA012002005.port.T = TC_1108_1109.port_b.T; AIR0CabiA012002005.port.T = TC_1109_1111.port_a.T; AIR0CabiA012002005.port.T = TC_1109_1155.port_a.T; AIR0CabiA012002005.port.T = TC_273_1109.port_b.T; AIR0CabiA012002005.port.T = TC_276_1109.port_b.T; AIR0CabiA012002005.port.T = TsAIR0CabiA012002005.port.T; TsAIR0CabiA011002005.port.Q_flow + (TC_1107_1108.port_b.Q_flow + (TC_1075_1108.port_b.Q_flow + (TC_272_1108.port_b.Q_flow + (AIR0CabiA011002005.port.Q_flow + (TC_1108_1109.port_a.Q_flow + (TC_1108_1154.port_a.Q_flow + TC_1108_1616.port_a.Q_flow)))))) = 0.0; AIR0CabiA011002005.port.T = TC_1075_1108.port_b.T; AIR0CabiA011002005.port.T = TC_1107_1108.port_b.T; AIR0CabiA011002005.port.T = TC_1108_1109.port_a.T; AIR0CabiA011002005.port.T = TC_1108_1154.port_a.T; AIR0CabiA011002005.port.T = TC_1108_1616.port_a.T; AIR0CabiA011002005.port.T = TC_272_1108.port_b.T; AIR0CabiA011002005.port.T = TsAIR0CabiA011002005.port.T; TsAIR0CabiA010002005.port.Q_flow + (TC_1106_1107.port_b.Q_flow + (TC_1074_1107.port_b.Q_flow + (TC_271_1107.port_b.Q_flow + (AIR0CabiA010002005.port.Q_flow + (TC_1107_1108.port_a.Q_flow + (TC_1107_1153.port_a.Q_flow + TC_1107_1615.port_a.Q_flow)))))) = 0.0; AIR0CabiA010002005.port.T = TC_1074_1107.port_b.T; AIR0CabiA010002005.port.T = TC_1106_1107.port_b.T; AIR0CabiA010002005.port.T = TC_1107_1108.port_a.T; AIR0CabiA010002005.port.T = TC_1107_1153.port_a.T; AIR0CabiA010002005.port.T = TC_1107_1615.port_a.T; AIR0CabiA010002005.port.T = TC_271_1107.port_b.T; AIR0CabiA010002005.port.T = TsAIR0CabiA010002005.port.T; TsAIR0CabiA009002005.port.Q_flow + (TC_1105_1106.port_b.Q_flow + (TC_1073_1106.port_b.Q_flow + (TC_270_1106.port_b.Q_flow + (AIR0CabiA009002005.port.Q_flow + (TC_1106_1107.port_a.Q_flow + (TC_1106_1152.port_a.Q_flow + TC_1106_1614.port_a.Q_flow)))))) = 0.0; AIR0CabiA009002005.port.T = TC_1073_1106.port_b.T; AIR0CabiA009002005.port.T = TC_1105_1106.port_b.T; AIR0CabiA009002005.port.T = TC_1106_1107.port_a.T; AIR0CabiA009002005.port.T = TC_1106_1152.port_a.T; AIR0CabiA009002005.port.T = TC_1106_1614.port_a.T; AIR0CabiA009002005.port.T = TC_270_1106.port_b.T; AIR0CabiA009002005.port.T = TsAIR0CabiA009002005.port.T; TsAIR0CabiA008002005.port.Q_flow + (TC_1104_1105.port_b.Q_flow + (TC_1072_1105.port_b.Q_flow + (TC_269_1105.port_b.Q_flow + (AIR0CabiA008002005.port.Q_flow + (TC_1105_1106.port_a.Q_flow + (TC_1105_1151.port_a.Q_flow + TC_1105_1613.port_a.Q_flow)))))) = 0.0; AIR0CabiA008002005.port.T = TC_1072_1105.port_b.T; AIR0CabiA008002005.port.T = TC_1104_1105.port_b.T; AIR0CabiA008002005.port.T = TC_1105_1106.port_a.T; AIR0CabiA008002005.port.T = TC_1105_1151.port_a.T; AIR0CabiA008002005.port.T = TC_1105_1613.port_a.T; AIR0CabiA008002005.port.T = TC_269_1105.port_b.T; AIR0CabiA008002005.port.T = TsAIR0CabiA008002005.port.T; TsAIR0CabiA007002005.port.Q_flow + (TC_1103_1104.port_b.Q_flow + (TC_1071_1104.port_b.Q_flow + (TC_268_1104.port_b.Q_flow + (AIR0CabiA007002005.port.Q_flow + (TC_1104_1105.port_a.Q_flow + (TC_1104_1150.port_a.Q_flow + TC_1104_1612.port_a.Q_flow)))))) = 0.0; AIR0CabiA007002005.port.T = TC_1071_1104.port_b.T; AIR0CabiA007002005.port.T = TC_1103_1104.port_b.T; AIR0CabiA007002005.port.T = TC_1104_1105.port_a.T; AIR0CabiA007002005.port.T = TC_1104_1150.port_a.T; AIR0CabiA007002005.port.T = TC_1104_1612.port_a.T; AIR0CabiA007002005.port.T = TC_268_1104.port_b.T; AIR0CabiA007002005.port.T = TsAIR0CabiA007002005.port.T; TsAIR0CabiA006002005.port.Q_flow + (TC_1102_1103.port_b.Q_flow + (TC_1070_1103.port_b.Q_flow + (TC_267_1103.port_b.Q_flow + (AIR0CabiA006002005.port.Q_flow + (TC_1103_1104.port_a.Q_flow + (TC_1103_1149.port_a.Q_flow + TC_1103_1611.port_a.Q_flow)))))) = 0.0; AIR0CabiA006002005.port.T = TC_1070_1103.port_b.T; AIR0CabiA006002005.port.T = TC_1102_1103.port_b.T; AIR0CabiA006002005.port.T = TC_1103_1104.port_a.T; AIR0CabiA006002005.port.T = TC_1103_1149.port_a.T; AIR0CabiA006002005.port.T = TC_1103_1611.port_a.T; AIR0CabiA006002005.port.T = TC_267_1103.port_b.T; AIR0CabiA006002005.port.T = TsAIR0CabiA006002005.port.T; TsAIR0CabiA005002005.port.Q_flow + (TC_1101_1102.port_b.Q_flow + (TC_1069_1102.port_b.Q_flow + (TC_266_1102.port_b.Q_flow + (AIR0CabiA005002005.port.Q_flow + (TC_1102_1103.port_a.Q_flow + (TC_1102_1148.port_a.Q_flow + TC_1102_1610.port_a.Q_flow)))))) = 0.0; AIR0CabiA005002005.port.T = TC_1069_1102.port_b.T; AIR0CabiA005002005.port.T = TC_1101_1102.port_b.T; AIR0CabiA005002005.port.T = TC_1102_1103.port_a.T; AIR0CabiA005002005.port.T = TC_1102_1148.port_a.T; AIR0CabiA005002005.port.T = TC_1102_1610.port_a.T; AIR0CabiA005002005.port.T = TC_266_1102.port_b.T; AIR0CabiA005002005.port.T = TsAIR0CabiA005002005.port.T; TsAIR0CabiA004002005.port.Q_flow + (TC_1100_1101.port_b.Q_flow + (TC_1068_1101.port_b.Q_flow + (TC_265_1101.port_b.Q_flow + (AIR0CabiA004002005.port.Q_flow + (TC_1101_1102.port_a.Q_flow + (TC_1101_1147.port_a.Q_flow + TC_1101_1609.port_a.Q_flow)))))) = 0.0; AIR0CabiA004002005.port.T = TC_1068_1101.port_b.T; AIR0CabiA004002005.port.T = TC_1100_1101.port_b.T; AIR0CabiA004002005.port.T = TC_1101_1102.port_a.T; AIR0CabiA004002005.port.T = TC_1101_1147.port_a.T; AIR0CabiA004002005.port.T = TC_1101_1609.port_a.T; AIR0CabiA004002005.port.T = TC_265_1101.port_b.T; AIR0CabiA004002005.port.T = TsAIR0CabiA004002005.port.T; TsAIR0CabiA003002005.port.Q_flow + (TC_1099_1100.port_b.Q_flow + (TC_1067_1100.port_b.Q_flow + (TC_264_1100.port_b.Q_flow + (AIR0CabiA003002005.port.Q_flow + (TC_1100_1101.port_a.Q_flow + (TC_1100_1146.port_a.Q_flow + TC_1100_1608.port_a.Q_flow)))))) = 0.0; AIR0CabiA003002005.port.T = TC_1067_1100.port_b.T; AIR0CabiA003002005.port.T = TC_1099_1100.port_b.T; AIR0CabiA003002005.port.T = TC_1100_1101.port_a.T; AIR0CabiA003002005.port.T = TC_1100_1146.port_a.T; AIR0CabiA003002005.port.T = TC_1100_1608.port_a.T; AIR0CabiA003002005.port.T = TC_264_1100.port_b.T; AIR0CabiA003002005.port.T = TsAIR0CabiA003002005.port.T; TsAIR0CabiA002002005.port.Q_flow + (TC_1066_1099.port_b.Q_flow + (TC_275_1099.port_b.Q_flow + (TC_263_1099.port_b.Q_flow + (AIR0CabiA002002005.port.Q_flow + (TC_1099_1100.port_a.Q_flow + (TC_1099_1110.port_a.Q_flow + TC_1099_1145.port_a.Q_flow)))))) = 0.0; AIR0CabiA002002005.port.T = TC_1066_1099.port_b.T; AIR0CabiA002002005.port.T = TC_1099_1100.port_a.T; AIR0CabiA002002005.port.T = TC_1099_1110.port_a.T; AIR0CabiA002002005.port.T = TC_1099_1145.port_a.T; AIR0CabiA002002005.port.T = TC_263_1099.port_b.T; AIR0CabiA002002005.port.T = TC_275_1099.port_b.T; AIR0CabiA002002005.port.T = TsAIR0CabiA002002005.port.T; TsAIR0CabiA005005006.port.Q_flow + (TC_1097_1098.port_b.Q_flow + (TC_1091_1098.port_b.Q_flow + (TC_1034_1098.port_b.Q_flow + (TC_956_1098.port_b.Q_flow + (AIR0CabiA005005006.port.Q_flow + (TC_1098_1628.port_a.Q_flow + TC_1098_1639.port_a.Q_flow)))))) = 0.0; AIR0CabiA005005006.port.T = TC_1034_1098.port_b.T; AIR0CabiA005005006.port.T = TC_1091_1098.port_b.T; AIR0CabiA005005006.port.T = TC_1097_1098.port_b.T; AIR0CabiA005005006.port.T = TC_1098_1628.port_a.T; AIR0CabiA005005006.port.T = TC_1098_1639.port_a.T; AIR0CabiA005005006.port.T = TC_956_1098.port_b.T; AIR0CabiA005005006.port.T = TsAIR0CabiA005005006.port.T; TsAIR0CabiA004005006.port.Q_flow + (TC_1096_1097.port_b.Q_flow + (TC_1090_1097.port_b.Q_flow + (TC_1033_1097.port_b.Q_flow + (TC_955_1097.port_b.Q_flow + (AIR0CabiA004005006.port.Q_flow + (TC_1097_1098.port_a.Q_flow + TC_1097_1627.port_a.Q_flow)))))) = 0.0; AIR0CabiA004005006.port.T = TC_1033_1097.port_b.T; AIR0CabiA004005006.port.T = TC_1090_1097.port_b.T; AIR0CabiA004005006.port.T = TC_1096_1097.port_b.T; AIR0CabiA004005006.port.T = TC_1097_1098.port_a.T; AIR0CabiA004005006.port.T = TC_1097_1627.port_a.T; AIR0CabiA004005006.port.T = TC_955_1097.port_b.T; AIR0CabiA004005006.port.T = TsAIR0CabiA004005006.port.T; TsAIR0CabiA003005006.port.Q_flow + (TC_1095_1096.port_b.Q_flow + (TC_1089_1096.port_b.Q_flow + (TC_1032_1096.port_b.Q_flow + (TC_954_1096.port_b.Q_flow + (AIR0CabiA003005006.port.Q_flow + (TC_1096_1097.port_a.Q_flow + TC_1096_1626.port_a.Q_flow)))))) = 0.0; AIR0CabiA003005006.port.T = TC_1032_1096.port_b.T; AIR0CabiA003005006.port.T = TC_1089_1096.port_b.T; AIR0CabiA003005006.port.T = TC_1095_1096.port_b.T; AIR0CabiA003005006.port.T = TC_1096_1097.port_a.T; AIR0CabiA003005006.port.T = TC_1096_1626.port_a.T; AIR0CabiA003005006.port.T = TC_954_1096.port_b.T; AIR0CabiA003005006.port.T = TsAIR0CabiA003005006.port.T; TsAIR0CabiA002005006.port.Q_flow + (TC_1088_1095.port_b.Q_flow + (TC_1031_1095.port_b.Q_flow + (TC_953_1095.port_b.Q_flow + (TC_444_1095.port_b.Q_flow + (AIR0CabiA002005006.port.Q_flow + (TC_1095_1096.port_a.Q_flow + TC_1095_1114.port_a.Q_flow)))))) = 0.0; AIR0CabiA002005006.port.T = TC_1031_1095.port_b.T; AIR0CabiA002005006.port.T = TC_1088_1095.port_b.T; AIR0CabiA002005006.port.T = TC_1095_1096.port_a.T; AIR0CabiA002005006.port.T = TC_1095_1114.port_a.T; AIR0CabiA002005006.port.T = TC_444_1095.port_b.T; AIR0CabiA002005006.port.T = TC_953_1095.port_b.T; AIR0CabiA002005006.port.T = TsAIR0CabiA002005006.port.T; TsAIR0CabiA012004006.port.Q_flow + (TC_1093_1094.port_b.Q_flow + (TC_1087_1094.port_b.Q_flow + (TC_1030_1094.port_b.Q_flow + (TC_952_1094.port_b.Q_flow + (TC_443_1094.port_b.Q_flow + (AIR0CabiA012004006.port.Q_flow + TC_1094_1113.port_a.Q_flow)))))) = 0.0; AIR0CabiA012004006.port.T = TC_1030_1094.port_b.T; AIR0CabiA012004006.port.T = TC_1087_1094.port_b.T; AIR0CabiA012004006.port.T = TC_1093_1094.port_b.T; AIR0CabiA012004006.port.T = TC_1094_1113.port_a.T; AIR0CabiA012004006.port.T = TC_443_1094.port_b.T; AIR0CabiA012004006.port.T = TC_952_1094.port_b.T; AIR0CabiA012004006.port.T = TsAIR0CabiA012004006.port.T; TsAIR0CabiA011004006.port.Q_flow + (TC_1092_1093.port_b.Q_flow + (TC_1086_1093.port_b.Q_flow + (TC_1029_1093.port_b.Q_flow + (TC_951_1093.port_b.Q_flow + (AIR0CabiA011004006.port.Q_flow + (TC_1093_1094.port_a.Q_flow + TC_1093_1625.port_a.Q_flow)))))) = 0.0; AIR0CabiA011004006.port.T = TC_1029_1093.port_b.T; AIR0CabiA011004006.port.T = TC_1086_1093.port_b.T; AIR0CabiA011004006.port.T = TC_1092_1093.port_b.T; AIR0CabiA011004006.port.T = TC_1093_1094.port_a.T; AIR0CabiA011004006.port.T = TC_1093_1625.port_a.T; AIR0CabiA011004006.port.T = TC_951_1093.port_b.T; AIR0CabiA011004006.port.T = TsAIR0CabiA011004006.port.T; TsAIR0CabiA010004006.port.Q_flow + (TC_1085_1092.port_b.Q_flow + (TC_1028_1092.port_b.Q_flow + (TC_950_1092.port_b.Q_flow + (AIR0CabiA010004006.port.Q_flow + (TC_1092_1093.port_a.Q_flow + (TC_1092_1624.port_a.Q_flow + TC_1092_1638.port_a.Q_flow)))))) = 0.0; AIR0CabiA010004006.port.T = TC_1028_1092.port_b.T; AIR0CabiA010004006.port.T = TC_1085_1092.port_b.T; AIR0CabiA010004006.port.T = TC_1092_1093.port_a.T; AIR0CabiA010004006.port.T = TC_1092_1624.port_a.T; AIR0CabiA010004006.port.T = TC_1092_1638.port_a.T; AIR0CabiA010004006.port.T = TC_950_1092.port_b.T; AIR0CabiA010004006.port.T = TsAIR0CabiA010004006.port.T; TsAIR0CabiA005004006.port.Q_flow + (TC_1090_1091.port_b.Q_flow + (TC_1080_1091.port_b.Q_flow + (TC_945_1091.port_b.Q_flow + (AIR0CabiA005004006.port.Q_flow + (TC_1091_1098.port_a.Q_flow + (TC_1091_1619.port_a.Q_flow + TC_1091_1635.port_a.Q_flow)))))) = 0.0; AIR0CabiA005004006.port.T = TC_1080_1091.port_b.T; AIR0CabiA005004006.port.T = TC_1090_1091.port_b.T; AIR0CabiA005004006.port.T = TC_1091_1098.port_a.T; AIR0CabiA005004006.port.T = TC_1091_1619.port_a.T; AIR0CabiA005004006.port.T = TC_1091_1635.port_a.T; AIR0CabiA005004006.port.T = TC_945_1091.port_b.T; AIR0CabiA005004006.port.T = TsAIR0CabiA005004006.port.T; TsAIR0CabiA004004006.port.Q_flow + (TC_1089_1090.port_b.Q_flow + (TC_1079_1090.port_b.Q_flow + (TC_944_1090.port_b.Q_flow + (AIR0CabiA004004006.port.Q_flow + (TC_1090_1091.port_a.Q_flow + (TC_1090_1097.port_a.Q_flow + TC_1090_1618.port_a.Q_flow)))))) = 0.0; AIR0CabiA004004006.port.T = TC_1079_1090.port_b.T; AIR0CabiA004004006.port.T = TC_1089_1090.port_b.T; AIR0CabiA004004006.port.T = TC_1090_1091.port_a.T; AIR0CabiA004004006.port.T = TC_1090_1097.port_a.T; AIR0CabiA004004006.port.T = TC_1090_1618.port_a.T; AIR0CabiA004004006.port.T = TC_944_1090.port_b.T; AIR0CabiA004004006.port.T = TsAIR0CabiA004004006.port.T; TsAIR0CabiA003004006.port.Q_flow + (TC_1088_1089.port_b.Q_flow + (TC_1078_1089.port_b.Q_flow + (TC_943_1089.port_b.Q_flow + (AIR0CabiA003004006.port.Q_flow + (TC_1089_1090.port_a.Q_flow + (TC_1089_1096.port_a.Q_flow + TC_1089_1617.port_a.Q_flow)))))) = 0.0; AIR0CabiA003004006.port.T = TC_1078_1089.port_b.T; AIR0CabiA003004006.port.T = TC_1088_1089.port_b.T; AIR0CabiA003004006.port.T = TC_1089_1090.port_a.T; AIR0CabiA003004006.port.T = TC_1089_1096.port_a.T; AIR0CabiA003004006.port.T = TC_1089_1617.port_a.T; AIR0CabiA003004006.port.T = TC_943_1089.port_b.T; AIR0CabiA003004006.port.T = TsAIR0CabiA003004006.port.T; TsAIR0CabiA002004006.port.Q_flow + (TC_1077_1088.port_b.Q_flow + (TC_942_1088.port_b.Q_flow + (TC_442_1088.port_b.Q_flow + (AIR0CabiA002004006.port.Q_flow + (TC_1088_1089.port_a.Q_flow + (TC_1088_1095.port_a.Q_flow + TC_1088_1112.port_a.Q_flow)))))) = 0.0; AIR0CabiA002004006.port.T = TC_1077_1088.port_b.T; AIR0CabiA002004006.port.T = TC_1088_1089.port_a.T; AIR0CabiA002004006.port.T = TC_1088_1095.port_a.T; AIR0CabiA002004006.port.T = TC_1088_1112.port_a.T; AIR0CabiA002004006.port.T = TC_442_1088.port_b.T; AIR0CabiA002004006.port.T = TC_942_1088.port_b.T; AIR0CabiA002004006.port.T = TsAIR0CabiA002004006.port.T; TsAIR0CabiA012003006.port.Q_flow + (TC_1086_1087.port_b.Q_flow + (TC_1076_1087.port_b.Q_flow + (TC_941_1087.port_b.Q_flow + (TC_441_1087.port_b.Q_flow + (AIR0CabiA012003006.port.Q_flow + (TC_1087_1094.port_a.Q_flow + TC_1087_1111.port_a.Q_flow)))))) = 0.0; AIR0CabiA012003006.port.T = TC_1076_1087.port_b.T; AIR0CabiA012003006.port.T = TC_1086_1087.port_b.T; AIR0CabiA012003006.port.T = TC_1087_1094.port_a.T; AIR0CabiA012003006.port.T = TC_1087_1111.port_a.T; AIR0CabiA012003006.port.T = TC_441_1087.port_b.T; AIR0CabiA012003006.port.T = TC_941_1087.port_b.T; AIR0CabiA012003006.port.T = TsAIR0CabiA012003006.port.T; TsAIR0CabiA011003006.port.Q_flow + (TC_1085_1086.port_b.Q_flow + (TC_1075_1086.port_b.Q_flow + (TC_940_1086.port_b.Q_flow + (AIR0CabiA011003006.port.Q_flow + (TC_1086_1087.port_a.Q_flow + (TC_1086_1093.port_a.Q_flow + TC_1086_1616.port_a.Q_flow)))))) = 0.0; AIR0CabiA011003006.port.T = TC_1075_1086.port_b.T; AIR0CabiA011003006.port.T = TC_1085_1086.port_b.T; AIR0CabiA011003006.port.T = TC_1086_1087.port_a.T; AIR0CabiA011003006.port.T = TC_1086_1093.port_a.T; AIR0CabiA011003006.port.T = TC_1086_1616.port_a.T; AIR0CabiA011003006.port.T = TC_940_1086.port_b.T; AIR0CabiA011003006.port.T = TsAIR0CabiA011003006.port.T; TsAIR0CabiA010003006.port.Q_flow + (TC_1084_1085.port_b.Q_flow + (TC_1074_1085.port_b.Q_flow + (TC_939_1085.port_b.Q_flow + (AIR0CabiA010003006.port.Q_flow + (TC_1085_1086.port_a.Q_flow + (TC_1085_1092.port_a.Q_flow + TC_1085_1615.port_a.Q_flow)))))) = 0.0; AIR0CabiA010003006.port.T = TC_1074_1085.port_b.T; AIR0CabiA010003006.port.T = TC_1084_1085.port_b.T; AIR0CabiA010003006.port.T = TC_1085_1086.port_a.T; AIR0CabiA010003006.port.T = TC_1085_1092.port_a.T; AIR0CabiA010003006.port.T = TC_1085_1615.port_a.T; AIR0CabiA010003006.port.T = TC_939_1085.port_b.T; AIR0CabiA010003006.port.T = TsAIR0CabiA010003006.port.T; TsAIR0CabiA009003006.port.Q_flow + (TC_1083_1084.port_b.Q_flow + (TC_1073_1084.port_b.Q_flow + (TC_938_1084.port_b.Q_flow + (AIR0CabiA009003006.port.Q_flow + (TC_1084_1085.port_a.Q_flow + (TC_1084_1614.port_a.Q_flow + TC_1084_1638.port_a.Q_flow)))))) = 0.0; AIR0CabiA009003006.port.T = TC_1073_1084.port_b.T; AIR0CabiA009003006.port.T = TC_1083_1084.port_b.T; AIR0CabiA009003006.port.T = TC_1084_1085.port_a.T; AIR0CabiA009003006.port.T = TC_1084_1614.port_a.T; AIR0CabiA009003006.port.T = TC_1084_1638.port_a.T; AIR0CabiA009003006.port.T = TC_938_1084.port_b.T; AIR0CabiA009003006.port.T = TsAIR0CabiA009003006.port.T; TsAIR0CabiA008003006.port.Q_flow + (TC_1082_1083.port_b.Q_flow + (TC_1072_1083.port_b.Q_flow + (TC_937_1083.port_b.Q_flow + (AIR0CabiA008003006.port.Q_flow + (TC_1083_1084.port_a.Q_flow + (TC_1083_1613.port_a.Q_flow + TC_1083_1637.port_a.Q_flow)))))) = 0.0; AIR0CabiA008003006.port.T = TC_1072_1083.port_b.T; AIR0CabiA008003006.port.T = TC_1082_1083.port_b.T; AIR0CabiA008003006.port.T = TC_1083_1084.port_a.T; AIR0CabiA008003006.port.T = TC_1083_1613.port_a.T; AIR0CabiA008003006.port.T = TC_1083_1637.port_a.T; AIR0CabiA008003006.port.T = TC_937_1083.port_b.T; AIR0CabiA008003006.port.T = TsAIR0CabiA008003006.port.T; TsAIR0CabiA007003006.port.Q_flow + (TC_1081_1082.port_b.Q_flow + (TC_1071_1082.port_b.Q_flow + (TC_936_1082.port_b.Q_flow + (AIR0CabiA007003006.port.Q_flow + (TC_1082_1083.port_a.Q_flow + (TC_1082_1612.port_a.Q_flow + TC_1082_1636.port_a.Q_flow)))))) = 0.0; AIR0CabiA007003006.port.T = TC_1071_1082.port_b.T; AIR0CabiA007003006.port.T = TC_1081_1082.port_b.T; AIR0CabiA007003006.port.T = TC_1082_1083.port_a.T; AIR0CabiA007003006.port.T = TC_1082_1612.port_a.T; AIR0CabiA007003006.port.T = TC_1082_1636.port_a.T; AIR0CabiA007003006.port.T = TC_936_1082.port_b.T; AIR0CabiA007003006.port.T = TsAIR0CabiA007003006.port.T; TsAIR0CabiA006003006.port.Q_flow + (TC_1080_1081.port_b.Q_flow + (TC_1070_1081.port_b.Q_flow + (TC_935_1081.port_b.Q_flow + (AIR0CabiA006003006.port.Q_flow + (TC_1081_1082.port_a.Q_flow + (TC_1081_1611.port_a.Q_flow + TC_1081_1635.port_a.Q_flow)))))) = 0.0; AIR0CabiA006003006.port.T = TC_1070_1081.port_b.T; AIR0CabiA006003006.port.T = TC_1080_1081.port_b.T; AIR0CabiA006003006.port.T = TC_1081_1082.port_a.T; AIR0CabiA006003006.port.T = TC_1081_1611.port_a.T; AIR0CabiA006003006.port.T = TC_1081_1635.port_a.T; AIR0CabiA006003006.port.T = TC_935_1081.port_b.T; AIR0CabiA006003006.port.T = TsAIR0CabiA006003006.port.T; TsAIR0CabiA005003006.port.Q_flow + (TC_1079_1080.port_b.Q_flow + (TC_1069_1080.port_b.Q_flow + (TC_934_1080.port_b.Q_flow + (AIR0CabiA005003006.port.Q_flow + (TC_1080_1081.port_a.Q_flow + (TC_1080_1091.port_a.Q_flow + TC_1080_1610.port_a.Q_flow)))))) = 0.0; AIR0CabiA005003006.port.T = TC_1069_1080.port_b.T; AIR0CabiA005003006.port.T = TC_1079_1080.port_b.T; AIR0CabiA005003006.port.T = TC_1080_1081.port_a.T; AIR0CabiA005003006.port.T = TC_1080_1091.port_a.T; AIR0CabiA005003006.port.T = TC_1080_1610.port_a.T; AIR0CabiA005003006.port.T = TC_934_1080.port_b.T; AIR0CabiA005003006.port.T = TsAIR0CabiA005003006.port.T; TsAIR0CabiA004003006.port.Q_flow + (TC_1078_1079.port_b.Q_flow + (TC_1068_1079.port_b.Q_flow + (TC_933_1079.port_b.Q_flow + (AIR0CabiA004003006.port.Q_flow + (TC_1079_1080.port_a.Q_flow + (TC_1079_1090.port_a.Q_flow + TC_1079_1609.port_a.Q_flow)))))) = 0.0; AIR0CabiA004003006.port.T = TC_1068_1079.port_b.T; AIR0CabiA004003006.port.T = TC_1078_1079.port_b.T; AIR0CabiA004003006.port.T = TC_1079_1080.port_a.T; AIR0CabiA004003006.port.T = TC_1079_1090.port_a.T; AIR0CabiA004003006.port.T = TC_1079_1609.port_a.T; AIR0CabiA004003006.port.T = TC_933_1079.port_b.T; AIR0CabiA004003006.port.T = TsAIR0CabiA004003006.port.T; TsAIR0CabiA003003006.port.Q_flow + (TC_1077_1078.port_b.Q_flow + (TC_1067_1078.port_b.Q_flow + (TC_932_1078.port_b.Q_flow + (AIR0CabiA003003006.port.Q_flow + (TC_1078_1079.port_a.Q_flow + (TC_1078_1089.port_a.Q_flow + TC_1078_1608.port_a.Q_flow)))))) = 0.0; AIR0CabiA003003006.port.T = TC_1067_1078.port_b.T; AIR0CabiA003003006.port.T = TC_1077_1078.port_b.T; AIR0CabiA003003006.port.T = TC_1078_1079.port_a.T; AIR0CabiA003003006.port.T = TC_1078_1089.port_a.T; AIR0CabiA003003006.port.T = TC_1078_1608.port_a.T; AIR0CabiA003003006.port.T = TC_932_1078.port_b.T; AIR0CabiA003003006.port.T = TsAIR0CabiA003003006.port.T; TsAIR0CabiA002003006.port.Q_flow + (TC_1066_1077.port_b.Q_flow + (TC_931_1077.port_b.Q_flow + (TC_440_1077.port_b.Q_flow + (AIR0CabiA002003006.port.Q_flow + (TC_1077_1078.port_a.Q_flow + (TC_1077_1088.port_a.Q_flow + TC_1077_1110.port_a.Q_flow)))))) = 0.0; AIR0CabiA002003006.port.T = TC_1066_1077.port_b.T; AIR0CabiA002003006.port.T = TC_1077_1078.port_a.T; AIR0CabiA002003006.port.T = TC_1077_1088.port_a.T; AIR0CabiA002003006.port.T = TC_1077_1110.port_a.T; AIR0CabiA002003006.port.T = TC_440_1077.port_b.T; AIR0CabiA002003006.port.T = TC_931_1077.port_b.T; AIR0CabiA002003006.port.T = TsAIR0CabiA002003006.port.T; TsAIR0CabiA012002006.port.Q_flow + (TC_1075_1076.port_b.Q_flow + (TC_930_1076.port_b.Q_flow + (TC_439_1076.port_b.Q_flow + (TC_436_1076.port_b.Q_flow + (AIR0CabiA012002006.port.Q_flow + (TC_1076_1087.port_a.Q_flow + TC_1076_1109.port_a.Q_flow)))))) = 0.0; AIR0CabiA012002006.port.T = TC_1075_1076.port_b.T; AIR0CabiA012002006.port.T = TC_1076_1087.port_a.T; AIR0CabiA012002006.port.T = TC_1076_1109.port_a.T; AIR0CabiA012002006.port.T = TC_436_1076.port_b.T; AIR0CabiA012002006.port.T = TC_439_1076.port_b.T; AIR0CabiA012002006.port.T = TC_930_1076.port_b.T; AIR0CabiA012002006.port.T = TsAIR0CabiA012002006.port.T; TsAIR0CabiA011002006.port.Q_flow + (TC_1074_1075.port_b.Q_flow + (TC_929_1075.port_b.Q_flow + (TC_435_1075.port_b.Q_flow + (AIR0CabiA011002006.port.Q_flow + (TC_1075_1076.port_a.Q_flow + (TC_1075_1086.port_a.Q_flow + TC_1075_1108.port_a.Q_flow)))))) = 0.0; AIR0CabiA011002006.port.T = TC_1074_1075.port_b.T; AIR0CabiA011002006.port.T = TC_1075_1076.port_a.T; AIR0CabiA011002006.port.T = TC_1075_1086.port_a.T; AIR0CabiA011002006.port.T = TC_1075_1108.port_a.T; AIR0CabiA011002006.port.T = TC_435_1075.port_b.T; AIR0CabiA011002006.port.T = TC_929_1075.port_b.T; AIR0CabiA011002006.port.T = TsAIR0CabiA011002006.port.T; TsAIR0CabiA010002006.port.Q_flow + (TC_1073_1074.port_b.Q_flow + (TC_928_1074.port_b.Q_flow + (TC_434_1074.port_b.Q_flow + (AIR0CabiA010002006.port.Q_flow + (TC_1074_1075.port_a.Q_flow + (TC_1074_1085.port_a.Q_flow + TC_1074_1107.port_a.Q_flow)))))) = 0.0; AIR0CabiA010002006.port.T = TC_1073_1074.port_b.T; AIR0CabiA010002006.port.T = TC_1074_1075.port_a.T; AIR0CabiA010002006.port.T = TC_1074_1085.port_a.T; AIR0CabiA010002006.port.T = TC_1074_1107.port_a.T; AIR0CabiA010002006.port.T = TC_434_1074.port_b.T; AIR0CabiA010002006.port.T = TC_928_1074.port_b.T; AIR0CabiA010002006.port.T = TsAIR0CabiA010002006.port.T; TsAIR0CabiA009002006.port.Q_flow + (TC_1072_1073.port_b.Q_flow + (TC_927_1073.port_b.Q_flow + (TC_433_1073.port_b.Q_flow + (AIR0CabiA009002006.port.Q_flow + (TC_1073_1074.port_a.Q_flow + (TC_1073_1084.port_a.Q_flow + TC_1073_1106.port_a.Q_flow)))))) = 0.0; AIR0CabiA009002006.port.T = TC_1072_1073.port_b.T; AIR0CabiA009002006.port.T = TC_1073_1074.port_a.T; AIR0CabiA009002006.port.T = TC_1073_1084.port_a.T; AIR0CabiA009002006.port.T = TC_1073_1106.port_a.T; AIR0CabiA009002006.port.T = TC_433_1073.port_b.T; AIR0CabiA009002006.port.T = TC_927_1073.port_b.T; AIR0CabiA009002006.port.T = TsAIR0CabiA009002006.port.T; TsAIR0CabiA008002006.port.Q_flow + (TC_1071_1072.port_b.Q_flow + (TC_926_1072.port_b.Q_flow + (TC_432_1072.port_b.Q_flow + (AIR0CabiA008002006.port.Q_flow + (TC_1072_1073.port_a.Q_flow + (TC_1072_1083.port_a.Q_flow + TC_1072_1105.port_a.Q_flow)))))) = 0.0; AIR0CabiA008002006.port.T = TC_1071_1072.port_b.T; AIR0CabiA008002006.port.T = TC_1072_1073.port_a.T; AIR0CabiA008002006.port.T = TC_1072_1083.port_a.T; AIR0CabiA008002006.port.T = TC_1072_1105.port_a.T; AIR0CabiA008002006.port.T = TC_432_1072.port_b.T; AIR0CabiA008002006.port.T = TC_926_1072.port_b.T; AIR0CabiA008002006.port.T = TsAIR0CabiA008002006.port.T; TsAIR0CabiA007002006.port.Q_flow + (TC_1070_1071.port_b.Q_flow + (TC_925_1071.port_b.Q_flow + (TC_431_1071.port_b.Q_flow + (AIR0CabiA007002006.port.Q_flow + (TC_1071_1072.port_a.Q_flow + (TC_1071_1082.port_a.Q_flow + TC_1071_1104.port_a.Q_flow)))))) = 0.0; AIR0CabiA007002006.port.T = TC_1070_1071.port_b.T; AIR0CabiA007002006.port.T = TC_1071_1072.port_a.T; AIR0CabiA007002006.port.T = TC_1071_1082.port_a.T; AIR0CabiA007002006.port.T = TC_1071_1104.port_a.T; AIR0CabiA007002006.port.T = TC_431_1071.port_b.T; AIR0CabiA007002006.port.T = TC_925_1071.port_b.T; AIR0CabiA007002006.port.T = TsAIR0CabiA007002006.port.T; TsAIR0CabiA006002006.port.Q_flow + (TC_1069_1070.port_b.Q_flow + (TC_924_1070.port_b.Q_flow + (TC_430_1070.port_b.Q_flow + (AIR0CabiA006002006.port.Q_flow + (TC_1070_1071.port_a.Q_flow + (TC_1070_1081.port_a.Q_flow + TC_1070_1103.port_a.Q_flow)))))) = 0.0; AIR0CabiA006002006.port.T = TC_1069_1070.port_b.T; AIR0CabiA006002006.port.T = TC_1070_1071.port_a.T; AIR0CabiA006002006.port.T = TC_1070_1081.port_a.T; AIR0CabiA006002006.port.T = TC_1070_1103.port_a.T; AIR0CabiA006002006.port.T = TC_430_1070.port_b.T; AIR0CabiA006002006.port.T = TC_924_1070.port_b.T; AIR0CabiA006002006.port.T = TsAIR0CabiA006002006.port.T; TsAIR0CabiA005002006.port.Q_flow + (TC_1068_1069.port_b.Q_flow + (TC_923_1069.port_b.Q_flow + (TC_429_1069.port_b.Q_flow + (AIR0CabiA005002006.port.Q_flow + (TC_1069_1070.port_a.Q_flow + (TC_1069_1080.port_a.Q_flow + TC_1069_1102.port_a.Q_flow)))))) = 0.0; AIR0CabiA005002006.port.T = TC_1068_1069.port_b.T; AIR0CabiA005002006.port.T = TC_1069_1070.port_a.T; AIR0CabiA005002006.port.T = TC_1069_1080.port_a.T; AIR0CabiA005002006.port.T = TC_1069_1102.port_a.T; AIR0CabiA005002006.port.T = TC_429_1069.port_b.T; AIR0CabiA005002006.port.T = TC_923_1069.port_b.T; AIR0CabiA005002006.port.T = TsAIR0CabiA005002006.port.T; TsAIR0CabiA004002006.port.Q_flow + (TC_1067_1068.port_b.Q_flow + (TC_922_1068.port_b.Q_flow + (TC_428_1068.port_b.Q_flow + (AIR0CabiA004002006.port.Q_flow + (TC_1068_1069.port_a.Q_flow + (TC_1068_1079.port_a.Q_flow + TC_1068_1101.port_a.Q_flow)))))) = 0.0; AIR0CabiA004002006.port.T = TC_1067_1068.port_b.T; AIR0CabiA004002006.port.T = TC_1068_1069.port_a.T; AIR0CabiA004002006.port.T = TC_1068_1079.port_a.T; AIR0CabiA004002006.port.T = TC_1068_1101.port_a.T; AIR0CabiA004002006.port.T = TC_428_1068.port_b.T; AIR0CabiA004002006.port.T = TC_922_1068.port_b.T; AIR0CabiA004002006.port.T = TsAIR0CabiA004002006.port.T; TsAIR0CabiA003002006.port.Q_flow + (TC_1066_1067.port_b.Q_flow + (TC_921_1067.port_b.Q_flow + (TC_427_1067.port_b.Q_flow + (AIR0CabiA003002006.port.Q_flow + (TC_1067_1068.port_a.Q_flow + (TC_1067_1078.port_a.Q_flow + TC_1067_1100.port_a.Q_flow)))))) = 0.0; AIR0CabiA003002006.port.T = TC_1066_1067.port_b.T; AIR0CabiA003002006.port.T = TC_1067_1068.port_a.T; AIR0CabiA003002006.port.T = TC_1067_1078.port_a.T; AIR0CabiA003002006.port.T = TC_1067_1100.port_a.T; AIR0CabiA003002006.port.T = TC_427_1067.port_b.T; AIR0CabiA003002006.port.T = TC_921_1067.port_b.T; AIR0CabiA003002006.port.T = TsAIR0CabiA003002006.port.T; TsAIR0CabiA002002006.port.Q_flow + (TC_920_1066.port_b.Q_flow + (TC_438_1066.port_b.Q_flow + (TC_426_1066.port_b.Q_flow + (AIR0CabiA002002006.port.Q_flow + (TC_1066_1067.port_a.Q_flow + (TC_1066_1077.port_a.Q_flow + TC_1066_1099.port_a.Q_flow)))))) = 0.0; AIR0CabiA002002006.port.T = TC_1066_1067.port_a.T; AIR0CabiA002002006.port.T = TC_1066_1077.port_a.T; AIR0CabiA002002006.port.T = TC_1066_1099.port_a.T; AIR0CabiA002002006.port.T = TC_426_1066.port_b.T; AIR0CabiA002002006.port.T = TC_438_1066.port_b.T; AIR0CabiA002002006.port.T = TC_920_1066.port_b.T; AIR0CabiA002002006.port.T = TsAIR0CabiA002002006.port.T; TsAIR0CabiA007009006.port.Q_flow + (TC_1064_1065.port_b.Q_flow + (TC_1054_1065.port_b.Q_flow + (TC_982_1065.port_b.Q_flow + (TC_870_1065.port_b.Q_flow + (AIR0CabiA007009006.port.Q_flow + (TC_1065_1594.port_a.Q_flow + TC_1065_1647.port_a.Q_flow)))))) = 0.0; AIR0CabiA007009006.port.T = TC_1054_1065.port_b.T; AIR0CabiA007009006.port.T = TC_1064_1065.port_b.T; AIR0CabiA007009006.port.T = TC_1065_1594.port_a.T; AIR0CabiA007009006.port.T = TC_1065_1647.port_a.T; AIR0CabiA007009006.port.T = TC_870_1065.port_b.T; AIR0CabiA007009006.port.T = TC_982_1065.port_b.T; AIR0CabiA007009006.port.T = TsAIR0CabiA007009006.port.T; TsAIR0CabiA006009006.port.Q_flow + (TC_1063_1064.port_b.Q_flow + (TC_1053_1064.port_b.Q_flow + (TC_981_1064.port_b.Q_flow + (TC_869_1064.port_b.Q_flow + (AIR0CabiA006009006.port.Q_flow + (TC_1064_1065.port_a.Q_flow + TC_1064_1593.port_a.Q_flow)))))) = 0.0; AIR0CabiA006009006.port.T = TC_1053_1064.port_b.T; AIR0CabiA006009006.port.T = TC_1063_1064.port_b.T; AIR0CabiA006009006.port.T = TC_1064_1065.port_a.T; AIR0CabiA006009006.port.T = TC_1064_1593.port_a.T; AIR0CabiA006009006.port.T = TC_869_1064.port_b.T; AIR0CabiA006009006.port.T = TC_981_1064.port_b.T; AIR0CabiA006009006.port.T = TsAIR0CabiA006009006.port.T; TsAIR0CabiA005009006.port.Q_flow + (TC_1062_1063.port_b.Q_flow + (TC_1052_1063.port_b.Q_flow + (TC_980_1063.port_b.Q_flow + (TC_868_1063.port_b.Q_flow + (AIR0CabiA005009006.port.Q_flow + (TC_1063_1064.port_a.Q_flow + TC_1063_1592.port_a.Q_flow)))))) = 0.0; AIR0CabiA005009006.port.T = TC_1052_1063.port_b.T; AIR0CabiA005009006.port.T = TC_1062_1063.port_b.T; AIR0CabiA005009006.port.T = TC_1063_1064.port_a.T; AIR0CabiA005009006.port.T = TC_1063_1592.port_a.T; AIR0CabiA005009006.port.T = TC_868_1063.port_b.T; AIR0CabiA005009006.port.T = TC_980_1063.port_b.T; AIR0CabiA005009006.port.T = TsAIR0CabiA005009006.port.T; TsAIR0CabiA004009006.port.Q_flow + (TC_1061_1062.port_b.Q_flow + (TC_1051_1062.port_b.Q_flow + (TC_979_1062.port_b.Q_flow + (TC_867_1062.port_b.Q_flow + (AIR0CabiA004009006.port.Q_flow + (TC_1062_1063.port_a.Q_flow + TC_1062_1591.port_a.Q_flow)))))) = 0.0; AIR0CabiA004009006.port.T = TC_1051_1062.port_b.T; AIR0CabiA004009006.port.T = TC_1061_1062.port_b.T; AIR0CabiA004009006.port.T = TC_1062_1063.port_a.T; AIR0CabiA004009006.port.T = TC_1062_1591.port_a.T; AIR0CabiA004009006.port.T = TC_867_1062.port_b.T; AIR0CabiA004009006.port.T = TC_979_1062.port_b.T; AIR0CabiA004009006.port.T = TsAIR0CabiA004009006.port.T; TsAIR0CabiA003009006.port.Q_flow + (TC_1060_1061.port_b.Q_flow + (TC_1050_1061.port_b.Q_flow + (TC_978_1061.port_b.Q_flow + (TC_866_1061.port_b.Q_flow + (AIR0CabiA003009006.port.Q_flow + (TC_1061_1062.port_a.Q_flow + TC_1061_1590.port_a.Q_flow)))))) = 0.0; AIR0CabiA003009006.port.T = TC_1050_1061.port_b.T; AIR0CabiA003009006.port.T = TC_1060_1061.port_b.T; AIR0CabiA003009006.port.T = TC_1061_1062.port_a.T; AIR0CabiA003009006.port.T = TC_1061_1590.port_a.T; AIR0CabiA003009006.port.T = TC_866_1061.port_b.T; AIR0CabiA003009006.port.T = TC_978_1061.port_b.T; AIR0CabiA003009006.port.T = TsAIR0CabiA003009006.port.T; TsAIR0CabiA002009006.port.Q_flow + (TC_1049_1060.port_b.Q_flow + (TC_977_1060.port_b.Q_flow + (TC_865_1060.port_b.Q_flow + (TC_452_1060.port_b.Q_flow + (AIR0CabiA002009006.port.Q_flow + (TC_1060_1061.port_a.Q_flow + TC_1060_1122.port_a.Q_flow)))))) = 0.0; AIR0CabiA002009006.port.T = TC_1049_1060.port_b.T; AIR0CabiA002009006.port.T = TC_1060_1061.port_a.T; AIR0CabiA002009006.port.T = TC_1060_1122.port_a.T; AIR0CabiA002009006.port.T = TC_452_1060.port_b.T; AIR0CabiA002009006.port.T = TC_865_1060.port_b.T; AIR0CabiA002009006.port.T = TC_977_1060.port_b.T; AIR0CabiA002009006.port.T = TsAIR0CabiA002009006.port.T; TsAIR0CabiA012008006.port.Q_flow + (TC_1058_1059.port_b.Q_flow + (TC_1048_1059.port_b.Q_flow + (TC_976_1059.port_b.Q_flow + (TC_864_1059.port_b.Q_flow + (TC_451_1059.port_b.Q_flow + (AIR0CabiA012008006.port.Q_flow + TC_1059_1121.port_a.Q_flow)))))) = 0.0; AIR0CabiA012008006.port.T = TC_1048_1059.port_b.T; AIR0CabiA012008006.port.T = TC_1058_1059.port_b.T; AIR0CabiA012008006.port.T = TC_1059_1121.port_a.T; AIR0CabiA012008006.port.T = TC_451_1059.port_b.T; AIR0CabiA012008006.port.T = TC_864_1059.port_b.T; AIR0CabiA012008006.port.T = TC_976_1059.port_b.T; AIR0CabiA012008006.port.T = TsAIR0CabiA012008006.port.T; TsAIR0CabiA011008006.port.Q_flow + (TC_1057_1058.port_b.Q_flow + (TC_1047_1058.port_b.Q_flow + (TC_975_1058.port_b.Q_flow + (TC_863_1058.port_b.Q_flow + (AIR0CabiA011008006.port.Q_flow + (TC_1058_1059.port_a.Q_flow + TC_1058_1589.port_a.Q_flow)))))) = 0.0; AIR0CabiA011008006.port.T = TC_1047_1058.port_b.T; AIR0CabiA011008006.port.T = TC_1057_1058.port_b.T; AIR0CabiA011008006.port.T = TC_1058_1059.port_a.T; AIR0CabiA011008006.port.T = TC_1058_1589.port_a.T; AIR0CabiA011008006.port.T = TC_863_1058.port_b.T; AIR0CabiA011008006.port.T = TC_975_1058.port_b.T; AIR0CabiA011008006.port.T = TsAIR0CabiA011008006.port.T; TsAIR0CabiA010008006.port.Q_flow + (TC_1056_1057.port_b.Q_flow + (TC_1046_1057.port_b.Q_flow + (TC_862_1057.port_b.Q_flow + (AIR0CabiA010008006.port.Q_flow + (TC_1057_1058.port_a.Q_flow + (TC_1057_1588.port_a.Q_flow + TC_1057_1649.port_a.Q_flow)))))) = 0.0; AIR0CabiA010008006.port.T = TC_1046_1057.port_b.T; AIR0CabiA010008006.port.T = TC_1056_1057.port_b.T; AIR0CabiA010008006.port.T = TC_1057_1058.port_a.T; AIR0CabiA010008006.port.T = TC_1057_1588.port_a.T; AIR0CabiA010008006.port.T = TC_1057_1649.port_a.T; AIR0CabiA010008006.port.T = TC_862_1057.port_b.T; AIR0CabiA010008006.port.T = TsAIR0CabiA010008006.port.T; TsAIR0CabiA009008006.port.Q_flow + (TC_1055_1056.port_b.Q_flow + (TC_1045_1056.port_b.Q_flow + (TC_861_1056.port_b.Q_flow + (AIR0CabiA009008006.port.Q_flow + (TC_1056_1057.port_a.Q_flow + (TC_1056_1587.port_a.Q_flow + TC_1056_1648.port_a.Q_flow)))))) = 0.0; AIR0CabiA009008006.port.T = TC_1045_1056.port_b.T; AIR0CabiA009008006.port.T = TC_1055_1056.port_b.T; AIR0CabiA009008006.port.T = TC_1056_1057.port_a.T; AIR0CabiA009008006.port.T = TC_1056_1587.port_a.T; AIR0CabiA009008006.port.T = TC_1056_1648.port_a.T; AIR0CabiA009008006.port.T = TC_861_1056.port_b.T; AIR0CabiA009008006.port.T = TsAIR0CabiA009008006.port.T; TsAIR0CabiA008008006.port.Q_flow + (TC_1054_1055.port_b.Q_flow + (TC_1044_1055.port_b.Q_flow + (TC_860_1055.port_b.Q_flow + (AIR0CabiA008008006.port.Q_flow + (TC_1055_1056.port_a.Q_flow + (TC_1055_1586.port_a.Q_flow + TC_1055_1647.port_a.Q_flow)))))) = 0.0; AIR0CabiA008008006.port.T = TC_1044_1055.port_b.T; AIR0CabiA008008006.port.T = TC_1054_1055.port_b.T; AIR0CabiA008008006.port.T = TC_1055_1056.port_a.T; AIR0CabiA008008006.port.T = TC_1055_1586.port_a.T; AIR0CabiA008008006.port.T = TC_1055_1647.port_a.T; AIR0CabiA008008006.port.T = TC_860_1055.port_b.T; AIR0CabiA008008006.port.T = TsAIR0CabiA008008006.port.T; TsAIR0CabiA007008006.port.Q_flow + (TC_1053_1054.port_b.Q_flow + (TC_1043_1054.port_b.Q_flow + (TC_859_1054.port_b.Q_flow + (AIR0CabiA007008006.port.Q_flow + (TC_1054_1055.port_a.Q_flow + (TC_1054_1065.port_a.Q_flow + TC_1054_1585.port_a.Q_flow)))))) = 0.0; AIR0CabiA007008006.port.T = TC_1043_1054.port_b.T; AIR0CabiA007008006.port.T = TC_1053_1054.port_b.T; AIR0CabiA007008006.port.T = TC_1054_1055.port_a.T; AIR0CabiA007008006.port.T = TC_1054_1065.port_a.T; AIR0CabiA007008006.port.T = TC_1054_1585.port_a.T; AIR0CabiA007008006.port.T = TC_859_1054.port_b.T; AIR0CabiA007008006.port.T = TsAIR0CabiA007008006.port.T; TsAIR0CabiA006008006.port.Q_flow + (TC_1052_1053.port_b.Q_flow + (TC_1042_1053.port_b.Q_flow + (TC_858_1053.port_b.Q_flow + (AIR0CabiA006008006.port.Q_flow + (TC_1053_1054.port_a.Q_flow + (TC_1053_1064.port_a.Q_flow + TC_1053_1584.port_a.Q_flow)))))) = 0.0; AIR0CabiA006008006.port.T = TC_1042_1053.port_b.T; AIR0CabiA006008006.port.T = TC_1052_1053.port_b.T; AIR0CabiA006008006.port.T = TC_1053_1054.port_a.T; AIR0CabiA006008006.port.T = TC_1053_1064.port_a.T; AIR0CabiA006008006.port.T = TC_1053_1584.port_a.T; AIR0CabiA006008006.port.T = TC_858_1053.port_b.T; AIR0CabiA006008006.port.T = TsAIR0CabiA006008006.port.T; TsAIR0CabiA005008006.port.Q_flow + (TC_1051_1052.port_b.Q_flow + (TC_1041_1052.port_b.Q_flow + (TC_857_1052.port_b.Q_flow + (AIR0CabiA005008006.port.Q_flow + (TC_1052_1053.port_a.Q_flow + (TC_1052_1063.port_a.Q_flow + TC_1052_1583.port_a.Q_flow)))))) = 0.0; AIR0CabiA005008006.port.T = TC_1041_1052.port_b.T; AIR0CabiA005008006.port.T = TC_1051_1052.port_b.T; AIR0CabiA005008006.port.T = TC_1052_1053.port_a.T; AIR0CabiA005008006.port.T = TC_1052_1063.port_a.T; AIR0CabiA005008006.port.T = TC_1052_1583.port_a.T; AIR0CabiA005008006.port.T = TC_857_1052.port_b.T; AIR0CabiA005008006.port.T = TsAIR0CabiA005008006.port.T; TsAIR0CabiA004008006.port.Q_flow + (TC_1050_1051.port_b.Q_flow + (TC_1040_1051.port_b.Q_flow + (TC_856_1051.port_b.Q_flow + (AIR0CabiA004008006.port.Q_flow + (TC_1051_1052.port_a.Q_flow + (TC_1051_1062.port_a.Q_flow + TC_1051_1582.port_a.Q_flow)))))) = 0.0; AIR0CabiA004008006.port.T = TC_1040_1051.port_b.T; AIR0CabiA004008006.port.T = TC_1050_1051.port_b.T; AIR0CabiA004008006.port.T = TC_1051_1052.port_a.T; AIR0CabiA004008006.port.T = TC_1051_1062.port_a.T; AIR0CabiA004008006.port.T = TC_1051_1582.port_a.T; AIR0CabiA004008006.port.T = TC_856_1051.port_b.T; AIR0CabiA004008006.port.T = TsAIR0CabiA004008006.port.T; TsAIR0CabiA003008006.port.Q_flow + (TC_1049_1050.port_b.Q_flow + (TC_1039_1050.port_b.Q_flow + (TC_855_1050.port_b.Q_flow + (AIR0CabiA003008006.port.Q_flow + (TC_1050_1051.port_a.Q_flow + (TC_1050_1061.port_a.Q_flow + TC_1050_1581.port_a.Q_flow)))))) = 0.0; AIR0CabiA003008006.port.T = TC_1039_1050.port_b.T; AIR0CabiA003008006.port.T = TC_1049_1050.port_b.T; AIR0CabiA003008006.port.T = TC_1050_1051.port_a.T; AIR0CabiA003008006.port.T = TC_1050_1061.port_a.T; AIR0CabiA003008006.port.T = TC_1050_1581.port_a.T; AIR0CabiA003008006.port.T = TC_855_1050.port_b.T; AIR0CabiA003008006.port.T = TsAIR0CabiA003008006.port.T; TsAIR0CabiA002008006.port.Q_flow + (TC_1038_1049.port_b.Q_flow + (TC_854_1049.port_b.Q_flow + (TC_450_1049.port_b.Q_flow + (AIR0CabiA002008006.port.Q_flow + (TC_1049_1050.port_a.Q_flow + (TC_1049_1060.port_a.Q_flow + TC_1049_1120.port_a.Q_flow)))))) = 0.0; AIR0CabiA002008006.port.T = TC_1038_1049.port_b.T; AIR0CabiA002008006.port.T = TC_1049_1050.port_a.T; AIR0CabiA002008006.port.T = TC_1049_1060.port_a.T; AIR0CabiA002008006.port.T = TC_1049_1120.port_a.T; AIR0CabiA002008006.port.T = TC_450_1049.port_b.T; AIR0CabiA002008006.port.T = TC_854_1049.port_b.T; AIR0CabiA002008006.port.T = TsAIR0CabiA002008006.port.T; TsAIR0CabiA012007006.port.Q_flow + (TC_1047_1048.port_b.Q_flow + (TC_1037_1048.port_b.Q_flow + (TC_853_1048.port_b.Q_flow + (TC_449_1048.port_b.Q_flow + (AIR0CabiA012007006.port.Q_flow + (TC_1048_1059.port_a.Q_flow + TC_1048_1119.port_a.Q_flow)))))) = 0.0; AIR0CabiA012007006.port.T = TC_1037_1048.port_b.T; AIR0CabiA012007006.port.T = TC_1047_1048.port_b.T; AIR0CabiA012007006.port.T = TC_1048_1059.port_a.T; AIR0CabiA012007006.port.T = TC_1048_1119.port_a.T; AIR0CabiA012007006.port.T = TC_449_1048.port_b.T; AIR0CabiA012007006.port.T = TC_853_1048.port_b.T; AIR0CabiA012007006.port.T = TsAIR0CabiA012007006.port.T; TsAIR0CabiA011007006.port.Q_flow + (TC_1046_1047.port_b.Q_flow + (TC_1036_1047.port_b.Q_flow + (TC_852_1047.port_b.Q_flow + (AIR0CabiA011007006.port.Q_flow + (TC_1047_1048.port_a.Q_flow + (TC_1047_1058.port_a.Q_flow + TC_1047_1580.port_a.Q_flow)))))) = 0.0; AIR0CabiA011007006.port.T = TC_1036_1047.port_b.T; AIR0CabiA011007006.port.T = TC_1046_1047.port_b.T; AIR0CabiA011007006.port.T = TC_1047_1048.port_a.T; AIR0CabiA011007006.port.T = TC_1047_1058.port_a.T; AIR0CabiA011007006.port.T = TC_1047_1580.port_a.T; AIR0CabiA011007006.port.T = TC_852_1047.port_b.T; AIR0CabiA011007006.port.T = TsAIR0CabiA011007006.port.T; TsAIR0CabiA010007006.port.Q_flow + (TC_1045_1046.port_b.Q_flow + (TC_1035_1046.port_b.Q_flow + (TC_851_1046.port_b.Q_flow + (AIR0CabiA010007006.port.Q_flow + (TC_1046_1047.port_a.Q_flow + (TC_1046_1057.port_a.Q_flow + TC_1046_1579.port_a.Q_flow)))))) = 0.0; AIR0CabiA010007006.port.T = TC_1035_1046.port_b.T; AIR0CabiA010007006.port.T = TC_1045_1046.port_b.T; AIR0CabiA010007006.port.T = TC_1046_1047.port_a.T; AIR0CabiA010007006.port.T = TC_1046_1057.port_a.T; AIR0CabiA010007006.port.T = TC_1046_1579.port_a.T; AIR0CabiA010007006.port.T = TC_851_1046.port_b.T; AIR0CabiA010007006.port.T = TsAIR0CabiA010007006.port.T; TsAIR0CabiA009007006.port.Q_flow + (TC_1044_1045.port_b.Q_flow + (TC_850_1045.port_b.Q_flow + (AIR0CabiA009007006.port.Q_flow + (TC_1045_1046.port_a.Q_flow + (TC_1045_1056.port_a.Q_flow + (TC_1045_1578.port_a.Q_flow + TC_1045_1646.port_a.Q_flow)))))) = 0.0; AIR0CabiA009007006.port.T = TC_1044_1045.port_b.T; AIR0CabiA009007006.port.T = TC_1045_1046.port_a.T; AIR0CabiA009007006.port.T = TC_1045_1056.port_a.T; AIR0CabiA009007006.port.T = TC_1045_1578.port_a.T; AIR0CabiA009007006.port.T = TC_1045_1646.port_a.T; AIR0CabiA009007006.port.T = TC_850_1045.port_b.T; AIR0CabiA009007006.port.T = TsAIR0CabiA009007006.port.T; TsAIR0CabiA008007006.port.Q_flow + (TC_1043_1044.port_b.Q_flow + (TC_849_1044.port_b.Q_flow + (AIR0CabiA008007006.port.Q_flow + (TC_1044_1045.port_a.Q_flow + (TC_1044_1055.port_a.Q_flow + (TC_1044_1577.port_a.Q_flow + TC_1044_1645.port_a.Q_flow)))))) = 0.0; AIR0CabiA008007006.port.T = TC_1043_1044.port_b.T; AIR0CabiA008007006.port.T = TC_1044_1045.port_a.T; AIR0CabiA008007006.port.T = TC_1044_1055.port_a.T; AIR0CabiA008007006.port.T = TC_1044_1577.port_a.T; AIR0CabiA008007006.port.T = TC_1044_1645.port_a.T; AIR0CabiA008007006.port.T = TC_849_1044.port_b.T; AIR0CabiA008007006.port.T = TsAIR0CabiA008007006.port.T; TsAIR0CabiA007007006.port.Q_flow + (TC_1042_1043.port_b.Q_flow + (TC_848_1043.port_b.Q_flow + (AIR0CabiA007007006.port.Q_flow + (TC_1043_1044.port_a.Q_flow + (TC_1043_1054.port_a.Q_flow + (TC_1043_1576.port_a.Q_flow + TC_1043_1644.port_a.Q_flow)))))) = 0.0; AIR0CabiA007007006.port.T = TC_1042_1043.port_b.T; AIR0CabiA007007006.port.T = TC_1043_1044.port_a.T; AIR0CabiA007007006.port.T = TC_1043_1054.port_a.T; AIR0CabiA007007006.port.T = TC_1043_1576.port_a.T; AIR0CabiA007007006.port.T = TC_1043_1644.port_a.T; AIR0CabiA007007006.port.T = TC_848_1043.port_b.T; AIR0CabiA007007006.port.T = TsAIR0CabiA007007006.port.T; TsAIR0CabiA006007006.port.Q_flow + (TC_1041_1042.port_b.Q_flow + (TC_847_1042.port_b.Q_flow + (AIR0CabiA006007006.port.Q_flow + (TC_1042_1043.port_a.Q_flow + (TC_1042_1053.port_a.Q_flow + (TC_1042_1575.port_a.Q_flow + TC_1042_1643.port_a.Q_flow)))))) = 0.0; AIR0CabiA006007006.port.T = TC_1041_1042.port_b.T; AIR0CabiA006007006.port.T = TC_1042_1043.port_a.T; AIR0CabiA006007006.port.T = TC_1042_1053.port_a.T; AIR0CabiA006007006.port.T = TC_1042_1575.port_a.T; AIR0CabiA006007006.port.T = TC_1042_1643.port_a.T; AIR0CabiA006007006.port.T = TC_847_1042.port_b.T; AIR0CabiA006007006.port.T = TsAIR0CabiA006007006.port.T; TsAIR0CabiA005007006.port.Q_flow + (TC_1040_1041.port_b.Q_flow + (TC_1034_1041.port_b.Q_flow + (TC_846_1041.port_b.Q_flow + (AIR0CabiA005007006.port.Q_flow + (TC_1041_1042.port_a.Q_flow + (TC_1041_1052.port_a.Q_flow + TC_1041_1574.port_a.Q_flow)))))) = 0.0; AIR0CabiA005007006.port.T = TC_1034_1041.port_b.T; AIR0CabiA005007006.port.T = TC_1040_1041.port_b.T; AIR0CabiA005007006.port.T = TC_1041_1042.port_a.T; AIR0CabiA005007006.port.T = TC_1041_1052.port_a.T; AIR0CabiA005007006.port.T = TC_1041_1574.port_a.T; AIR0CabiA005007006.port.T = TC_846_1041.port_b.T; AIR0CabiA005007006.port.T = TsAIR0CabiA005007006.port.T; TsAIR0CabiA004007006.port.Q_flow + (TC_1039_1040.port_b.Q_flow + (TC_1033_1040.port_b.Q_flow + (TC_845_1040.port_b.Q_flow + (AIR0CabiA004007006.port.Q_flow + (TC_1040_1041.port_a.Q_flow + (TC_1040_1051.port_a.Q_flow + TC_1040_1573.port_a.Q_flow)))))) = 0.0; AIR0CabiA004007006.port.T = TC_1033_1040.port_b.T; AIR0CabiA004007006.port.T = TC_1039_1040.port_b.T; AIR0CabiA004007006.port.T = TC_1040_1041.port_a.T; AIR0CabiA004007006.port.T = TC_1040_1051.port_a.T; AIR0CabiA004007006.port.T = TC_1040_1573.port_a.T; AIR0CabiA004007006.port.T = TC_845_1040.port_b.T; AIR0CabiA004007006.port.T = TsAIR0CabiA004007006.port.T; TsAIR0CabiA003007006.port.Q_flow + (TC_1038_1039.port_b.Q_flow + (TC_1032_1039.port_b.Q_flow + (TC_844_1039.port_b.Q_flow + (AIR0CabiA003007006.port.Q_flow + (TC_1039_1040.port_a.Q_flow + (TC_1039_1050.port_a.Q_flow + TC_1039_1572.port_a.Q_flow)))))) = 0.0; AIR0CabiA003007006.port.T = TC_1032_1039.port_b.T; AIR0CabiA003007006.port.T = TC_1038_1039.port_b.T; AIR0CabiA003007006.port.T = TC_1039_1040.port_a.T; AIR0CabiA003007006.port.T = TC_1039_1050.port_a.T; AIR0CabiA003007006.port.T = TC_1039_1572.port_a.T; AIR0CabiA003007006.port.T = TC_844_1039.port_b.T; AIR0CabiA003007006.port.T = TsAIR0CabiA003007006.port.T; TsAIR0CabiA002007006.port.Q_flow + (TC_1031_1038.port_b.Q_flow + (TC_843_1038.port_b.Q_flow + (TC_448_1038.port_b.Q_flow + (AIR0CabiA002007006.port.Q_flow + (TC_1038_1039.port_a.Q_flow + (TC_1038_1049.port_a.Q_flow + TC_1038_1118.port_a.Q_flow)))))) = 0.0; AIR0CabiA002007006.port.T = TC_1031_1038.port_b.T; AIR0CabiA002007006.port.T = TC_1038_1039.port_a.T; AIR0CabiA002007006.port.T = TC_1038_1049.port_a.T; AIR0CabiA002007006.port.T = TC_1038_1118.port_a.T; AIR0CabiA002007006.port.T = TC_448_1038.port_b.T; AIR0CabiA002007006.port.T = TC_843_1038.port_b.T; AIR0CabiA002007006.port.T = TsAIR0CabiA002007006.port.T; TsAIR0CabiA012006006.port.Q_flow + (TC_1036_1037.port_b.Q_flow + (TC_1030_1037.port_b.Q_flow + (TC_974_1037.port_b.Q_flow + (TC_447_1037.port_b.Q_flow + (AIR0CabiA012006006.port.Q_flow + (TC_1037_1048.port_a.Q_flow + TC_1037_1117.port_a.Q_flow)))))) = 0.0; AIR0CabiA012006006.port.T = TC_1030_1037.port_b.T; AIR0CabiA012006006.port.T = TC_1036_1037.port_b.T; AIR0CabiA012006006.port.T = TC_1037_1048.port_a.T; AIR0CabiA012006006.port.T = TC_1037_1117.port_a.T; AIR0CabiA012006006.port.T = TC_447_1037.port_b.T; AIR0CabiA012006006.port.T = TC_974_1037.port_b.T; AIR0CabiA012006006.port.T = TsAIR0CabiA012006006.port.T; TsAIR0CabiA011006006.port.Q_flow + (TC_1035_1036.port_b.Q_flow + (TC_1029_1036.port_b.Q_flow + (TC_973_1036.port_b.Q_flow + (AIR0CabiA011006006.port.Q_flow + (TC_1036_1037.port_a.Q_flow + (TC_1036_1047.port_a.Q_flow + TC_1036_1571.port_a.Q_flow)))))) = 0.0; AIR0CabiA011006006.port.T = TC_1029_1036.port_b.T; AIR0CabiA011006006.port.T = TC_1035_1036.port_b.T; AIR0CabiA011006006.port.T = TC_1036_1037.port_a.T; AIR0CabiA011006006.port.T = TC_1036_1047.port_a.T; AIR0CabiA011006006.port.T = TC_1036_1571.port_a.T; AIR0CabiA011006006.port.T = TC_973_1036.port_b.T; AIR0CabiA011006006.port.T = TsAIR0CabiA011006006.port.T; TsAIR0CabiA010006006.port.Q_flow + (TC_1028_1035.port_b.Q_flow + (TC_972_1035.port_b.Q_flow + (AIR0CabiA010006006.port.Q_flow + (TC_1035_1036.port_a.Q_flow + (TC_1035_1046.port_a.Q_flow + (TC_1035_1570.port_a.Q_flow + TC_1035_1646.port_a.Q_flow)))))) = 0.0; AIR0CabiA010006006.port.T = TC_1028_1035.port_b.T; AIR0CabiA010006006.port.T = TC_1035_1036.port_a.T; AIR0CabiA010006006.port.T = TC_1035_1046.port_a.T; AIR0CabiA010006006.port.T = TC_1035_1570.port_a.T; AIR0CabiA010006006.port.T = TC_1035_1646.port_a.T; AIR0CabiA010006006.port.T = TC_972_1035.port_b.T; AIR0CabiA010006006.port.T = TsAIR0CabiA010006006.port.T; TsAIR0CabiA005006006.port.Q_flow + (TC_1033_1034.port_b.Q_flow + (TC_967_1034.port_b.Q_flow + (AIR0CabiA005006006.port.Q_flow + (TC_1034_1041.port_a.Q_flow + (TC_1034_1098.port_a.Q_flow + (TC_1034_1565.port_a.Q_flow + TC_1034_1643.port_a.Q_flow)))))) = 0.0; AIR0CabiA005006006.port.T = TC_1033_1034.port_b.T; AIR0CabiA005006006.port.T = TC_1034_1041.port_a.T; AIR0CabiA005006006.port.T = TC_1034_1098.port_a.T; AIR0CabiA005006006.port.T = TC_1034_1565.port_a.T; AIR0CabiA005006006.port.T = TC_1034_1643.port_a.T; AIR0CabiA005006006.port.T = TC_967_1034.port_b.T; AIR0CabiA005006006.port.T = TsAIR0CabiA005006006.port.T; TsAIR0CabiA004006006.port.Q_flow + (TC_1032_1033.port_b.Q_flow + (TC_966_1033.port_b.Q_flow + (AIR0CabiA004006006.port.Q_flow + (TC_1033_1034.port_a.Q_flow + (TC_1033_1040.port_a.Q_flow + (TC_1033_1097.port_a.Q_flow + TC_1033_1564.port_a.Q_flow)))))) = 0.0; AIR0CabiA004006006.port.T = TC_1032_1033.port_b.T; AIR0CabiA004006006.port.T = TC_1033_1034.port_a.T; AIR0CabiA004006006.port.T = TC_1033_1040.port_a.T; AIR0CabiA004006006.port.T = TC_1033_1097.port_a.T; AIR0CabiA004006006.port.T = TC_1033_1564.port_a.T; AIR0CabiA004006006.port.T = TC_966_1033.port_b.T; AIR0CabiA004006006.port.T = TsAIR0CabiA004006006.port.T; TsAIR0CabiA003006006.port.Q_flow + (TC_1031_1032.port_b.Q_flow + (TC_965_1032.port_b.Q_flow + (AIR0CabiA003006006.port.Q_flow + (TC_1032_1033.port_a.Q_flow + (TC_1032_1039.port_a.Q_flow + (TC_1032_1096.port_a.Q_flow + TC_1032_1563.port_a.Q_flow)))))) = 0.0; AIR0CabiA003006006.port.T = TC_1031_1032.port_b.T; AIR0CabiA003006006.port.T = TC_1032_1033.port_a.T; AIR0CabiA003006006.port.T = TC_1032_1039.port_a.T; AIR0CabiA003006006.port.T = TC_1032_1096.port_a.T; AIR0CabiA003006006.port.T = TC_1032_1563.port_a.T; AIR0CabiA003006006.port.T = TC_965_1032.port_b.T; AIR0CabiA003006006.port.T = TsAIR0CabiA003006006.port.T; TsAIR0CabiA002006006.port.Q_flow + (TC_964_1031.port_b.Q_flow + (TC_446_1031.port_b.Q_flow + (AIR0CabiA002006006.port.Q_flow + (TC_1031_1032.port_a.Q_flow + (TC_1031_1038.port_a.Q_flow + (TC_1031_1095.port_a.Q_flow + TC_1031_1116.port_a.Q_flow)))))) = 0.0; AIR0CabiA002006006.port.T = TC_1031_1032.port_a.T; AIR0CabiA002006006.port.T = TC_1031_1038.port_a.T; AIR0CabiA002006006.port.T = TC_1031_1095.port_a.T; AIR0CabiA002006006.port.T = TC_1031_1116.port_a.T; AIR0CabiA002006006.port.T = TC_446_1031.port_b.T; AIR0CabiA002006006.port.T = TC_964_1031.port_b.T; AIR0CabiA002006006.port.T = TsAIR0CabiA002006006.port.T; TsAIR0CabiA012005006.port.Q_flow + (TC_1029_1030.port_b.Q_flow + (TC_963_1030.port_b.Q_flow + (TC_445_1030.port_b.Q_flow + (AIR0CabiA012005006.port.Q_flow + (TC_1030_1037.port_a.Q_flow + (TC_1030_1094.port_a.Q_flow + TC_1030_1115.port_a.Q_flow)))))) = 0.0; AIR0CabiA012005006.port.T = TC_1029_1030.port_b.T; AIR0CabiA012005006.port.T = TC_1030_1037.port_a.T; AIR0CabiA012005006.port.T = TC_1030_1094.port_a.T; AIR0CabiA012005006.port.T = TC_1030_1115.port_a.T; AIR0CabiA012005006.port.T = TC_445_1030.port_b.T; AIR0CabiA012005006.port.T = TC_963_1030.port_b.T; AIR0CabiA012005006.port.T = TsAIR0CabiA012005006.port.T; TsAIR0CabiA011005006.port.Q_flow + (TC_1028_1029.port_b.Q_flow + (TC_962_1029.port_b.Q_flow + (AIR0CabiA011005006.port.Q_flow + (TC_1029_1030.port_a.Q_flow + (TC_1029_1036.port_a.Q_flow + (TC_1029_1093.port_a.Q_flow + TC_1029_1634.port_a.Q_flow)))))) = 0.0; AIR0CabiA011005006.port.T = TC_1028_1029.port_b.T; AIR0CabiA011005006.port.T = TC_1029_1030.port_a.T; AIR0CabiA011005006.port.T = TC_1029_1036.port_a.T; AIR0CabiA011005006.port.T = TC_1029_1093.port_a.T; AIR0CabiA011005006.port.T = TC_1029_1634.port_a.T; AIR0CabiA011005006.port.T = TC_962_1029.port_b.T; AIR0CabiA011005006.port.T = TsAIR0CabiA011005006.port.T; TsAIR0CabiA010005006.port.Q_flow + (TC_961_1028.port_b.Q_flow + (AIR0CabiA010005006.port.Q_flow + (TC_1028_1029.port_a.Q_flow + (TC_1028_1035.port_a.Q_flow + (TC_1028_1092.port_a.Q_flow + (TC_1028_1633.port_a.Q_flow + TC_1028_1642.port_a.Q_flow)))))) = 0.0; AIR0CabiA010005006.port.T = TC_1028_1029.port_a.T; AIR0CabiA010005006.port.T = TC_1028_1035.port_a.T; AIR0CabiA010005006.port.T = TC_1028_1092.port_a.T; AIR0CabiA010005006.port.T = TC_1028_1633.port_a.T; AIR0CabiA010005006.port.T = TC_1028_1642.port_a.T; AIR0CabiA010005006.port.T = TC_961_1028.port_b.T; AIR0CabiA010005006.port.T = TsAIR0CabiA010005006.port.T; TsAIR0CabiA012015006.port.Q_flow + (TC_1026_1027.port_b.Q_flow + (TC_1016_1027.port_b.Q_flow + (TC_831_1027.port_b.Q_flow + (TC_477_1027.port_b.Q_flow + (TC_465_1027.port_b.Q_flow + (AIR0CabiA012015006.port.Q_flow + TC_1027_1144.port_a.Q_flow)))))) = 0.0; AIR0CabiA012015006.port.T = TC_1016_1027.port_b.T; AIR0CabiA012015006.port.T = TC_1026_1027.port_b.T; AIR0CabiA012015006.port.T = TC_1027_1144.port_a.T; AIR0CabiA012015006.port.T = TC_465_1027.port_b.T; AIR0CabiA012015006.port.T = TC_477_1027.port_b.T; AIR0CabiA012015006.port.T = TC_831_1027.port_b.T; AIR0CabiA012015006.port.T = TsAIR0CabiA012015006.port.T; TsAIR0CabiA011015006.port.Q_flow + (TC_1025_1026.port_b.Q_flow + (TC_1015_1026.port_b.Q_flow + (TC_830_1026.port_b.Q_flow + (TC_476_1026.port_b.Q_flow + (AIR0CabiA011015006.port.Q_flow + (TC_1026_1027.port_a.Q_flow + TC_1026_1143.port_a.Q_flow)))))) = 0.0; AIR0CabiA011015006.port.T = TC_1015_1026.port_b.T; AIR0CabiA011015006.port.T = TC_1025_1026.port_b.T; AIR0CabiA011015006.port.T = TC_1026_1027.port_a.T; AIR0CabiA011015006.port.T = TC_1026_1143.port_a.T; AIR0CabiA011015006.port.T = TC_476_1026.port_b.T; AIR0CabiA011015006.port.T = TC_830_1026.port_b.T; AIR0CabiA011015006.port.T = TsAIR0CabiA011015006.port.T; TsAIR0CabiA010015006.port.Q_flow + (TC_1024_1025.port_b.Q_flow + (TC_1014_1025.port_b.Q_flow + (TC_829_1025.port_b.Q_flow + (TC_475_1025.port_b.Q_flow + (AIR0CabiA010015006.port.Q_flow + (TC_1025_1026.port_a.Q_flow + TC_1025_1142.port_a.Q_flow)))))) = 0.0; AIR0CabiA010015006.port.T = TC_1014_1025.port_b.T; AIR0CabiA010015006.port.T = TC_1024_1025.port_b.T; AIR0CabiA010015006.port.T = TC_1025_1026.port_a.T; AIR0CabiA010015006.port.T = TC_1025_1142.port_a.T; AIR0CabiA010015006.port.T = TC_475_1025.port_b.T; AIR0CabiA010015006.port.T = TC_829_1025.port_b.T; AIR0CabiA010015006.port.T = TsAIR0CabiA010015006.port.T; TsAIR0CabiA009015006.port.Q_flow + (TC_1023_1024.port_b.Q_flow + (TC_1013_1024.port_b.Q_flow + (TC_828_1024.port_b.Q_flow + (TC_474_1024.port_b.Q_flow + (AIR0CabiA009015006.port.Q_flow + (TC_1024_1025.port_a.Q_flow + TC_1024_1141.port_a.Q_flow)))))) = 0.0; AIR0CabiA009015006.port.T = TC_1013_1024.port_b.T; AIR0CabiA009015006.port.T = TC_1023_1024.port_b.T; AIR0CabiA009015006.port.T = TC_1024_1025.port_a.T; AIR0CabiA009015006.port.T = TC_1024_1141.port_a.T; AIR0CabiA009015006.port.T = TC_474_1024.port_b.T; AIR0CabiA009015006.port.T = TC_828_1024.port_b.T; AIR0CabiA009015006.port.T = TsAIR0CabiA009015006.port.T; TsAIR0CabiA008015006.port.Q_flow + (TC_1022_1023.port_b.Q_flow + (TC_1012_1023.port_b.Q_flow + (TC_827_1023.port_b.Q_flow + (TC_473_1023.port_b.Q_flow + (AIR0CabiA008015006.port.Q_flow + (TC_1023_1024.port_a.Q_flow + TC_1023_1140.port_a.Q_flow)))))) = 0.0; AIR0CabiA008015006.port.T = TC_1012_1023.port_b.T; AIR0CabiA008015006.port.T = TC_1022_1023.port_b.T; AIR0CabiA008015006.port.T = TC_1023_1024.port_a.T; AIR0CabiA008015006.port.T = TC_1023_1140.port_a.T; AIR0CabiA008015006.port.T = TC_473_1023.port_b.T; AIR0CabiA008015006.port.T = TC_827_1023.port_b.T; AIR0CabiA008015006.port.T = TsAIR0CabiA008015006.port.T; TsAIR0CabiA007015006.port.Q_flow + (TC_1021_1022.port_b.Q_flow + (TC_1011_1022.port_b.Q_flow + (TC_826_1022.port_b.Q_flow + (TC_472_1022.port_b.Q_flow + (AIR0CabiA007015006.port.Q_flow + (TC_1022_1023.port_a.Q_flow + TC_1022_1139.port_a.Q_flow)))))) = 0.0; AIR0CabiA007015006.port.T = TC_1011_1022.port_b.T; AIR0CabiA007015006.port.T = TC_1021_1022.port_b.T; AIR0CabiA007015006.port.T = TC_1022_1023.port_a.T; AIR0CabiA007015006.port.T = TC_1022_1139.port_a.T; AIR0CabiA007015006.port.T = TC_472_1022.port_b.T; AIR0CabiA007015006.port.T = TC_826_1022.port_b.T; AIR0CabiA007015006.port.T = TsAIR0CabiA007015006.port.T; TsAIR0CabiA006015006.port.Q_flow + (TC_1020_1021.port_b.Q_flow + (TC_1010_1021.port_b.Q_flow + (TC_825_1021.port_b.Q_flow + (TC_471_1021.port_b.Q_flow + (AIR0CabiA006015006.port.Q_flow + (TC_1021_1022.port_a.Q_flow + TC_1021_1138.port_a.Q_flow)))))) = 0.0; AIR0CabiA006015006.port.T = TC_1010_1021.port_b.T; AIR0CabiA006015006.port.T = TC_1020_1021.port_b.T; AIR0CabiA006015006.port.T = TC_1021_1022.port_a.T; AIR0CabiA006015006.port.T = TC_1021_1138.port_a.T; AIR0CabiA006015006.port.T = TC_471_1021.port_b.T; AIR0CabiA006015006.port.T = TC_825_1021.port_b.T; AIR0CabiA006015006.port.T = TsAIR0CabiA006015006.port.T; TsAIR0CabiA005015006.port.Q_flow + (TC_1019_1020.port_b.Q_flow + (TC_1009_1020.port_b.Q_flow + (TC_824_1020.port_b.Q_flow + (TC_470_1020.port_b.Q_flow + (AIR0CabiA005015006.port.Q_flow + (TC_1020_1021.port_a.Q_flow + TC_1020_1137.port_a.Q_flow)))))) = 0.0; AIR0CabiA005015006.port.T = TC_1009_1020.port_b.T; AIR0CabiA005015006.port.T = TC_1019_1020.port_b.T; AIR0CabiA005015006.port.T = TC_1020_1021.port_a.T; AIR0CabiA005015006.port.T = TC_1020_1137.port_a.T; AIR0CabiA005015006.port.T = TC_470_1020.port_b.T; AIR0CabiA005015006.port.T = TC_824_1020.port_b.T; AIR0CabiA005015006.port.T = TsAIR0CabiA005015006.port.T; TsAIR0CabiA004015006.port.Q_flow + (TC_1018_1019.port_b.Q_flow + (TC_1008_1019.port_b.Q_flow + (TC_823_1019.port_b.Q_flow + (TC_469_1019.port_b.Q_flow + (AIR0CabiA004015006.port.Q_flow + (TC_1019_1020.port_a.Q_flow + TC_1019_1136.port_a.Q_flow)))))) = 0.0; AIR0CabiA004015006.port.T = TC_1008_1019.port_b.T; AIR0CabiA004015006.port.T = TC_1018_1019.port_b.T; AIR0CabiA004015006.port.T = TC_1019_1020.port_a.T; AIR0CabiA004015006.port.T = TC_1019_1136.port_a.T; AIR0CabiA004015006.port.T = TC_469_1019.port_b.T; AIR0CabiA004015006.port.T = TC_823_1019.port_b.T; AIR0CabiA004015006.port.T = TsAIR0CabiA004015006.port.T; TsAIR0CabiA003015006.port.Q_flow + (TC_1017_1018.port_b.Q_flow + (TC_1007_1018.port_b.Q_flow + (TC_822_1018.port_b.Q_flow + (TC_468_1018.port_b.Q_flow + (AIR0CabiA003015006.port.Q_flow + (TC_1018_1019.port_a.Q_flow + TC_1018_1135.port_a.Q_flow)))))) = 0.0; AIR0CabiA003015006.port.T = TC_1007_1018.port_b.T; AIR0CabiA003015006.port.T = TC_1017_1018.port_b.T; AIR0CabiA003015006.port.T = TC_1018_1019.port_a.T; AIR0CabiA003015006.port.T = TC_1018_1135.port_a.T; AIR0CabiA003015006.port.T = TC_468_1018.port_b.T; AIR0CabiA003015006.port.T = TC_822_1018.port_b.T; AIR0CabiA003015006.port.T = TsAIR0CabiA003015006.port.T; TsAIR0CabiA002015006.port.Q_flow + (TC_1006_1017.port_b.Q_flow + (TC_821_1017.port_b.Q_flow + (TC_467_1017.port_b.Q_flow + (TC_464_1017.port_b.Q_flow + (AIR0CabiA002015006.port.Q_flow + (TC_1017_1018.port_a.Q_flow + TC_1017_1134.port_a.Q_flow)))))) = 0.0; AIR0CabiA002015006.port.T = TC_1006_1017.port_b.T; AIR0CabiA002015006.port.T = TC_1017_1018.port_a.T; AIR0CabiA002015006.port.T = TC_1017_1134.port_a.T; AIR0CabiA002015006.port.T = TC_464_1017.port_b.T; AIR0CabiA002015006.port.T = TC_467_1017.port_b.T; AIR0CabiA002015006.port.T = TC_821_1017.port_b.T; AIR0CabiA002015006.port.T = TsAIR0CabiA002015006.port.T; TsAIR0CabiA012014006.port.Q_flow + (TC_1015_1016.port_b.Q_flow + (TC_1005_1016.port_b.Q_flow + (TC_842_1016.port_b.Q_flow + (TC_463_1016.port_b.Q_flow + (AIR0CabiA012014006.port.Q_flow + (TC_1016_1027.port_a.Q_flow + TC_1016_1133.port_a.Q_flow)))))) = 0.0; AIR0CabiA012014006.port.T = TC_1005_1016.port_b.T; AIR0CabiA012014006.port.T = TC_1015_1016.port_b.T; AIR0CabiA012014006.port.T = TC_1016_1027.port_a.T; AIR0CabiA012014006.port.T = TC_1016_1133.port_a.T; AIR0CabiA012014006.port.T = TC_463_1016.port_b.T; AIR0CabiA012014006.port.T = TC_842_1016.port_b.T; AIR0CabiA012014006.port.T = TsAIR0CabiA012014006.port.T; TsAIR0CabiA011014006.port.Q_flow + (TC_1014_1015.port_b.Q_flow + (TC_1004_1015.port_b.Q_flow + (TC_841_1015.port_b.Q_flow + (AIR0CabiA011014006.port.Q_flow + (TC_1015_1016.port_a.Q_flow + (TC_1015_1026.port_a.Q_flow + TC_1015_1562.port_a.Q_flow)))))) = 0.0; AIR0CabiA011014006.port.T = TC_1004_1015.port_b.T; AIR0CabiA011014006.port.T = TC_1014_1015.port_b.T; AIR0CabiA011014006.port.T = TC_1015_1016.port_a.T; AIR0CabiA011014006.port.T = TC_1015_1026.port_a.T; AIR0CabiA011014006.port.T = TC_1015_1562.port_a.T; AIR0CabiA011014006.port.T = TC_841_1015.port_b.T; AIR0CabiA011014006.port.T = TsAIR0CabiA011014006.port.T; TsAIR0CabiA010014006.port.Q_flow + (TC_1013_1014.port_b.Q_flow + (TC_1003_1014.port_b.Q_flow + (TC_840_1014.port_b.Q_flow + (AIR0CabiA010014006.port.Q_flow + (TC_1014_1015.port_a.Q_flow + (TC_1014_1025.port_a.Q_flow + TC_1014_1561.port_a.Q_flow)))))) = 0.0; AIR0CabiA010014006.port.T = TC_1003_1014.port_b.T; AIR0CabiA010014006.port.T = TC_1013_1014.port_b.T; AIR0CabiA010014006.port.T = TC_1014_1015.port_a.T; AIR0CabiA010014006.port.T = TC_1014_1025.port_a.T; AIR0CabiA010014006.port.T = TC_1014_1561.port_a.T; AIR0CabiA010014006.port.T = TC_840_1014.port_b.T; AIR0CabiA010014006.port.T = TsAIR0CabiA010014006.port.T; TsAIR0CabiA009014006.port.Q_flow + (TC_1012_1013.port_b.Q_flow + (TC_1002_1013.port_b.Q_flow + (TC_839_1013.port_b.Q_flow + (AIR0CabiA009014006.port.Q_flow + (TC_1013_1014.port_a.Q_flow + (TC_1013_1024.port_a.Q_flow + TC_1013_1560.port_a.Q_flow)))))) = 0.0; AIR0CabiA009014006.port.T = TC_1002_1013.port_b.T; AIR0CabiA009014006.port.T = TC_1012_1013.port_b.T; AIR0CabiA009014006.port.T = TC_1013_1014.port_a.T; AIR0CabiA009014006.port.T = TC_1013_1024.port_a.T; AIR0CabiA009014006.port.T = TC_1013_1560.port_a.T; AIR0CabiA009014006.port.T = TC_839_1013.port_b.T; AIR0CabiA009014006.port.T = TsAIR0CabiA009014006.port.T; TsAIR0CabiA008014006.port.Q_flow + (TC_1011_1012.port_b.Q_flow + (TC_1001_1012.port_b.Q_flow + (TC_838_1012.port_b.Q_flow + (AIR0CabiA008014006.port.Q_flow + (TC_1012_1013.port_a.Q_flow + (TC_1012_1023.port_a.Q_flow + TC_1012_1559.port_a.Q_flow)))))) = 0.0; AIR0CabiA008014006.port.T = TC_1001_1012.port_b.T; AIR0CabiA008014006.port.T = TC_1011_1012.port_b.T; AIR0CabiA008014006.port.T = TC_1012_1013.port_a.T; AIR0CabiA008014006.port.T = TC_1012_1023.port_a.T; AIR0CabiA008014006.port.T = TC_1012_1559.port_a.T; AIR0CabiA008014006.port.T = TC_838_1012.port_b.T; AIR0CabiA008014006.port.T = TsAIR0CabiA008014006.port.T; TsAIR0CabiA007014006.port.Q_flow + (TC_1010_1011.port_b.Q_flow + (TC_1000_1011.port_b.Q_flow + (TC_837_1011.port_b.Q_flow + (AIR0CabiA007014006.port.Q_flow + (TC_1011_1012.port_a.Q_flow + (TC_1011_1022.port_a.Q_flow + TC_1011_1558.port_a.Q_flow)))))) = 0.0; AIR0CabiA007014006.port.T = TC_1000_1011.port_b.T; AIR0CabiA007014006.port.T = TC_1010_1011.port_b.T; AIR0CabiA007014006.port.T = TC_1011_1012.port_a.T; AIR0CabiA007014006.port.T = TC_1011_1022.port_a.T; AIR0CabiA007014006.port.T = TC_1011_1558.port_a.T; AIR0CabiA007014006.port.T = TC_837_1011.port_b.T; AIR0CabiA007014006.port.T = TsAIR0CabiA007014006.port.T; TsAIR0CabiA006014006.port.Q_flow + (TC_1009_1010.port_b.Q_flow + (TC_836_1010.port_b.Q_flow + (AIR0CabiA006014006.port.Q_flow + (TC_1010_1011.port_a.Q_flow + (TC_1010_1021.port_a.Q_flow + (TC_1010_1557.port_a.Q_flow + TC_1010_1664.port_a.Q_flow)))))) = 0.0; AIR0CabiA006014006.port.T = TC_1009_1010.port_b.T; AIR0CabiA006014006.port.T = TC_1010_1011.port_a.T; AIR0CabiA006014006.port.T = TC_1010_1021.port_a.T; AIR0CabiA006014006.port.T = TC_1010_1557.port_a.T; AIR0CabiA006014006.port.T = TC_1010_1664.port_a.T; AIR0CabiA006014006.port.T = TC_836_1010.port_b.T; AIR0CabiA006014006.port.T = TsAIR0CabiA006014006.port.T; TsAIR0CabiA005014006.port.Q_flow + (TC_1008_1009.port_b.Q_flow + (TC_835_1009.port_b.Q_flow + (AIR0CabiA005014006.port.Q_flow + (TC_1009_1010.port_a.Q_flow + (TC_1009_1020.port_a.Q_flow + (TC_1009_1556.port_a.Q_flow + TC_1009_1663.port_a.Q_flow)))))) = 0.0; AIR0CabiA005014006.port.T = TC_1008_1009.port_b.T; AIR0CabiA005014006.port.T = TC_1009_1010.port_a.T; AIR0CabiA005014006.port.T = TC_1009_1020.port_a.T; AIR0CabiA005014006.port.T = TC_1009_1556.port_a.T; AIR0CabiA005014006.port.T = TC_1009_1663.port_a.T; AIR0CabiA005014006.port.T = TC_835_1009.port_b.T; AIR0CabiA005014006.port.T = TsAIR0CabiA005014006.port.T; TsAIR0CabiA004014006.port.Q_flow + (TC_1007_1008.port_b.Q_flow + (TC_834_1008.port_b.Q_flow + (AIR0CabiA004014006.port.Q_flow + (TC_1008_1009.port_a.Q_flow + (TC_1008_1019.port_a.Q_flow + (TC_1008_1555.port_a.Q_flow + TC_1008_1662.port_a.Q_flow)))))) = 0.0; AIR0CabiA004014006.port.T = TC_1007_1008.port_b.T; AIR0CabiA004014006.port.T = TC_1008_1009.port_a.T; AIR0CabiA004014006.port.T = TC_1008_1019.port_a.T; AIR0CabiA004014006.port.T = TC_1008_1555.port_a.T; AIR0CabiA004014006.port.T = TC_1008_1662.port_a.T; AIR0CabiA004014006.port.T = TC_834_1008.port_b.T; AIR0CabiA004014006.port.T = TsAIR0CabiA004014006.port.T; TsAIR0CabiA003014006.port.Q_flow + (TC_1006_1007.port_b.Q_flow + (TC_999_1007.port_b.Q_flow + (TC_833_1007.port_b.Q_flow + (AIR0CabiA003014006.port.Q_flow + (TC_1007_1008.port_a.Q_flow + (TC_1007_1018.port_a.Q_flow + TC_1007_1554.port_a.Q_flow)))))) = 0.0; AIR0CabiA003014006.port.T = TC_1006_1007.port_b.T; AIR0CabiA003014006.port.T = TC_1007_1008.port_a.T; AIR0CabiA003014006.port.T = TC_1007_1018.port_a.T; AIR0CabiA003014006.port.T = TC_1007_1554.port_a.T; AIR0CabiA003014006.port.T = TC_833_1007.port_b.T; AIR0CabiA003014006.port.T = TC_999_1007.port_b.T; AIR0CabiA003014006.port.T = TsAIR0CabiA003014006.port.T; TsAIR0CabiA002014006.port.Q_flow + (TC_998_1006.port_b.Q_flow + (TC_832_1006.port_b.Q_flow + (TC_462_1006.port_b.Q_flow + (AIR0CabiA002014006.port.Q_flow + (TC_1006_1007.port_a.Q_flow + (TC_1006_1017.port_a.Q_flow + TC_1006_1132.port_a.Q_flow)))))) = 0.0; AIR0CabiA002014006.port.T = TC_1006_1007.port_a.T; AIR0CabiA002014006.port.T = TC_1006_1017.port_a.T; AIR0CabiA002014006.port.T = TC_1006_1132.port_a.T; AIR0CabiA002014006.port.T = TC_462_1006.port_b.T; AIR0CabiA002014006.port.T = TC_832_1006.port_b.T; AIR0CabiA002014006.port.T = TC_998_1006.port_b.T; AIR0CabiA002014006.port.T = TsAIR0CabiA002014006.port.T; TsAIR0CabiA012013006.port.Q_flow + (TC_1004_1005.port_b.Q_flow + (TC_997_1005.port_b.Q_flow + (TC_919_1005.port_b.Q_flow + (TC_461_1005.port_b.Q_flow + (AIR0CabiA012013006.port.Q_flow + (TC_1005_1016.port_a.Q_flow + TC_1005_1131.port_a.Q_flow)))))) = 0.0; AIR0CabiA012013006.port.T = TC_1004_1005.port_b.T; AIR0CabiA012013006.port.T = TC_1005_1016.port_a.T; AIR0CabiA012013006.port.T = TC_1005_1131.port_a.T; AIR0CabiA012013006.port.T = TC_461_1005.port_b.T; AIR0CabiA012013006.port.T = TC_919_1005.port_b.T; AIR0CabiA012013006.port.T = TC_997_1005.port_b.T; AIR0CabiA012013006.port.T = TsAIR0CabiA012013006.port.T; TsAIR0CabiA011013006.port.Q_flow + (TC_1003_1004.port_b.Q_flow + (TC_996_1004.port_b.Q_flow + (TC_918_1004.port_b.Q_flow + (AIR0CabiA011013006.port.Q_flow + (TC_1004_1005.port_a.Q_flow + (TC_1004_1015.port_a.Q_flow + TC_1004_1553.port_a.Q_flow)))))) = 0.0; AIR0CabiA011013006.port.T = TC_1003_1004.port_b.T; AIR0CabiA011013006.port.T = TC_1004_1005.port_a.T; AIR0CabiA011013006.port.T = TC_1004_1015.port_a.T; AIR0CabiA011013006.port.T = TC_1004_1553.port_a.T; AIR0CabiA011013006.port.T = TC_918_1004.port_b.T; AIR0CabiA011013006.port.T = TC_996_1004.port_b.T; AIR0CabiA011013006.port.T = TsAIR0CabiA011013006.port.T; TsAIR0CabiA010013006.port.Q_flow + (TC_1002_1003.port_b.Q_flow + (TC_995_1003.port_b.Q_flow + (TC_917_1003.port_b.Q_flow + (AIR0CabiA010013006.port.Q_flow + (TC_1003_1004.port_a.Q_flow + (TC_1003_1014.port_a.Q_flow + TC_1003_1552.port_a.Q_flow)))))) = 0.0; AIR0CabiA010013006.port.T = TC_1002_1003.port_b.T; AIR0CabiA010013006.port.T = TC_1003_1004.port_a.T; AIR0CabiA010013006.port.T = TC_1003_1014.port_a.T; AIR0CabiA010013006.port.T = TC_1003_1552.port_a.T; AIR0CabiA010013006.port.T = TC_917_1003.port_b.T; AIR0CabiA010013006.port.T = TC_995_1003.port_b.T; AIR0CabiA010013006.port.T = TsAIR0CabiA010013006.port.T; TsAIR0CabiA009013006.port.Q_flow + (TC_1001_1002.port_b.Q_flow + (TC_994_1002.port_b.Q_flow + (TC_916_1002.port_b.Q_flow + (AIR0CabiA009013006.port.Q_flow + (TC_1002_1003.port_a.Q_flow + (TC_1002_1013.port_a.Q_flow + TC_1002_1551.port_a.Q_flow)))))) = 0.0; AIR0CabiA009013006.port.T = TC_1001_1002.port_b.T; AIR0CabiA009013006.port.T = TC_1002_1003.port_a.T; AIR0CabiA009013006.port.T = TC_1002_1013.port_a.T; AIR0CabiA009013006.port.T = TC_1002_1551.port_a.T; AIR0CabiA009013006.port.T = TC_916_1002.port_b.T; AIR0CabiA009013006.port.T = TC_994_1002.port_b.T; AIR0CabiA009013006.port.T = TsAIR0CabiA009013006.port.T; TsAIR0CabiA008013006.port.Q_flow + (TC_1000_1001.port_b.Q_flow + (TC_993_1001.port_b.Q_flow + (TC_915_1001.port_b.Q_flow + (AIR0CabiA008013006.port.Q_flow + (TC_1001_1002.port_a.Q_flow + (TC_1001_1012.port_a.Q_flow + TC_1001_1550.port_a.Q_flow)))))) = 0.0; AIR0CabiA008013006.port.T = TC_1000_1001.port_b.T; AIR0CabiA008013006.port.T = TC_1001_1002.port_a.T; AIR0CabiA008013006.port.T = TC_1001_1012.port_a.T; AIR0CabiA008013006.port.T = TC_1001_1550.port_a.T; AIR0CabiA008013006.port.T = TC_915_1001.port_b.T; AIR0CabiA008013006.port.T = TC_993_1001.port_b.T; AIR0CabiA008013006.port.T = TsAIR0CabiA008013006.port.T; TsAIR0CabiA007013006.port.Q_flow + (TC_992_1000.port_b.Q_flow + (TC_914_1000.port_b.Q_flow + (AIR0CabiA007013006.port.Q_flow + (TC_1000_1001.port_a.Q_flow + (TC_1000_1011.port_a.Q_flow + (TC_1000_1549.port_a.Q_flow + TC_1000_1664.port_a.Q_flow)))))) = 0.0; AIR0CabiA007013006.port.T = TC_1000_1001.port_a.T; AIR0CabiA007013006.port.T = TC_1000_1011.port_a.T; AIR0CabiA007013006.port.T = TC_1000_1549.port_a.T; AIR0CabiA007013006.port.T = TC_1000_1664.port_a.T; AIR0CabiA007013006.port.T = TC_914_1000.port_b.T; AIR0CabiA007013006.port.T = TC_992_1000.port_b.T; AIR0CabiA007013006.port.T = TsAIR0CabiA007013006.port.T; TsAIR0CabiA003013006.port.Q_flow + (TC_998_999.port_b.Q_flow + (TC_991_999.port_b.Q_flow + (TC_910_999.port_b.Q_flow + (AIR0CabiA003013006.port.Q_flow + (TC_999_1007.port_a.Q_flow + (TC_999_1545.port_a.Q_flow + TC_999_1662.port_a.Q_flow)))))) = 0.0; AIR0CabiA003013006.port.T = TC_910_999.port_b.T; AIR0CabiA003013006.port.T = TC_991_999.port_b.T; AIR0CabiA003013006.port.T = TC_998_999.port_b.T; AIR0CabiA003013006.port.T = TC_999_1007.port_a.T; AIR0CabiA003013006.port.T = TC_999_1545.port_a.T; AIR0CabiA003013006.port.T = TC_999_1662.port_a.T; AIR0CabiA003013006.port.T = TsAIR0CabiA003013006.port.T; TsAIR0CabiA002013006.port.Q_flow + (TC_990_998.port_b.Q_flow + (TC_909_998.port_b.Q_flow + (TC_460_998.port_b.Q_flow + (AIR0CabiA002013006.port.Q_flow + (TC_998_999.port_a.Q_flow + (TC_998_1006.port_a.Q_flow + TC_998_1130.port_a.Q_flow)))))) = 0.0; AIR0CabiA002013006.port.T = TC_460_998.port_b.T; AIR0CabiA002013006.port.T = TC_909_998.port_b.T; AIR0CabiA002013006.port.T = TC_990_998.port_b.T; AIR0CabiA002013006.port.T = TC_998_1006.port_a.T; AIR0CabiA002013006.port.T = TC_998_1130.port_a.T; AIR0CabiA002013006.port.T = TC_998_999.port_a.T; AIR0CabiA002013006.port.T = TsAIR0CabiA002013006.port.T; TsAIR0CabiA012012006.port.Q_flow + (TC_996_997.port_b.Q_flow + (TC_989_997.port_b.Q_flow + (TC_908_997.port_b.Q_flow + (TC_459_997.port_b.Q_flow + (AIR0CabiA012012006.port.Q_flow + (TC_997_1005.port_a.Q_flow + TC_997_1129.port_a.Q_flow)))))) = 0.0; AIR0CabiA012012006.port.T = TC_459_997.port_b.T; AIR0CabiA012012006.port.T = TC_908_997.port_b.T; AIR0CabiA012012006.port.T = TC_989_997.port_b.T; AIR0CabiA012012006.port.T = TC_996_997.port_b.T; AIR0CabiA012012006.port.T = TC_997_1005.port_a.T; AIR0CabiA012012006.port.T = TC_997_1129.port_a.T; AIR0CabiA012012006.port.T = TsAIR0CabiA012012006.port.T; TsAIR0CabiA011012006.port.Q_flow + (TC_995_996.port_b.Q_flow + (TC_988_996.port_b.Q_flow + (TC_907_996.port_b.Q_flow + (AIR0CabiA011012006.port.Q_flow + (TC_996_997.port_a.Q_flow + (TC_996_1004.port_a.Q_flow + TC_996_1544.port_a.Q_flow)))))) = 0.0; AIR0CabiA011012006.port.T = TC_907_996.port_b.T; AIR0CabiA011012006.port.T = TC_988_996.port_b.T; AIR0CabiA011012006.port.T = TC_995_996.port_b.T; AIR0CabiA011012006.port.T = TC_996_1004.port_a.T; AIR0CabiA011012006.port.T = TC_996_1544.port_a.T; AIR0CabiA011012006.port.T = TC_996_997.port_a.T; AIR0CabiA011012006.port.T = TsAIR0CabiA011012006.port.T; TsAIR0CabiA010012006.port.Q_flow + (TC_994_995.port_b.Q_flow + (TC_906_995.port_b.Q_flow + (AIR0CabiA010012006.port.Q_flow + (TC_995_996.port_a.Q_flow + (TC_995_1003.port_a.Q_flow + (TC_995_1543.port_a.Q_flow + TC_995_1655.port_a.Q_flow)))))) = 0.0; AIR0CabiA010012006.port.T = TC_906_995.port_b.T; AIR0CabiA010012006.port.T = TC_994_995.port_b.T; AIR0CabiA010012006.port.T = TC_995_1003.port_a.T; AIR0CabiA010012006.port.T = TC_995_1543.port_a.T; AIR0CabiA010012006.port.T = TC_995_1655.port_a.T; AIR0CabiA010012006.port.T = TC_995_996.port_a.T; AIR0CabiA010012006.port.T = TsAIR0CabiA010012006.port.T; TsAIR0CabiA009012006.port.Q_flow + (TC_993_994.port_b.Q_flow + (TC_905_994.port_b.Q_flow + (AIR0CabiA009012006.port.Q_flow + (TC_994_995.port_a.Q_flow + (TC_994_1002.port_a.Q_flow + (TC_994_1542.port_a.Q_flow + TC_994_1654.port_a.Q_flow)))))) = 0.0; AIR0CabiA009012006.port.T = TC_905_994.port_b.T; AIR0CabiA009012006.port.T = TC_993_994.port_b.T; AIR0CabiA009012006.port.T = TC_994_1002.port_a.T; AIR0CabiA009012006.port.T = TC_994_1542.port_a.T; AIR0CabiA009012006.port.T = TC_994_1654.port_a.T; AIR0CabiA009012006.port.T = TC_994_995.port_a.T; AIR0CabiA009012006.port.T = TsAIR0CabiA009012006.port.T; TsAIR0CabiA008012006.port.Q_flow + (TC_992_993.port_b.Q_flow + (TC_904_993.port_b.Q_flow + (AIR0CabiA008012006.port.Q_flow + (TC_993_994.port_a.Q_flow + (TC_993_1001.port_a.Q_flow + (TC_993_1541.port_a.Q_flow + TC_993_1653.port_a.Q_flow)))))) = 0.0; AIR0CabiA008012006.port.T = TC_904_993.port_b.T; AIR0CabiA008012006.port.T = TC_992_993.port_b.T; AIR0CabiA008012006.port.T = TC_993_1001.port_a.T; AIR0CabiA008012006.port.T = TC_993_1541.port_a.T; AIR0CabiA008012006.port.T = TC_993_1653.port_a.T; AIR0CabiA008012006.port.T = TC_993_994.port_a.T; AIR0CabiA008012006.port.T = TsAIR0CabiA008012006.port.T; TsAIR0CabiA007012006.port.Q_flow + (TC_987_992.port_b.Q_flow + (TC_903_992.port_b.Q_flow + (AIR0CabiA007012006.port.Q_flow + (TC_992_993.port_a.Q_flow + (TC_992_1000.port_a.Q_flow + (TC_992_1540.port_a.Q_flow + TC_992_1661.port_a.Q_flow)))))) = 0.0; AIR0CabiA007012006.port.T = TC_903_992.port_b.T; AIR0CabiA007012006.port.T = TC_987_992.port_b.T; AIR0CabiA007012006.port.T = TC_992_1000.port_a.T; AIR0CabiA007012006.port.T = TC_992_1540.port_a.T; AIR0CabiA007012006.port.T = TC_992_1661.port_a.T; AIR0CabiA007012006.port.T = TC_992_993.port_a.T; AIR0CabiA007012006.port.T = TsAIR0CabiA007012006.port.T; TsAIR0CabiA003012006.port.Q_flow + (TC_990_991.port_b.Q_flow + (TC_986_991.port_b.Q_flow + (TC_899_991.port_b.Q_flow + (AIR0CabiA003012006.port.Q_flow + (TC_991_999.port_a.Q_flow + (TC_991_1536.port_a.Q_flow + TC_991_1659.port_a.Q_flow)))))) = 0.0; AIR0CabiA003012006.port.T = TC_899_991.port_b.T; AIR0CabiA003012006.port.T = TC_986_991.port_b.T; AIR0CabiA003012006.port.T = TC_990_991.port_b.T; AIR0CabiA003012006.port.T = TC_991_1536.port_a.T; AIR0CabiA003012006.port.T = TC_991_1659.port_a.T; AIR0CabiA003012006.port.T = TC_991_999.port_a.T; AIR0CabiA003012006.port.T = TsAIR0CabiA003012006.port.T; TsAIR0CabiA002012006.port.Q_flow + (TC_985_990.port_b.Q_flow + (TC_898_990.port_b.Q_flow + (TC_458_990.port_b.Q_flow + (AIR0CabiA002012006.port.Q_flow + (TC_990_991.port_a.Q_flow + (TC_990_998.port_a.Q_flow + TC_990_1128.port_a.Q_flow)))))) = 0.0; AIR0CabiA002012006.port.T = TC_458_990.port_b.T; AIR0CabiA002012006.port.T = TC_898_990.port_b.T; AIR0CabiA002012006.port.T = TC_985_990.port_b.T; AIR0CabiA002012006.port.T = TC_990_1128.port_a.T; AIR0CabiA002012006.port.T = TC_990_991.port_a.T; AIR0CabiA002012006.port.T = TC_990_998.port_a.T; AIR0CabiA002012006.port.T = TsAIR0CabiA002012006.port.T; TsAIR0CabiA012011006.port.Q_flow + (TC_988_989.port_b.Q_flow + (TC_984_989.port_b.Q_flow + (TC_897_989.port_b.Q_flow + (TC_457_989.port_b.Q_flow + (AIR0CabiA012011006.port.Q_flow + (TC_989_997.port_a.Q_flow + TC_989_1127.port_a.Q_flow)))))) = 0.0; AIR0CabiA012011006.port.T = TC_457_989.port_b.T; AIR0CabiA012011006.port.T = TC_897_989.port_b.T; AIR0CabiA012011006.port.T = TC_984_989.port_b.T; AIR0CabiA012011006.port.T = TC_988_989.port_b.T; AIR0CabiA012011006.port.T = TC_989_1127.port_a.T; AIR0CabiA012011006.port.T = TC_989_997.port_a.T; AIR0CabiA012011006.port.T = TsAIR0CabiA012011006.port.T; TsAIR0CabiA011011006.port.Q_flow + (TC_983_988.port_b.Q_flow + (TC_896_988.port_b.Q_flow + (AIR0CabiA011011006.port.Q_flow + (TC_988_989.port_a.Q_flow + (TC_988_996.port_a.Q_flow + (TC_988_1535.port_a.Q_flow + TC_988_1655.port_a.Q_flow)))))) = 0.0; AIR0CabiA011011006.port.T = TC_896_988.port_b.T; AIR0CabiA011011006.port.T = TC_983_988.port_b.T; AIR0CabiA011011006.port.T = TC_988_1535.port_a.T; AIR0CabiA011011006.port.T = TC_988_1655.port_a.T; AIR0CabiA011011006.port.T = TC_988_989.port_a.T; AIR0CabiA011011006.port.T = TC_988_996.port_a.T; AIR0CabiA011011006.port.T = TsAIR0CabiA011011006.port.T; TsAIR0CabiA007011006.port.Q_flow + (TC_982_987.port_b.Q_flow + (TC_892_987.port_b.Q_flow + (AIR0CabiA007011006.port.Q_flow + (TC_987_992.port_a.Q_flow + (TC_987_1531.port_a.Q_flow + (TC_987_1653.port_a.Q_flow + TC_987_1658.port_a.Q_flow)))))) = 0.0; AIR0CabiA007011006.port.T = TC_892_987.port_b.T; AIR0CabiA007011006.port.T = TC_982_987.port_b.T; AIR0CabiA007011006.port.T = TC_987_1531.port_a.T; AIR0CabiA007011006.port.T = TC_987_1653.port_a.T; AIR0CabiA007011006.port.T = TC_987_1658.port_a.T; AIR0CabiA007011006.port.T = TC_987_992.port_a.T; AIR0CabiA007011006.port.T = TsAIR0CabiA007011006.port.T; TsAIR0CabiA003011006.port.Q_flow + (TC_985_986.port_b.Q_flow + (TC_978_986.port_b.Q_flow + (TC_888_986.port_b.Q_flow + (AIR0CabiA003011006.port.Q_flow + (TC_986_991.port_a.Q_flow + (TC_986_1527.port_a.Q_flow + TC_986_1656.port_a.Q_flow)))))) = 0.0; AIR0CabiA003011006.port.T = TC_888_986.port_b.T; AIR0CabiA003011006.port.T = TC_978_986.port_b.T; AIR0CabiA003011006.port.T = TC_985_986.port_b.T; AIR0CabiA003011006.port.T = TC_986_1527.port_a.T; AIR0CabiA003011006.port.T = TC_986_1656.port_a.T; AIR0CabiA003011006.port.T = TC_986_991.port_a.T; AIR0CabiA003011006.port.T = TsAIR0CabiA003011006.port.T; TsAIR0CabiA002011006.port.Q_flow + (TC_977_985.port_b.Q_flow + (TC_887_985.port_b.Q_flow + (TC_456_985.port_b.Q_flow + (AIR0CabiA002011006.port.Q_flow + (TC_985_986.port_a.Q_flow + (TC_985_990.port_a.Q_flow + TC_985_1126.port_a.Q_flow)))))) = 0.0; AIR0CabiA002011006.port.T = TC_456_985.port_b.T; AIR0CabiA002011006.port.T = TC_887_985.port_b.T; AIR0CabiA002011006.port.T = TC_977_985.port_b.T; AIR0CabiA002011006.port.T = TC_985_1126.port_a.T; AIR0CabiA002011006.port.T = TC_985_986.port_a.T; AIR0CabiA002011006.port.T = TC_985_990.port_a.T; AIR0CabiA002011006.port.T = TsAIR0CabiA002011006.port.T; TsAIR0CabiA012010006.port.Q_flow + (TC_983_984.port_b.Q_flow + (TC_976_984.port_b.Q_flow + (TC_886_984.port_b.Q_flow + (TC_455_984.port_b.Q_flow + (AIR0CabiA012010006.port.Q_flow + (TC_984_989.port_a.Q_flow + TC_984_1125.port_a.Q_flow)))))) = 0.0; AIR0CabiA012010006.port.T = TC_455_984.port_b.T; AIR0CabiA012010006.port.T = TC_886_984.port_b.T; AIR0CabiA012010006.port.T = TC_976_984.port_b.T; AIR0CabiA012010006.port.T = TC_983_984.port_b.T; AIR0CabiA012010006.port.T = TC_984_1125.port_a.T; AIR0CabiA012010006.port.T = TC_984_989.port_a.T; AIR0CabiA012010006.port.T = TsAIR0CabiA012010006.port.T; TsAIR0CabiA011010006.port.Q_flow + (TC_975_983.port_b.Q_flow + (TC_885_983.port_b.Q_flow + (AIR0CabiA011010006.port.Q_flow + (TC_983_984.port_a.Q_flow + (TC_983_988.port_a.Q_flow + (TC_983_1607.port_a.Q_flow + TC_983_1652.port_a.Q_flow)))))) = 0.0; AIR0CabiA011010006.port.T = TC_885_983.port_b.T; AIR0CabiA011010006.port.T = TC_975_983.port_b.T; AIR0CabiA011010006.port.T = TC_983_1607.port_a.T; AIR0CabiA011010006.port.T = TC_983_1652.port_a.T; AIR0CabiA011010006.port.T = TC_983_984.port_a.T; AIR0CabiA011010006.port.T = TC_983_988.port_a.T; AIR0CabiA011010006.port.T = TsAIR0CabiA011010006.port.T; TsAIR0CabiA007010006.port.Q_flow + (TC_981_982.port_b.Q_flow + (TC_881_982.port_b.Q_flow + (AIR0CabiA007010006.port.Q_flow + (TC_982_987.port_a.Q_flow + (TC_982_1065.port_a.Q_flow + (TC_982_1603.port_a.Q_flow + TC_982_1650.port_a.Q_flow)))))) = 0.0; AIR0CabiA007010006.port.T = TC_881_982.port_b.T; AIR0CabiA007010006.port.T = TC_981_982.port_b.T; AIR0CabiA007010006.port.T = TC_982_1065.port_a.T; AIR0CabiA007010006.port.T = TC_982_1603.port_a.T; AIR0CabiA007010006.port.T = TC_982_1650.port_a.T; AIR0CabiA007010006.port.T = TC_982_987.port_a.T; AIR0CabiA007010006.port.T = TsAIR0CabiA007010006.port.T; TsAIR0CabiA006010006.port.Q_flow + (TC_980_981.port_b.Q_flow + (TC_880_981.port_b.Q_flow + (AIR0CabiA006010006.port.Q_flow + (TC_981_982.port_a.Q_flow + (TC_981_1064.port_a.Q_flow + (TC_981_1602.port_a.Q_flow + TC_981_1658.port_a.Q_flow)))))) = 0.0; AIR0CabiA006010006.port.T = TC_880_981.port_b.T; AIR0CabiA006010006.port.T = TC_980_981.port_b.T; AIR0CabiA006010006.port.T = TC_981_1064.port_a.T; AIR0CabiA006010006.port.T = TC_981_1602.port_a.T; AIR0CabiA006010006.port.T = TC_981_1658.port_a.T; AIR0CabiA006010006.port.T = TC_981_982.port_a.T; AIR0CabiA006010006.port.T = TsAIR0CabiA006010006.port.T; TsAIR0CabiA005010006.port.Q_flow + (TC_979_980.port_b.Q_flow + (TC_879_980.port_b.Q_flow + (AIR0CabiA005010006.port.Q_flow + (TC_980_981.port_a.Q_flow + (TC_980_1063.port_a.Q_flow + (TC_980_1601.port_a.Q_flow + TC_980_1657.port_a.Q_flow)))))) = 0.0; AIR0CabiA005010006.port.T = TC_879_980.port_b.T; AIR0CabiA005010006.port.T = TC_979_980.port_b.T; AIR0CabiA005010006.port.T = TC_980_1063.port_a.T; AIR0CabiA005010006.port.T = TC_980_1601.port_a.T; AIR0CabiA005010006.port.T = TC_980_1657.port_a.T; AIR0CabiA005010006.port.T = TC_980_981.port_a.T; AIR0CabiA005010006.port.T = TsAIR0CabiA005010006.port.T; TsAIR0CabiA004010006.port.Q_flow + (TC_978_979.port_b.Q_flow + (TC_878_979.port_b.Q_flow + (AIR0CabiA004010006.port.Q_flow + (TC_979_980.port_a.Q_flow + (TC_979_1062.port_a.Q_flow + (TC_979_1600.port_a.Q_flow + TC_979_1656.port_a.Q_flow)))))) = 0.0; AIR0CabiA004010006.port.T = TC_878_979.port_b.T; AIR0CabiA004010006.port.T = TC_978_979.port_b.T; AIR0CabiA004010006.port.T = TC_979_1062.port_a.T; AIR0CabiA004010006.port.T = TC_979_1600.port_a.T; AIR0CabiA004010006.port.T = TC_979_1656.port_a.T; AIR0CabiA004010006.port.T = TC_979_980.port_a.T; AIR0CabiA004010006.port.T = TsAIR0CabiA004010006.port.T; TsAIR0CabiA003010006.port.Q_flow + (TC_977_978.port_b.Q_flow + (TC_877_978.port_b.Q_flow + (AIR0CabiA003010006.port.Q_flow + (TC_978_979.port_a.Q_flow + (TC_978_986.port_a.Q_flow + (TC_978_1061.port_a.Q_flow + TC_978_1599.port_a.Q_flow)))))) = 0.0; AIR0CabiA003010006.port.T = TC_877_978.port_b.T; AIR0CabiA003010006.port.T = TC_977_978.port_b.T; AIR0CabiA003010006.port.T = TC_978_1061.port_a.T; AIR0CabiA003010006.port.T = TC_978_1599.port_a.T; AIR0CabiA003010006.port.T = TC_978_979.port_a.T; AIR0CabiA003010006.port.T = TC_978_986.port_a.T; AIR0CabiA003010006.port.T = TsAIR0CabiA003010006.port.T; TsAIR0CabiA002010006.port.Q_flow + (TC_876_977.port_b.Q_flow + (TC_454_977.port_b.Q_flow + (AIR0CabiA002010006.port.Q_flow + (TC_977_978.port_a.Q_flow + (TC_977_985.port_a.Q_flow + (TC_977_1060.port_a.Q_flow + TC_977_1124.port_a.Q_flow)))))) = 0.0; AIR0CabiA002010006.port.T = TC_454_977.port_b.T; AIR0CabiA002010006.port.T = TC_876_977.port_b.T; AIR0CabiA002010006.port.T = TC_977_1060.port_a.T; AIR0CabiA002010006.port.T = TC_977_1124.port_a.T; AIR0CabiA002010006.port.T = TC_977_978.port_a.T; AIR0CabiA002010006.port.T = TC_977_985.port_a.T; AIR0CabiA002010006.port.T = TsAIR0CabiA002010006.port.T; TsAIR0CabiA012009006.port.Q_flow + (TC_975_976.port_b.Q_flow + (TC_875_976.port_b.Q_flow + (TC_453_976.port_b.Q_flow + (AIR0CabiA012009006.port.Q_flow + (TC_976_984.port_a.Q_flow + (TC_976_1059.port_a.Q_flow + TC_976_1123.port_a.Q_flow)))))) = 0.0; AIR0CabiA012009006.port.T = TC_453_976.port_b.T; AIR0CabiA012009006.port.T = TC_875_976.port_b.T; AIR0CabiA012009006.port.T = TC_975_976.port_b.T; AIR0CabiA012009006.port.T = TC_976_1059.port_a.T; AIR0CabiA012009006.port.T = TC_976_1123.port_a.T; AIR0CabiA012009006.port.T = TC_976_984.port_a.T; AIR0CabiA012009006.port.T = TsAIR0CabiA012009006.port.T; TsAIR0CabiA011009006.port.Q_flow + (TC_874_975.port_b.Q_flow + (AIR0CabiA011009006.port.Q_flow + (TC_975_976.port_a.Q_flow + (TC_975_983.port_a.Q_flow + (TC_975_1058.port_a.Q_flow + (TC_975_1598.port_a.Q_flow + TC_975_1649.port_a.Q_flow)))))) = 0.0; AIR0CabiA011009006.port.T = TC_874_975.port_b.T; AIR0CabiA011009006.port.T = TC_975_1058.port_a.T; AIR0CabiA011009006.port.T = TC_975_1598.port_a.T; AIR0CabiA011009006.port.T = TC_975_1649.port_a.T; AIR0CabiA011009006.port.T = TC_975_976.port_a.T; AIR0CabiA011009006.port.T = TC_975_983.port_a.T; AIR0CabiA011009006.port.T = TsAIR0CabiA011009006.port.T; TsAIR0CabiA012006007.port.Q_flow + (TC_973_974.port_b.Q_flow + (TC_963_974.port_b.Q_flow + (TC_853_974.port_b.Q_flow + (TC_609_974.port_b.Q_flow + (TC_501_974.port_b.Q_flow + (AIR0CabiA012006007.port.Q_flow + TC_974_1037.port_a.Q_flow)))))) = 0.0; AIR0CabiA012006007.port.T = TC_501_974.port_b.T; AIR0CabiA012006007.port.T = TC_609_974.port_b.T; AIR0CabiA012006007.port.T = TC_853_974.port_b.T; AIR0CabiA012006007.port.T = TC_963_974.port_b.T; AIR0CabiA012006007.port.T = TC_973_974.port_b.T; AIR0CabiA012006007.port.T = TC_974_1037.port_a.T; AIR0CabiA012006007.port.T = TsAIR0CabiA012006007.port.T; TsAIR0CabiA011006007.port.Q_flow + (TC_972_973.port_b.Q_flow + (TC_962_973.port_b.Q_flow + (TC_852_973.port_b.Q_flow + (TC_608_973.port_b.Q_flow + (AIR0CabiA011006007.port.Q_flow + (TC_973_974.port_a.Q_flow + TC_973_1036.port_a.Q_flow)))))) = 0.0; AIR0CabiA011006007.port.T = TC_608_973.port_b.T; AIR0CabiA011006007.port.T = TC_852_973.port_b.T; AIR0CabiA011006007.port.T = TC_962_973.port_b.T; AIR0CabiA011006007.port.T = TC_972_973.port_b.T; AIR0CabiA011006007.port.T = TC_973_1036.port_a.T; AIR0CabiA011006007.port.T = TC_973_974.port_a.T; AIR0CabiA011006007.port.T = TsAIR0CabiA011006007.port.T; TsAIR0CabiA010006007.port.Q_flow + (TC_971_972.port_b.Q_flow + (TC_961_972.port_b.Q_flow + (TC_851_972.port_b.Q_flow + (TC_607_972.port_b.Q_flow + (AIR0CabiA010006007.port.Q_flow + (TC_972_973.port_a.Q_flow + TC_972_1035.port_a.Q_flow)))))) = 0.0; AIR0CabiA010006007.port.T = TC_607_972.port_b.T; AIR0CabiA010006007.port.T = TC_851_972.port_b.T; AIR0CabiA010006007.port.T = TC_961_972.port_b.T; AIR0CabiA010006007.port.T = TC_971_972.port_b.T; AIR0CabiA010006007.port.T = TC_972_1035.port_a.T; AIR0CabiA010006007.port.T = TC_972_973.port_a.T; AIR0CabiA010006007.port.T = TsAIR0CabiA010006007.port.T; TsAIR0CabiA009006007.port.Q_flow + (TC_970_971.port_b.Q_flow + (TC_960_971.port_b.Q_flow + (TC_850_971.port_b.Q_flow + (TC_606_971.port_b.Q_flow + (AIR0CabiA009006007.port.Q_flow + (TC_971_972.port_a.Q_flow + TC_971_1646.port_a.Q_flow)))))) = 0.0; AIR0CabiA009006007.port.T = TC_606_971.port_b.T; AIR0CabiA009006007.port.T = TC_850_971.port_b.T; AIR0CabiA009006007.port.T = TC_960_971.port_b.T; AIR0CabiA009006007.port.T = TC_970_971.port_b.T; AIR0CabiA009006007.port.T = TC_971_1646.port_a.T; AIR0CabiA009006007.port.T = TC_971_972.port_a.T; AIR0CabiA009006007.port.T = TsAIR0CabiA009006007.port.T; TsAIR0CabiA008006007.port.Q_flow + (TC_969_970.port_b.Q_flow + (TC_959_970.port_b.Q_flow + (TC_849_970.port_b.Q_flow + (TC_605_970.port_b.Q_flow + (AIR0CabiA008006007.port.Q_flow + (TC_970_971.port_a.Q_flow + TC_970_1645.port_a.Q_flow)))))) = 0.0; AIR0CabiA008006007.port.T = TC_605_970.port_b.T; AIR0CabiA008006007.port.T = TC_849_970.port_b.T; AIR0CabiA008006007.port.T = TC_959_970.port_b.T; AIR0CabiA008006007.port.T = TC_969_970.port_b.T; AIR0CabiA008006007.port.T = TC_970_1645.port_a.T; AIR0CabiA008006007.port.T = TC_970_971.port_a.T; AIR0CabiA008006007.port.T = TsAIR0CabiA008006007.port.T; TsAIR0CabiA007006007.port.Q_flow + (TC_968_969.port_b.Q_flow + (TC_958_969.port_b.Q_flow + (TC_848_969.port_b.Q_flow + (TC_604_969.port_b.Q_flow + (AIR0CabiA007006007.port.Q_flow + (TC_969_970.port_a.Q_flow + TC_969_1644.port_a.Q_flow)))))) = 0.0; AIR0CabiA007006007.port.T = TC_604_969.port_b.T; AIR0CabiA007006007.port.T = TC_848_969.port_b.T; AIR0CabiA007006007.port.T = TC_958_969.port_b.T; AIR0CabiA007006007.port.T = TC_968_969.port_b.T; AIR0CabiA007006007.port.T = TC_969_1644.port_a.T; AIR0CabiA007006007.port.T = TC_969_970.port_a.T; AIR0CabiA007006007.port.T = TsAIR0CabiA007006007.port.T; TsAIR0CabiA006006007.port.Q_flow + (TC_967_968.port_b.Q_flow + (TC_957_968.port_b.Q_flow + (TC_847_968.port_b.Q_flow + (TC_603_968.port_b.Q_flow + (AIR0CabiA006006007.port.Q_flow + (TC_968_969.port_a.Q_flow + TC_968_1643.port_a.Q_flow)))))) = 0.0; AIR0CabiA006006007.port.T = TC_603_968.port_b.T; AIR0CabiA006006007.port.T = TC_847_968.port_b.T; AIR0CabiA006006007.port.T = TC_957_968.port_b.T; AIR0CabiA006006007.port.T = TC_967_968.port_b.T; AIR0CabiA006006007.port.T = TC_968_1643.port_a.T; AIR0CabiA006006007.port.T = TC_968_969.port_a.T; AIR0CabiA006006007.port.T = TsAIR0CabiA006006007.port.T; TsAIR0CabiA005006007.port.Q_flow + (TC_966_967.port_b.Q_flow + (TC_956_967.port_b.Q_flow + (TC_846_967.port_b.Q_flow + (TC_602_967.port_b.Q_flow + (AIR0CabiA005006007.port.Q_flow + (TC_967_968.port_a.Q_flow + TC_967_1034.port_a.Q_flow)))))) = 0.0; AIR0CabiA005006007.port.T = TC_602_967.port_b.T; AIR0CabiA005006007.port.T = TC_846_967.port_b.T; AIR0CabiA005006007.port.T = TC_956_967.port_b.T; AIR0CabiA005006007.port.T = TC_966_967.port_b.T; AIR0CabiA005006007.port.T = TC_967_1034.port_a.T; AIR0CabiA005006007.port.T = TC_967_968.port_a.T; AIR0CabiA005006007.port.T = TsAIR0CabiA005006007.port.T; TsAIR0CabiA004006007.port.Q_flow + (TC_965_966.port_b.Q_flow + (TC_955_966.port_b.Q_flow + (TC_845_966.port_b.Q_flow + (TC_601_966.port_b.Q_flow + (AIR0CabiA004006007.port.Q_flow + (TC_966_967.port_a.Q_flow + TC_966_1033.port_a.Q_flow)))))) = 0.0; AIR0CabiA004006007.port.T = TC_601_966.port_b.T; AIR0CabiA004006007.port.T = TC_845_966.port_b.T; AIR0CabiA004006007.port.T = TC_955_966.port_b.T; AIR0CabiA004006007.port.T = TC_965_966.port_b.T; AIR0CabiA004006007.port.T = TC_966_1033.port_a.T; AIR0CabiA004006007.port.T = TC_966_967.port_a.T; AIR0CabiA004006007.port.T = TsAIR0CabiA004006007.port.T; TsAIR0CabiA003006007.port.Q_flow + (TC_964_965.port_b.Q_flow + (TC_954_965.port_b.Q_flow + (TC_844_965.port_b.Q_flow + (TC_600_965.port_b.Q_flow + (AIR0CabiA003006007.port.Q_flow + (TC_965_966.port_a.Q_flow + TC_965_1032.port_a.Q_flow)))))) = 0.0; AIR0CabiA003006007.port.T = TC_600_965.port_b.T; AIR0CabiA003006007.port.T = TC_844_965.port_b.T; AIR0CabiA003006007.port.T = TC_954_965.port_b.T; AIR0CabiA003006007.port.T = TC_964_965.port_b.T; AIR0CabiA003006007.port.T = TC_965_1032.port_a.T; AIR0CabiA003006007.port.T = TC_965_966.port_a.T; AIR0CabiA003006007.port.T = TsAIR0CabiA003006007.port.T; TsAIR0CabiA002006007.port.Q_flow + (TC_953_964.port_b.Q_flow + (TC_843_964.port_b.Q_flow + (TC_599_964.port_b.Q_flow + (TC_500_964.port_b.Q_flow + (AIR0CabiA002006007.port.Q_flow + (TC_964_965.port_a.Q_flow + TC_964_1031.port_a.Q_flow)))))) = 0.0; AIR0CabiA002006007.port.T = TC_500_964.port_b.T; AIR0CabiA002006007.port.T = TC_599_964.port_b.T; AIR0CabiA002006007.port.T = TC_843_964.port_b.T; AIR0CabiA002006007.port.T = TC_953_964.port_b.T; AIR0CabiA002006007.port.T = TC_964_1031.port_a.T; AIR0CabiA002006007.port.T = TC_964_965.port_a.T; AIR0CabiA002006007.port.T = TsAIR0CabiA002006007.port.T; TsAIR0CabiA012005007.port.Q_flow + (TC_962_963.port_b.Q_flow + (TC_952_963.port_b.Q_flow + (TC_596_963.port_b.Q_flow + (TC_499_963.port_b.Q_flow + (AIR0CabiA012005007.port.Q_flow + (TC_963_974.port_a.Q_flow + TC_963_1030.port_a.Q_flow)))))) = 0.0; AIR0CabiA012005007.port.T = TC_499_963.port_b.T; AIR0CabiA012005007.port.T = TC_596_963.port_b.T; AIR0CabiA012005007.port.T = TC_952_963.port_b.T; AIR0CabiA012005007.port.T = TC_962_963.port_b.T; AIR0CabiA012005007.port.T = TC_963_1030.port_a.T; AIR0CabiA012005007.port.T = TC_963_974.port_a.T; AIR0CabiA012005007.port.T = TsAIR0CabiA012005007.port.T; TsAIR0CabiA011005007.port.Q_flow + (TC_961_962.port_b.Q_flow + (TC_951_962.port_b.Q_flow + (TC_595_962.port_b.Q_flow + (AIR0CabiA011005007.port.Q_flow + (TC_962_963.port_a.Q_flow + (TC_962_973.port_a.Q_flow + TC_962_1029.port_a.Q_flow)))))) = 0.0; AIR0CabiA011005007.port.T = TC_595_962.port_b.T; AIR0CabiA011005007.port.T = TC_951_962.port_b.T; AIR0CabiA011005007.port.T = TC_961_962.port_b.T; AIR0CabiA011005007.port.T = TC_962_1029.port_a.T; AIR0CabiA011005007.port.T = TC_962_963.port_a.T; AIR0CabiA011005007.port.T = TC_962_973.port_a.T; AIR0CabiA011005007.port.T = TsAIR0CabiA011005007.port.T; TsAIR0CabiA010005007.port.Q_flow + (TC_960_961.port_b.Q_flow + (TC_950_961.port_b.Q_flow + (TC_594_961.port_b.Q_flow + (AIR0CabiA010005007.port.Q_flow + (TC_961_962.port_a.Q_flow + (TC_961_972.port_a.Q_flow + TC_961_1028.port_a.Q_flow)))))) = 0.0; AIR0CabiA010005007.port.T = TC_594_961.port_b.T; AIR0CabiA010005007.port.T = TC_950_961.port_b.T; AIR0CabiA010005007.port.T = TC_960_961.port_b.T; AIR0CabiA010005007.port.T = TC_961_1028.port_a.T; AIR0CabiA010005007.port.T = TC_961_962.port_a.T; AIR0CabiA010005007.port.T = TC_961_972.port_a.T; AIR0CabiA010005007.port.T = TsAIR0CabiA010005007.port.T; TsAIR0CabiA009005007.port.Q_flow + (TC_959_960.port_b.Q_flow + (TC_949_960.port_b.Q_flow + (TC_593_960.port_b.Q_flow + (AIR0CabiA009005007.port.Q_flow + (TC_960_961.port_a.Q_flow + (TC_960_971.port_a.Q_flow + TC_960_1642.port_a.Q_flow)))))) = 0.0; AIR0CabiA009005007.port.T = TC_593_960.port_b.T; AIR0CabiA009005007.port.T = TC_949_960.port_b.T; AIR0CabiA009005007.port.T = TC_959_960.port_b.T; AIR0CabiA009005007.port.T = TC_960_1642.port_a.T; AIR0CabiA009005007.port.T = TC_960_961.port_a.T; AIR0CabiA009005007.port.T = TC_960_971.port_a.T; AIR0CabiA009005007.port.T = TsAIR0CabiA009005007.port.T; TsAIR0CabiA008005007.port.Q_flow + (TC_958_959.port_b.Q_flow + (TC_948_959.port_b.Q_flow + (TC_592_959.port_b.Q_flow + (AIR0CabiA008005007.port.Q_flow + (TC_959_960.port_a.Q_flow + (TC_959_970.port_a.Q_flow + TC_959_1641.port_a.Q_flow)))))) = 0.0; AIR0CabiA008005007.port.T = TC_592_959.port_b.T; AIR0CabiA008005007.port.T = TC_948_959.port_b.T; AIR0CabiA008005007.port.T = TC_958_959.port_b.T; AIR0CabiA008005007.port.T = TC_959_1641.port_a.T; AIR0CabiA008005007.port.T = TC_959_960.port_a.T; AIR0CabiA008005007.port.T = TC_959_970.port_a.T; AIR0CabiA008005007.port.T = TsAIR0CabiA008005007.port.T; TsAIR0CabiA007005007.port.Q_flow + (TC_957_958.port_b.Q_flow + (TC_947_958.port_b.Q_flow + (TC_591_958.port_b.Q_flow + (AIR0CabiA007005007.port.Q_flow + (TC_958_959.port_a.Q_flow + (TC_958_969.port_a.Q_flow + TC_958_1640.port_a.Q_flow)))))) = 0.0; AIR0CabiA007005007.port.T = TC_591_958.port_b.T; AIR0CabiA007005007.port.T = TC_947_958.port_b.T; AIR0CabiA007005007.port.T = TC_957_958.port_b.T; AIR0CabiA007005007.port.T = TC_958_1640.port_a.T; AIR0CabiA007005007.port.T = TC_958_959.port_a.T; AIR0CabiA007005007.port.T = TC_958_969.port_a.T; AIR0CabiA007005007.port.T = TsAIR0CabiA007005007.port.T; TsAIR0CabiA006005007.port.Q_flow + (TC_956_957.port_b.Q_flow + (TC_946_957.port_b.Q_flow + (TC_590_957.port_b.Q_flow + (AIR0CabiA006005007.port.Q_flow + (TC_957_958.port_a.Q_flow + (TC_957_968.port_a.Q_flow + TC_957_1639.port_a.Q_flow)))))) = 0.0; AIR0CabiA006005007.port.T = TC_590_957.port_b.T; AIR0CabiA006005007.port.T = TC_946_957.port_b.T; AIR0CabiA006005007.port.T = TC_956_957.port_b.T; AIR0CabiA006005007.port.T = TC_957_1639.port_a.T; AIR0CabiA006005007.port.T = TC_957_958.port_a.T; AIR0CabiA006005007.port.T = TC_957_968.port_a.T; AIR0CabiA006005007.port.T = TsAIR0CabiA006005007.port.T; TsAIR0CabiA005005007.port.Q_flow + (TC_955_956.port_b.Q_flow + (TC_945_956.port_b.Q_flow + (TC_589_956.port_b.Q_flow + (AIR0CabiA005005007.port.Q_flow + (TC_956_957.port_a.Q_flow + (TC_956_967.port_a.Q_flow + TC_956_1098.port_a.Q_flow)))))) = 0.0; AIR0CabiA005005007.port.T = TC_589_956.port_b.T; AIR0CabiA005005007.port.T = TC_945_956.port_b.T; AIR0CabiA005005007.port.T = TC_955_956.port_b.T; AIR0CabiA005005007.port.T = TC_956_1098.port_a.T; AIR0CabiA005005007.port.T = TC_956_957.port_a.T; AIR0CabiA005005007.port.T = TC_956_967.port_a.T; AIR0CabiA005005007.port.T = TsAIR0CabiA005005007.port.T; TsAIR0CabiA004005007.port.Q_flow + (TC_954_955.port_b.Q_flow + (TC_944_955.port_b.Q_flow + (TC_588_955.port_b.Q_flow + (AIR0CabiA004005007.port.Q_flow + (TC_955_956.port_a.Q_flow + (TC_955_966.port_a.Q_flow + TC_955_1097.port_a.Q_flow)))))) = 0.0; AIR0CabiA004005007.port.T = TC_588_955.port_b.T; AIR0CabiA004005007.port.T = TC_944_955.port_b.T; AIR0CabiA004005007.port.T = TC_954_955.port_b.T; AIR0CabiA004005007.port.T = TC_955_1097.port_a.T; AIR0CabiA004005007.port.T = TC_955_956.port_a.T; AIR0CabiA004005007.port.T = TC_955_966.port_a.T; AIR0CabiA004005007.port.T = TsAIR0CabiA004005007.port.T; TsAIR0CabiA003005007.port.Q_flow + (TC_953_954.port_b.Q_flow + (TC_943_954.port_b.Q_flow + (TC_587_954.port_b.Q_flow + (AIR0CabiA003005007.port.Q_flow + (TC_954_955.port_a.Q_flow + (TC_954_965.port_a.Q_flow + TC_954_1096.port_a.Q_flow)))))) = 0.0; AIR0CabiA003005007.port.T = TC_587_954.port_b.T; AIR0CabiA003005007.port.T = TC_943_954.port_b.T; AIR0CabiA003005007.port.T = TC_953_954.port_b.T; AIR0CabiA003005007.port.T = TC_954_1096.port_a.T; AIR0CabiA003005007.port.T = TC_954_955.port_a.T; AIR0CabiA003005007.port.T = TC_954_965.port_a.T; AIR0CabiA003005007.port.T = TsAIR0CabiA003005007.port.T; TsAIR0CabiA002005007.port.Q_flow + (TC_942_953.port_b.Q_flow + (TC_586_953.port_b.Q_flow + (TC_498_953.port_b.Q_flow + (AIR0CabiA002005007.port.Q_flow + (TC_953_954.port_a.Q_flow + (TC_953_964.port_a.Q_flow + TC_953_1095.port_a.Q_flow)))))) = 0.0; AIR0CabiA002005007.port.T = TC_498_953.port_b.T; AIR0CabiA002005007.port.T = TC_586_953.port_b.T; AIR0CabiA002005007.port.T = TC_942_953.port_b.T; AIR0CabiA002005007.port.T = TC_953_1095.port_a.T; AIR0CabiA002005007.port.T = TC_953_954.port_a.T; AIR0CabiA002005007.port.T = TC_953_964.port_a.T; AIR0CabiA002005007.port.T = TsAIR0CabiA002005007.port.T; TsAIR0CabiA012004007.port.Q_flow + (TC_951_952.port_b.Q_flow + (TC_941_952.port_b.Q_flow + (TC_583_952.port_b.Q_flow + (TC_497_952.port_b.Q_flow + (AIR0CabiA012004007.port.Q_flow + (TC_952_963.port_a.Q_flow + TC_952_1094.port_a.Q_flow)))))) = 0.0; AIR0CabiA012004007.port.T = TC_497_952.port_b.T; AIR0CabiA012004007.port.T = TC_583_952.port_b.T; AIR0CabiA012004007.port.T = TC_941_952.port_b.T; AIR0CabiA012004007.port.T = TC_951_952.port_b.T; AIR0CabiA012004007.port.T = TC_952_1094.port_a.T; AIR0CabiA012004007.port.T = TC_952_963.port_a.T; AIR0CabiA012004007.port.T = TsAIR0CabiA012004007.port.T; TsAIR0CabiA011004007.port.Q_flow + (TC_950_951.port_b.Q_flow + (TC_940_951.port_b.Q_flow + (TC_582_951.port_b.Q_flow + (AIR0CabiA011004007.port.Q_flow + (TC_951_952.port_a.Q_flow + (TC_951_962.port_a.Q_flow + TC_951_1093.port_a.Q_flow)))))) = 0.0; AIR0CabiA011004007.port.T = TC_582_951.port_b.T; AIR0CabiA011004007.port.T = TC_940_951.port_b.T; AIR0CabiA011004007.port.T = TC_950_951.port_b.T; AIR0CabiA011004007.port.T = TC_951_1093.port_a.T; AIR0CabiA011004007.port.T = TC_951_952.port_a.T; AIR0CabiA011004007.port.T = TC_951_962.port_a.T; AIR0CabiA011004007.port.T = TsAIR0CabiA011004007.port.T; TsAIR0CabiA010004007.port.Q_flow + (TC_949_950.port_b.Q_flow + (TC_939_950.port_b.Q_flow + (TC_581_950.port_b.Q_flow + (AIR0CabiA010004007.port.Q_flow + (TC_950_951.port_a.Q_flow + (TC_950_961.port_a.Q_flow + TC_950_1092.port_a.Q_flow)))))) = 0.0; AIR0CabiA010004007.port.T = TC_581_950.port_b.T; AIR0CabiA010004007.port.T = TC_939_950.port_b.T; AIR0CabiA010004007.port.T = TC_949_950.port_b.T; AIR0CabiA010004007.port.T = TC_950_1092.port_a.T; AIR0CabiA010004007.port.T = TC_950_951.port_a.T; AIR0CabiA010004007.port.T = TC_950_961.port_a.T; AIR0CabiA010004007.port.T = TsAIR0CabiA010004007.port.T; TsAIR0CabiA009004007.port.Q_flow + (TC_948_949.port_b.Q_flow + (TC_938_949.port_b.Q_flow + (TC_580_949.port_b.Q_flow + (AIR0CabiA009004007.port.Q_flow + (TC_949_950.port_a.Q_flow + (TC_949_960.port_a.Q_flow + TC_949_1638.port_a.Q_flow)))))) = 0.0; AIR0CabiA009004007.port.T = TC_580_949.port_b.T; AIR0CabiA009004007.port.T = TC_938_949.port_b.T; AIR0CabiA009004007.port.T = TC_948_949.port_b.T; AIR0CabiA009004007.port.T = TC_949_1638.port_a.T; AIR0CabiA009004007.port.T = TC_949_950.port_a.T; AIR0CabiA009004007.port.T = TC_949_960.port_a.T; AIR0CabiA009004007.port.T = TsAIR0CabiA009004007.port.T; TsAIR0CabiA008004007.port.Q_flow + (TC_947_948.port_b.Q_flow + (TC_937_948.port_b.Q_flow + (TC_579_948.port_b.Q_flow + (AIR0CabiA008004007.port.Q_flow + (TC_948_949.port_a.Q_flow + (TC_948_959.port_a.Q_flow + TC_948_1637.port_a.Q_flow)))))) = 0.0; AIR0CabiA008004007.port.T = TC_579_948.port_b.T; AIR0CabiA008004007.port.T = TC_937_948.port_b.T; AIR0CabiA008004007.port.T = TC_947_948.port_b.T; AIR0CabiA008004007.port.T = TC_948_1637.port_a.T; AIR0CabiA008004007.port.T = TC_948_949.port_a.T; AIR0CabiA008004007.port.T = TC_948_959.port_a.T; AIR0CabiA008004007.port.T = TsAIR0CabiA008004007.port.T; TsAIR0CabiA007004007.port.Q_flow + (TC_946_947.port_b.Q_flow + (TC_936_947.port_b.Q_flow + (TC_578_947.port_b.Q_flow + (AIR0CabiA007004007.port.Q_flow + (TC_947_948.port_a.Q_flow + (TC_947_958.port_a.Q_flow + TC_947_1636.port_a.Q_flow)))))) = 0.0; AIR0CabiA007004007.port.T = TC_578_947.port_b.T; AIR0CabiA007004007.port.T = TC_936_947.port_b.T; AIR0CabiA007004007.port.T = TC_946_947.port_b.T; AIR0CabiA007004007.port.T = TC_947_1636.port_a.T; AIR0CabiA007004007.port.T = TC_947_948.port_a.T; AIR0CabiA007004007.port.T = TC_947_958.port_a.T; AIR0CabiA007004007.port.T = TsAIR0CabiA007004007.port.T; TsAIR0CabiA006004007.port.Q_flow + (TC_945_946.port_b.Q_flow + (TC_935_946.port_b.Q_flow + (TC_577_946.port_b.Q_flow + (AIR0CabiA006004007.port.Q_flow + (TC_946_947.port_a.Q_flow + (TC_946_957.port_a.Q_flow + TC_946_1635.port_a.Q_flow)))))) = 0.0; AIR0CabiA006004007.port.T = TC_577_946.port_b.T; AIR0CabiA006004007.port.T = TC_935_946.port_b.T; AIR0CabiA006004007.port.T = TC_945_946.port_b.T; AIR0CabiA006004007.port.T = TC_946_1635.port_a.T; AIR0CabiA006004007.port.T = TC_946_947.port_a.T; AIR0CabiA006004007.port.T = TC_946_957.port_a.T; AIR0CabiA006004007.port.T = TsAIR0CabiA006004007.port.T; TsAIR0CabiA005004007.port.Q_flow + (TC_944_945.port_b.Q_flow + (TC_934_945.port_b.Q_flow + (TC_576_945.port_b.Q_flow + (AIR0CabiA005004007.port.Q_flow + (TC_945_946.port_a.Q_flow + (TC_945_956.port_a.Q_flow + TC_945_1091.port_a.Q_flow)))))) = 0.0; AIR0CabiA005004007.port.T = TC_576_945.port_b.T; AIR0CabiA005004007.port.T = TC_934_945.port_b.T; AIR0CabiA005004007.port.T = TC_944_945.port_b.T; AIR0CabiA005004007.port.T = TC_945_1091.port_a.T; AIR0CabiA005004007.port.T = TC_945_946.port_a.T; AIR0CabiA005004007.port.T = TC_945_956.port_a.T; AIR0CabiA005004007.port.T = TsAIR0CabiA005004007.port.T; TsAIR0CabiA004004007.port.Q_flow + (TC_943_944.port_b.Q_flow + (TC_933_944.port_b.Q_flow + (TC_575_944.port_b.Q_flow + (AIR0CabiA004004007.port.Q_flow + (TC_944_945.port_a.Q_flow + (TC_944_955.port_a.Q_flow + TC_944_1090.port_a.Q_flow)))))) = 0.0; AIR0CabiA004004007.port.T = TC_575_944.port_b.T; AIR0CabiA004004007.port.T = TC_933_944.port_b.T; AIR0CabiA004004007.port.T = TC_943_944.port_b.T; AIR0CabiA004004007.port.T = TC_944_1090.port_a.T; AIR0CabiA004004007.port.T = TC_944_945.port_a.T; AIR0CabiA004004007.port.T = TC_944_955.port_a.T; AIR0CabiA004004007.port.T = TsAIR0CabiA004004007.port.T; TsAIR0CabiA003004007.port.Q_flow + (TC_942_943.port_b.Q_flow + (TC_932_943.port_b.Q_flow + (TC_574_943.port_b.Q_flow + (AIR0CabiA003004007.port.Q_flow + (TC_943_944.port_a.Q_flow + (TC_943_954.port_a.Q_flow + TC_943_1089.port_a.Q_flow)))))) = 0.0; AIR0CabiA003004007.port.T = TC_574_943.port_b.T; AIR0CabiA003004007.port.T = TC_932_943.port_b.T; AIR0CabiA003004007.port.T = TC_942_943.port_b.T; AIR0CabiA003004007.port.T = TC_943_1089.port_a.T; AIR0CabiA003004007.port.T = TC_943_944.port_a.T; AIR0CabiA003004007.port.T = TC_943_954.port_a.T; AIR0CabiA003004007.port.T = TsAIR0CabiA003004007.port.T; TsAIR0CabiA002004007.port.Q_flow + (TC_931_942.port_b.Q_flow + (TC_573_942.port_b.Q_flow + (TC_496_942.port_b.Q_flow + (AIR0CabiA002004007.port.Q_flow + (TC_942_943.port_a.Q_flow + (TC_942_953.port_a.Q_flow + TC_942_1088.port_a.Q_flow)))))) = 0.0; AIR0CabiA002004007.port.T = TC_496_942.port_b.T; AIR0CabiA002004007.port.T = TC_573_942.port_b.T; AIR0CabiA002004007.port.T = TC_931_942.port_b.T; AIR0CabiA002004007.port.T = TC_942_1088.port_a.T; AIR0CabiA002004007.port.T = TC_942_943.port_a.T; AIR0CabiA002004007.port.T = TC_942_953.port_a.T; AIR0CabiA002004007.port.T = TsAIR0CabiA002004007.port.T; TsAIR0CabiA012003007.port.Q_flow + (TC_940_941.port_b.Q_flow + (TC_930_941.port_b.Q_flow + (TC_570_941.port_b.Q_flow + (TC_495_941.port_b.Q_flow + (AIR0CabiA012003007.port.Q_flow + (TC_941_952.port_a.Q_flow + TC_941_1087.port_a.Q_flow)))))) = 0.0; AIR0CabiA012003007.port.T = TC_495_941.port_b.T; AIR0CabiA012003007.port.T = TC_570_941.port_b.T; AIR0CabiA012003007.port.T = TC_930_941.port_b.T; AIR0CabiA012003007.port.T = TC_940_941.port_b.T; AIR0CabiA012003007.port.T = TC_941_1087.port_a.T; AIR0CabiA012003007.port.T = TC_941_952.port_a.T; AIR0CabiA012003007.port.T = TsAIR0CabiA012003007.port.T; TsAIR0CabiA011003007.port.Q_flow + (TC_939_940.port_b.Q_flow + (TC_929_940.port_b.Q_flow + (TC_569_940.port_b.Q_flow + (AIR0CabiA011003007.port.Q_flow + (TC_940_941.port_a.Q_flow + (TC_940_951.port_a.Q_flow + TC_940_1086.port_a.Q_flow)))))) = 0.0; AIR0CabiA011003007.port.T = TC_569_940.port_b.T; AIR0CabiA011003007.port.T = TC_929_940.port_b.T; AIR0CabiA011003007.port.T = TC_939_940.port_b.T; AIR0CabiA011003007.port.T = TC_940_1086.port_a.T; AIR0CabiA011003007.port.T = TC_940_941.port_a.T; AIR0CabiA011003007.port.T = TC_940_951.port_a.T; AIR0CabiA011003007.port.T = TsAIR0CabiA011003007.port.T; TsAIR0CabiA010003007.port.Q_flow + (TC_938_939.port_b.Q_flow + (TC_928_939.port_b.Q_flow + (TC_568_939.port_b.Q_flow + (AIR0CabiA010003007.port.Q_flow + (TC_939_940.port_a.Q_flow + (TC_939_950.port_a.Q_flow + TC_939_1085.port_a.Q_flow)))))) = 0.0; AIR0CabiA010003007.port.T = TC_568_939.port_b.T; AIR0CabiA010003007.port.T = TC_928_939.port_b.T; AIR0CabiA010003007.port.T = TC_938_939.port_b.T; AIR0CabiA010003007.port.T = TC_939_1085.port_a.T; AIR0CabiA010003007.port.T = TC_939_940.port_a.T; AIR0CabiA010003007.port.T = TC_939_950.port_a.T; AIR0CabiA010003007.port.T = TsAIR0CabiA010003007.port.T; TsAIR0CabiA009003007.port.Q_flow + (TC_937_938.port_b.Q_flow + (TC_927_938.port_b.Q_flow + (TC_567_938.port_b.Q_flow + (AIR0CabiA009003007.port.Q_flow + (TC_938_939.port_a.Q_flow + (TC_938_949.port_a.Q_flow + TC_938_1084.port_a.Q_flow)))))) = 0.0; AIR0CabiA009003007.port.T = TC_567_938.port_b.T; AIR0CabiA009003007.port.T = TC_927_938.port_b.T; AIR0CabiA009003007.port.T = TC_937_938.port_b.T; AIR0CabiA009003007.port.T = TC_938_1084.port_a.T; AIR0CabiA009003007.port.T = TC_938_939.port_a.T; AIR0CabiA009003007.port.T = TC_938_949.port_a.T; AIR0CabiA009003007.port.T = TsAIR0CabiA009003007.port.T; TsAIR0CabiA008003007.port.Q_flow + (TC_936_937.port_b.Q_flow + (TC_926_937.port_b.Q_flow + (TC_566_937.port_b.Q_flow + (AIR0CabiA008003007.port.Q_flow + (TC_937_938.port_a.Q_flow + (TC_937_948.port_a.Q_flow + TC_937_1083.port_a.Q_flow)))))) = 0.0; AIR0CabiA008003007.port.T = TC_566_937.port_b.T; AIR0CabiA008003007.port.T = TC_926_937.port_b.T; AIR0CabiA008003007.port.T = TC_936_937.port_b.T; AIR0CabiA008003007.port.T = TC_937_1083.port_a.T; AIR0CabiA008003007.port.T = TC_937_938.port_a.T; AIR0CabiA008003007.port.T = TC_937_948.port_a.T; AIR0CabiA008003007.port.T = TsAIR0CabiA008003007.port.T; TsAIR0CabiA007003007.port.Q_flow + (TC_935_936.port_b.Q_flow + (TC_925_936.port_b.Q_flow + (TC_565_936.port_b.Q_flow + (AIR0CabiA007003007.port.Q_flow + (TC_936_937.port_a.Q_flow + (TC_936_947.port_a.Q_flow + TC_936_1082.port_a.Q_flow)))))) = 0.0; AIR0CabiA007003007.port.T = TC_565_936.port_b.T; AIR0CabiA007003007.port.T = TC_925_936.port_b.T; AIR0CabiA007003007.port.T = TC_935_936.port_b.T; AIR0CabiA007003007.port.T = TC_936_1082.port_a.T; AIR0CabiA007003007.port.T = TC_936_937.port_a.T; AIR0CabiA007003007.port.T = TC_936_947.port_a.T; AIR0CabiA007003007.port.T = TsAIR0CabiA007003007.port.T; TsAIR0CabiA006003007.port.Q_flow + (TC_934_935.port_b.Q_flow + (TC_924_935.port_b.Q_flow + (TC_564_935.port_b.Q_flow + (AIR0CabiA006003007.port.Q_flow + (TC_935_936.port_a.Q_flow + (TC_935_946.port_a.Q_flow + TC_935_1081.port_a.Q_flow)))))) = 0.0; AIR0CabiA006003007.port.T = TC_564_935.port_b.T; AIR0CabiA006003007.port.T = TC_924_935.port_b.T; AIR0CabiA006003007.port.T = TC_934_935.port_b.T; AIR0CabiA006003007.port.T = TC_935_1081.port_a.T; AIR0CabiA006003007.port.T = TC_935_936.port_a.T; AIR0CabiA006003007.port.T = TC_935_946.port_a.T; AIR0CabiA006003007.port.T = TsAIR0CabiA006003007.port.T; TsAIR0CabiA005003007.port.Q_flow + (TC_933_934.port_b.Q_flow + (TC_923_934.port_b.Q_flow + (TC_563_934.port_b.Q_flow + (AIR0CabiA005003007.port.Q_flow + (TC_934_935.port_a.Q_flow + (TC_934_945.port_a.Q_flow + TC_934_1080.port_a.Q_flow)))))) = 0.0; AIR0CabiA005003007.port.T = TC_563_934.port_b.T; AIR0CabiA005003007.port.T = TC_923_934.port_b.T; AIR0CabiA005003007.port.T = TC_933_934.port_b.T; AIR0CabiA005003007.port.T = TC_934_1080.port_a.T; AIR0CabiA005003007.port.T = TC_934_935.port_a.T; AIR0CabiA005003007.port.T = TC_934_945.port_a.T; AIR0CabiA005003007.port.T = TsAIR0CabiA005003007.port.T; TsAIR0CabiA004003007.port.Q_flow + (TC_932_933.port_b.Q_flow + (TC_922_933.port_b.Q_flow + (TC_562_933.port_b.Q_flow + (AIR0CabiA004003007.port.Q_flow + (TC_933_934.port_a.Q_flow + (TC_933_944.port_a.Q_flow + TC_933_1079.port_a.Q_flow)))))) = 0.0; AIR0CabiA004003007.port.T = TC_562_933.port_b.T; AIR0CabiA004003007.port.T = TC_922_933.port_b.T; AIR0CabiA004003007.port.T = TC_932_933.port_b.T; AIR0CabiA004003007.port.T = TC_933_1079.port_a.T; AIR0CabiA004003007.port.T = TC_933_934.port_a.T; AIR0CabiA004003007.port.T = TC_933_944.port_a.T; AIR0CabiA004003007.port.T = TsAIR0CabiA004003007.port.T; TsAIR0CabiA003003007.port.Q_flow + (TC_931_932.port_b.Q_flow + (TC_921_932.port_b.Q_flow + (TC_561_932.port_b.Q_flow + (AIR0CabiA003003007.port.Q_flow + (TC_932_933.port_a.Q_flow + (TC_932_943.port_a.Q_flow + TC_932_1078.port_a.Q_flow)))))) = 0.0; AIR0CabiA003003007.port.T = TC_561_932.port_b.T; AIR0CabiA003003007.port.T = TC_921_932.port_b.T; AIR0CabiA003003007.port.T = TC_931_932.port_b.T; AIR0CabiA003003007.port.T = TC_932_1078.port_a.T; AIR0CabiA003003007.port.T = TC_932_933.port_a.T; AIR0CabiA003003007.port.T = TC_932_943.port_a.T; AIR0CabiA003003007.port.T = TsAIR0CabiA003003007.port.T; TsAIR0CabiA002003007.port.Q_flow + (TC_920_931.port_b.Q_flow + (TC_560_931.port_b.Q_flow + (TC_494_931.port_b.Q_flow + (AIR0CabiA002003007.port.Q_flow + (TC_931_932.port_a.Q_flow + (TC_931_942.port_a.Q_flow + TC_931_1077.port_a.Q_flow)))))) = 0.0; AIR0CabiA002003007.port.T = TC_494_931.port_b.T; AIR0CabiA002003007.port.T = TC_560_931.port_b.T; AIR0CabiA002003007.port.T = TC_920_931.port_b.T; AIR0CabiA002003007.port.T = TC_931_1077.port_a.T; AIR0CabiA002003007.port.T = TC_931_932.port_a.T; AIR0CabiA002003007.port.T = TC_931_942.port_a.T; AIR0CabiA002003007.port.T = TsAIR0CabiA002003007.port.T; TsAIR0CabiA012002007.port.Q_flow + (TC_929_930.port_b.Q_flow + (TC_557_930.port_b.Q_flow + (TC_493_930.port_b.Q_flow + (TC_490_930.port_b.Q_flow + (AIR0CabiA012002007.port.Q_flow + (TC_930_941.port_a.Q_flow + TC_930_1076.port_a.Q_flow)))))) = 0.0; AIR0CabiA012002007.port.T = TC_490_930.port_b.T; AIR0CabiA012002007.port.T = TC_493_930.port_b.T; AIR0CabiA012002007.port.T = TC_557_930.port_b.T; AIR0CabiA012002007.port.T = TC_929_930.port_b.T; AIR0CabiA012002007.port.T = TC_930_1076.port_a.T; AIR0CabiA012002007.port.T = TC_930_941.port_a.T; AIR0CabiA012002007.port.T = TsAIR0CabiA012002007.port.T; TsAIR0CabiA011002007.port.Q_flow + (TC_928_929.port_b.Q_flow + (TC_556_929.port_b.Q_flow + (TC_489_929.port_b.Q_flow + (AIR0CabiA011002007.port.Q_flow + (TC_929_930.port_a.Q_flow + (TC_929_940.port_a.Q_flow + TC_929_1075.port_a.Q_flow)))))) = 0.0; AIR0CabiA011002007.port.T = TC_489_929.port_b.T; AIR0CabiA011002007.port.T = TC_556_929.port_b.T; AIR0CabiA011002007.port.T = TC_928_929.port_b.T; AIR0CabiA011002007.port.T = TC_929_1075.port_a.T; AIR0CabiA011002007.port.T = TC_929_930.port_a.T; AIR0CabiA011002007.port.T = TC_929_940.port_a.T; AIR0CabiA011002007.port.T = TsAIR0CabiA011002007.port.T; TsAIR0CabiA010002007.port.Q_flow + (TC_927_928.port_b.Q_flow + (TC_555_928.port_b.Q_flow + (TC_488_928.port_b.Q_flow + (AIR0CabiA010002007.port.Q_flow + (TC_928_929.port_a.Q_flow + (TC_928_939.port_a.Q_flow + TC_928_1074.port_a.Q_flow)))))) = 0.0; AIR0CabiA010002007.port.T = TC_488_928.port_b.T; AIR0CabiA010002007.port.T = TC_555_928.port_b.T; AIR0CabiA010002007.port.T = TC_927_928.port_b.T; AIR0CabiA010002007.port.T = TC_928_1074.port_a.T; AIR0CabiA010002007.port.T = TC_928_929.port_a.T; AIR0CabiA010002007.port.T = TC_928_939.port_a.T; AIR0CabiA010002007.port.T = TsAIR0CabiA010002007.port.T; TsAIR0CabiA009002007.port.Q_flow + (TC_926_927.port_b.Q_flow + (TC_554_927.port_b.Q_flow + (TC_487_927.port_b.Q_flow + (AIR0CabiA009002007.port.Q_flow + (TC_927_928.port_a.Q_flow + (TC_927_938.port_a.Q_flow + TC_927_1073.port_a.Q_flow)))))) = 0.0; AIR0CabiA009002007.port.T = TC_487_927.port_b.T; AIR0CabiA009002007.port.T = TC_554_927.port_b.T; AIR0CabiA009002007.port.T = TC_926_927.port_b.T; AIR0CabiA009002007.port.T = TC_927_1073.port_a.T; AIR0CabiA009002007.port.T = TC_927_928.port_a.T; AIR0CabiA009002007.port.T = TC_927_938.port_a.T; AIR0CabiA009002007.port.T = TsAIR0CabiA009002007.port.T; TsAIR0CabiA008002007.port.Q_flow + (TC_925_926.port_b.Q_flow + (TC_553_926.port_b.Q_flow + (TC_486_926.port_b.Q_flow + (AIR0CabiA008002007.port.Q_flow + (TC_926_927.port_a.Q_flow + (TC_926_937.port_a.Q_flow + TC_926_1072.port_a.Q_flow)))))) = 0.0; AIR0CabiA008002007.port.T = TC_486_926.port_b.T; AIR0CabiA008002007.port.T = TC_553_926.port_b.T; AIR0CabiA008002007.port.T = TC_925_926.port_b.T; AIR0CabiA008002007.port.T = TC_926_1072.port_a.T; AIR0CabiA008002007.port.T = TC_926_927.port_a.T; AIR0CabiA008002007.port.T = TC_926_937.port_a.T; AIR0CabiA008002007.port.T = TsAIR0CabiA008002007.port.T; TsAIR0CabiA007002007.port.Q_flow + (TC_924_925.port_b.Q_flow + (TC_552_925.port_b.Q_flow + (TC_485_925.port_b.Q_flow + (AIR0CabiA007002007.port.Q_flow + (TC_925_926.port_a.Q_flow + (TC_925_936.port_a.Q_flow + TC_925_1071.port_a.Q_flow)))))) = 0.0; AIR0CabiA007002007.port.T = TC_485_925.port_b.T; AIR0CabiA007002007.port.T = TC_552_925.port_b.T; AIR0CabiA007002007.port.T = TC_924_925.port_b.T; AIR0CabiA007002007.port.T = TC_925_1071.port_a.T; AIR0CabiA007002007.port.T = TC_925_926.port_a.T; AIR0CabiA007002007.port.T = TC_925_936.port_a.T; AIR0CabiA007002007.port.T = TsAIR0CabiA007002007.port.T; TsAIR0CabiA006002007.port.Q_flow + (TC_923_924.port_b.Q_flow + (TC_551_924.port_b.Q_flow + (TC_484_924.port_b.Q_flow + (AIR0CabiA006002007.port.Q_flow + (TC_924_925.port_a.Q_flow + (TC_924_935.port_a.Q_flow + TC_924_1070.port_a.Q_flow)))))) = 0.0; AIR0CabiA006002007.port.T = TC_484_924.port_b.T; AIR0CabiA006002007.port.T = TC_551_924.port_b.T; AIR0CabiA006002007.port.T = TC_923_924.port_b.T; AIR0CabiA006002007.port.T = TC_924_1070.port_a.T; AIR0CabiA006002007.port.T = TC_924_925.port_a.T; AIR0CabiA006002007.port.T = TC_924_935.port_a.T; AIR0CabiA006002007.port.T = TsAIR0CabiA006002007.port.T; TsAIR0CabiA005002007.port.Q_flow + (TC_922_923.port_b.Q_flow + (TC_550_923.port_b.Q_flow + (TC_483_923.port_b.Q_flow + (AIR0CabiA005002007.port.Q_flow + (TC_923_924.port_a.Q_flow + (TC_923_934.port_a.Q_flow + TC_923_1069.port_a.Q_flow)))))) = 0.0; AIR0CabiA005002007.port.T = TC_483_923.port_b.T; AIR0CabiA005002007.port.T = TC_550_923.port_b.T; AIR0CabiA005002007.port.T = TC_922_923.port_b.T; AIR0CabiA005002007.port.T = TC_923_1069.port_a.T; AIR0CabiA005002007.port.T = TC_923_924.port_a.T; AIR0CabiA005002007.port.T = TC_923_934.port_a.T; AIR0CabiA005002007.port.T = TsAIR0CabiA005002007.port.T; TsAIR0CabiA004002007.port.Q_flow + (TC_921_922.port_b.Q_flow + (TC_549_922.port_b.Q_flow + (TC_482_922.port_b.Q_flow + (AIR0CabiA004002007.port.Q_flow + (TC_922_923.port_a.Q_flow + (TC_922_933.port_a.Q_flow + TC_922_1068.port_a.Q_flow)))))) = 0.0; AIR0CabiA004002007.port.T = TC_482_922.port_b.T; AIR0CabiA004002007.port.T = TC_549_922.port_b.T; AIR0CabiA004002007.port.T = TC_921_922.port_b.T; AIR0CabiA004002007.port.T = TC_922_1068.port_a.T; AIR0CabiA004002007.port.T = TC_922_923.port_a.T; AIR0CabiA004002007.port.T = TC_922_933.port_a.T; AIR0CabiA004002007.port.T = TsAIR0CabiA004002007.port.T; TsAIR0CabiA003002007.port.Q_flow + (TC_920_921.port_b.Q_flow + (TC_548_921.port_b.Q_flow + (TC_481_921.port_b.Q_flow + (AIR0CabiA003002007.port.Q_flow + (TC_921_922.port_a.Q_flow + (TC_921_932.port_a.Q_flow + TC_921_1067.port_a.Q_flow)))))) = 0.0; AIR0CabiA003002007.port.T = TC_481_921.port_b.T; AIR0CabiA003002007.port.T = TC_548_921.port_b.T; AIR0CabiA003002007.port.T = TC_920_921.port_b.T; AIR0CabiA003002007.port.T = TC_921_1067.port_a.T; AIR0CabiA003002007.port.T = TC_921_922.port_a.T; AIR0CabiA003002007.port.T = TC_921_932.port_a.T; AIR0CabiA003002007.port.T = TsAIR0CabiA003002007.port.T; TsAIR0CabiA002002007.port.Q_flow + (TC_547_920.port_b.Q_flow + (TC_492_920.port_b.Q_flow + (TC_480_920.port_b.Q_flow + (AIR0CabiA002002007.port.Q_flow + (TC_920_921.port_a.Q_flow + (TC_920_931.port_a.Q_flow + TC_920_1066.port_a.Q_flow)))))) = 0.0; AIR0CabiA002002007.port.T = TC_480_920.port_b.T; AIR0CabiA002002007.port.T = TC_492_920.port_b.T; AIR0CabiA002002007.port.T = TC_547_920.port_b.T; AIR0CabiA002002007.port.T = TC_920_1066.port_a.T; AIR0CabiA002002007.port.T = TC_920_921.port_a.T; AIR0CabiA002002007.port.T = TC_920_931.port_a.T; AIR0CabiA002002007.port.T = TsAIR0CabiA002002007.port.T; TsAIR0CabiA012013007.port.Q_flow + (TC_918_919.port_b.Q_flow + (TC_908_919.port_b.Q_flow + (TC_842_919.port_b.Q_flow + (TC_700_919.port_b.Q_flow + (TC_515_919.port_b.Q_flow + (AIR0CabiA012013007.port.Q_flow + TC_919_1005.port_a.Q_flow)))))) = 0.0; AIR0CabiA012013007.port.T = TC_515_919.port_b.T; AIR0CabiA012013007.port.T = TC_700_919.port_b.T; AIR0CabiA012013007.port.T = TC_842_919.port_b.T; AIR0CabiA012013007.port.T = TC_908_919.port_b.T; AIR0CabiA012013007.port.T = TC_918_919.port_b.T; AIR0CabiA012013007.port.T = TC_919_1005.port_a.T; AIR0CabiA012013007.port.T = TsAIR0CabiA012013007.port.T; TsAIR0CabiA011013007.port.Q_flow + (TC_917_918.port_b.Q_flow + (TC_907_918.port_b.Q_flow + (TC_841_918.port_b.Q_flow + (TC_699_918.port_b.Q_flow + (AIR0CabiA011013007.port.Q_flow + (TC_918_919.port_a.Q_flow + TC_918_1004.port_a.Q_flow)))))) = 0.0; AIR0CabiA011013007.port.T = TC_699_918.port_b.T; AIR0CabiA011013007.port.T = TC_841_918.port_b.T; AIR0CabiA011013007.port.T = TC_907_918.port_b.T; AIR0CabiA011013007.port.T = TC_917_918.port_b.T; AIR0CabiA011013007.port.T = TC_918_1004.port_a.T; AIR0CabiA011013007.port.T = TC_918_919.port_a.T; AIR0CabiA011013007.port.T = TsAIR0CabiA011013007.port.T; TsAIR0CabiA010013007.port.Q_flow + (TC_916_917.port_b.Q_flow + (TC_906_917.port_b.Q_flow + (TC_840_917.port_b.Q_flow + (TC_698_917.port_b.Q_flow + (AIR0CabiA010013007.port.Q_flow + (TC_917_918.port_a.Q_flow + TC_917_1003.port_a.Q_flow)))))) = 0.0; AIR0CabiA010013007.port.T = TC_698_917.port_b.T; AIR0CabiA010013007.port.T = TC_840_917.port_b.T; AIR0CabiA010013007.port.T = TC_906_917.port_b.T; AIR0CabiA010013007.port.T = TC_916_917.port_b.T; AIR0CabiA010013007.port.T = TC_917_1003.port_a.T; AIR0CabiA010013007.port.T = TC_917_918.port_a.T; AIR0CabiA010013007.port.T = TsAIR0CabiA010013007.port.T; TsAIR0CabiA009013007.port.Q_flow + (TC_915_916.port_b.Q_flow + (TC_905_916.port_b.Q_flow + (TC_839_916.port_b.Q_flow + (TC_697_916.port_b.Q_flow + (AIR0CabiA009013007.port.Q_flow + (TC_916_917.port_a.Q_flow + TC_916_1002.port_a.Q_flow)))))) = 0.0; AIR0CabiA009013007.port.T = TC_697_916.port_b.T; AIR0CabiA009013007.port.T = TC_839_916.port_b.T; AIR0CabiA009013007.port.T = TC_905_916.port_b.T; AIR0CabiA009013007.port.T = TC_915_916.port_b.T; AIR0CabiA009013007.port.T = TC_916_1002.port_a.T; AIR0CabiA009013007.port.T = TC_916_917.port_a.T; AIR0CabiA009013007.port.T = TsAIR0CabiA009013007.port.T; TsAIR0CabiA008013007.port.Q_flow + (TC_914_915.port_b.Q_flow + (TC_904_915.port_b.Q_flow + (TC_838_915.port_b.Q_flow + (TC_696_915.port_b.Q_flow + (AIR0CabiA008013007.port.Q_flow + (TC_915_916.port_a.Q_flow + TC_915_1001.port_a.Q_flow)))))) = 0.0; AIR0CabiA008013007.port.T = TC_696_915.port_b.T; AIR0CabiA008013007.port.T = TC_838_915.port_b.T; AIR0CabiA008013007.port.T = TC_904_915.port_b.T; AIR0CabiA008013007.port.T = TC_914_915.port_b.T; AIR0CabiA008013007.port.T = TC_915_1001.port_a.T; AIR0CabiA008013007.port.T = TC_915_916.port_a.T; AIR0CabiA008013007.port.T = TsAIR0CabiA008013007.port.T; TsAIR0CabiA007013007.port.Q_flow + (TC_913_914.port_b.Q_flow + (TC_903_914.port_b.Q_flow + (TC_837_914.port_b.Q_flow + (TC_695_914.port_b.Q_flow + (AIR0CabiA007013007.port.Q_flow + (TC_914_915.port_a.Q_flow + TC_914_1000.port_a.Q_flow)))))) = 0.0; AIR0CabiA007013007.port.T = TC_695_914.port_b.T; AIR0CabiA007013007.port.T = TC_837_914.port_b.T; AIR0CabiA007013007.port.T = TC_903_914.port_b.T; AIR0CabiA007013007.port.T = TC_913_914.port_b.T; AIR0CabiA007013007.port.T = TC_914_1000.port_a.T; AIR0CabiA007013007.port.T = TC_914_915.port_a.T; AIR0CabiA007013007.port.T = TsAIR0CabiA007013007.port.T; TsAIR0CabiA006013007.port.Q_flow + (TC_912_913.port_b.Q_flow + (TC_902_913.port_b.Q_flow + (TC_836_913.port_b.Q_flow + (TC_694_913.port_b.Q_flow + (AIR0CabiA006013007.port.Q_flow + (TC_913_914.port_a.Q_flow + TC_913_1664.port_a.Q_flow)))))) = 0.0; AIR0CabiA006013007.port.T = TC_694_913.port_b.T; AIR0CabiA006013007.port.T = TC_836_913.port_b.T; AIR0CabiA006013007.port.T = TC_902_913.port_b.T; AIR0CabiA006013007.port.T = TC_912_913.port_b.T; AIR0CabiA006013007.port.T = TC_913_1664.port_a.T; AIR0CabiA006013007.port.T = TC_913_914.port_a.T; AIR0CabiA006013007.port.T = TsAIR0CabiA006013007.port.T; TsAIR0CabiA005013007.port.Q_flow + (TC_911_912.port_b.Q_flow + (TC_901_912.port_b.Q_flow + (TC_835_912.port_b.Q_flow + (TC_693_912.port_b.Q_flow + (AIR0CabiA005013007.port.Q_flow + (TC_912_913.port_a.Q_flow + TC_912_1663.port_a.Q_flow)))))) = 0.0; AIR0CabiA005013007.port.T = TC_693_912.port_b.T; AIR0CabiA005013007.port.T = TC_835_912.port_b.T; AIR0CabiA005013007.port.T = TC_901_912.port_b.T; AIR0CabiA005013007.port.T = TC_911_912.port_b.T; AIR0CabiA005013007.port.T = TC_912_1663.port_a.T; AIR0CabiA005013007.port.T = TC_912_913.port_a.T; AIR0CabiA005013007.port.T = TsAIR0CabiA005013007.port.T; TsAIR0CabiA004013007.port.Q_flow + (TC_910_911.port_b.Q_flow + (TC_900_911.port_b.Q_flow + (TC_834_911.port_b.Q_flow + (TC_692_911.port_b.Q_flow + (AIR0CabiA004013007.port.Q_flow + (TC_911_912.port_a.Q_flow + TC_911_1662.port_a.Q_flow)))))) = 0.0; AIR0CabiA004013007.port.T = TC_692_911.port_b.T; AIR0CabiA004013007.port.T = TC_834_911.port_b.T; AIR0CabiA004013007.port.T = TC_900_911.port_b.T; AIR0CabiA004013007.port.T = TC_910_911.port_b.T; AIR0CabiA004013007.port.T = TC_911_1662.port_a.T; AIR0CabiA004013007.port.T = TC_911_912.port_a.T; AIR0CabiA004013007.port.T = TsAIR0CabiA004013007.port.T; TsAIR0CabiA003013007.port.Q_flow + (TC_909_910.port_b.Q_flow + (TC_899_910.port_b.Q_flow + (TC_833_910.port_b.Q_flow + (TC_691_910.port_b.Q_flow + (AIR0CabiA003013007.port.Q_flow + (TC_910_911.port_a.Q_flow + TC_910_999.port_a.Q_flow)))))) = 0.0; AIR0CabiA003013007.port.T = TC_691_910.port_b.T; AIR0CabiA003013007.port.T = TC_833_910.port_b.T; AIR0CabiA003013007.port.T = TC_899_910.port_b.T; AIR0CabiA003013007.port.T = TC_909_910.port_b.T; AIR0CabiA003013007.port.T = TC_910_911.port_a.T; AIR0CabiA003013007.port.T = TC_910_999.port_a.T; AIR0CabiA003013007.port.T = TsAIR0CabiA003013007.port.T; TsAIR0CabiA002013007.port.Q_flow + (TC_898_909.port_b.Q_flow + (TC_832_909.port_b.Q_flow + (TC_690_909.port_b.Q_flow + (TC_514_909.port_b.Q_flow + (AIR0CabiA002013007.port.Q_flow + (TC_909_910.port_a.Q_flow + TC_909_998.port_a.Q_flow)))))) = 0.0; AIR0CabiA002013007.port.T = TC_514_909.port_b.T; AIR0CabiA002013007.port.T = TC_690_909.port_b.T; AIR0CabiA002013007.port.T = TC_832_909.port_b.T; AIR0CabiA002013007.port.T = TC_898_909.port_b.T; AIR0CabiA002013007.port.T = TC_909_910.port_a.T; AIR0CabiA002013007.port.T = TC_909_998.port_a.T; AIR0CabiA002013007.port.T = TsAIR0CabiA002013007.port.T; TsAIR0CabiA012012007.port.Q_flow + (TC_907_908.port_b.Q_flow + (TC_897_908.port_b.Q_flow + (TC_687_908.port_b.Q_flow + (TC_513_908.port_b.Q_flow + (AIR0CabiA012012007.port.Q_flow + (TC_908_919.port_a.Q_flow + TC_908_997.port_a.Q_flow)))))) = 0.0; AIR0CabiA012012007.port.T = TC_513_908.port_b.T; AIR0CabiA012012007.port.T = TC_687_908.port_b.T; AIR0CabiA012012007.port.T = TC_897_908.port_b.T; AIR0CabiA012012007.port.T = TC_907_908.port_b.T; AIR0CabiA012012007.port.T = TC_908_919.port_a.T; AIR0CabiA012012007.port.T = TC_908_997.port_a.T; AIR0CabiA012012007.port.T = TsAIR0CabiA012012007.port.T; TsAIR0CabiA011012007.port.Q_flow + (TC_906_907.port_b.Q_flow + (TC_896_907.port_b.Q_flow + (TC_686_907.port_b.Q_flow + (AIR0CabiA011012007.port.Q_flow + (TC_907_908.port_a.Q_flow + (TC_907_918.port_a.Q_flow + TC_907_996.port_a.Q_flow)))))) = 0.0; AIR0CabiA011012007.port.T = TC_686_907.port_b.T; AIR0CabiA011012007.port.T = TC_896_907.port_b.T; AIR0CabiA011012007.port.T = TC_906_907.port_b.T; AIR0CabiA011012007.port.T = TC_907_908.port_a.T; AIR0CabiA011012007.port.T = TC_907_918.port_a.T; AIR0CabiA011012007.port.T = TC_907_996.port_a.T; AIR0CabiA011012007.port.T = TsAIR0CabiA011012007.port.T; TsAIR0CabiA010012007.port.Q_flow + (TC_905_906.port_b.Q_flow + (TC_895_906.port_b.Q_flow + (TC_685_906.port_b.Q_flow + (AIR0CabiA010012007.port.Q_flow + (TC_906_907.port_a.Q_flow + (TC_906_917.port_a.Q_flow + TC_906_995.port_a.Q_flow)))))) = 0.0; AIR0CabiA010012007.port.T = TC_685_906.port_b.T; AIR0CabiA010012007.port.T = TC_895_906.port_b.T; AIR0CabiA010012007.port.T = TC_905_906.port_b.T; AIR0CabiA010012007.port.T = TC_906_907.port_a.T; AIR0CabiA010012007.port.T = TC_906_917.port_a.T; AIR0CabiA010012007.port.T = TC_906_995.port_a.T; AIR0CabiA010012007.port.T = TsAIR0CabiA010012007.port.T; TsAIR0CabiA009012007.port.Q_flow + (TC_904_905.port_b.Q_flow + (TC_894_905.port_b.Q_flow + (TC_684_905.port_b.Q_flow + (AIR0CabiA009012007.port.Q_flow + (TC_905_906.port_a.Q_flow + (TC_905_916.port_a.Q_flow + TC_905_994.port_a.Q_flow)))))) = 0.0; AIR0CabiA009012007.port.T = TC_684_905.port_b.T; AIR0CabiA009012007.port.T = TC_894_905.port_b.T; AIR0CabiA009012007.port.T = TC_904_905.port_b.T; AIR0CabiA009012007.port.T = TC_905_906.port_a.T; AIR0CabiA009012007.port.T = TC_905_916.port_a.T; AIR0CabiA009012007.port.T = TC_905_994.port_a.T; AIR0CabiA009012007.port.T = TsAIR0CabiA009012007.port.T; TsAIR0CabiA008012007.port.Q_flow + (TC_903_904.port_b.Q_flow + (TC_893_904.port_b.Q_flow + (TC_683_904.port_b.Q_flow + (AIR0CabiA008012007.port.Q_flow + (TC_904_905.port_a.Q_flow + (TC_904_915.port_a.Q_flow + TC_904_993.port_a.Q_flow)))))) = 0.0; AIR0CabiA008012007.port.T = TC_683_904.port_b.T; AIR0CabiA008012007.port.T = TC_893_904.port_b.T; AIR0CabiA008012007.port.T = TC_903_904.port_b.T; AIR0CabiA008012007.port.T = TC_904_905.port_a.T; AIR0CabiA008012007.port.T = TC_904_915.port_a.T; AIR0CabiA008012007.port.T = TC_904_993.port_a.T; AIR0CabiA008012007.port.T = TsAIR0CabiA008012007.port.T; TsAIR0CabiA007012007.port.Q_flow + (TC_902_903.port_b.Q_flow + (TC_892_903.port_b.Q_flow + (TC_682_903.port_b.Q_flow + (AIR0CabiA007012007.port.Q_flow + (TC_903_904.port_a.Q_flow + (TC_903_914.port_a.Q_flow + TC_903_992.port_a.Q_flow)))))) = 0.0; AIR0CabiA007012007.port.T = TC_682_903.port_b.T; AIR0CabiA007012007.port.T = TC_892_903.port_b.T; AIR0CabiA007012007.port.T = TC_902_903.port_b.T; AIR0CabiA007012007.port.T = TC_903_904.port_a.T; AIR0CabiA007012007.port.T = TC_903_914.port_a.T; AIR0CabiA007012007.port.T = TC_903_992.port_a.T; AIR0CabiA007012007.port.T = TsAIR0CabiA007012007.port.T; TsAIR0CabiA006012007.port.Q_flow + (TC_901_902.port_b.Q_flow + (TC_891_902.port_b.Q_flow + (TC_681_902.port_b.Q_flow + (AIR0CabiA006012007.port.Q_flow + (TC_902_903.port_a.Q_flow + (TC_902_913.port_a.Q_flow + TC_902_1661.port_a.Q_flow)))))) = 0.0; AIR0CabiA006012007.port.T = TC_681_902.port_b.T; AIR0CabiA006012007.port.T = TC_891_902.port_b.T; AIR0CabiA006012007.port.T = TC_901_902.port_b.T; AIR0CabiA006012007.port.T = TC_902_1661.port_a.T; AIR0CabiA006012007.port.T = TC_902_903.port_a.T; AIR0CabiA006012007.port.T = TC_902_913.port_a.T; AIR0CabiA006012007.port.T = TsAIR0CabiA006012007.port.T; TsAIR0CabiA005012007.port.Q_flow + (TC_900_901.port_b.Q_flow + (TC_890_901.port_b.Q_flow + (TC_680_901.port_b.Q_flow + (AIR0CabiA005012007.port.Q_flow + (TC_901_902.port_a.Q_flow + (TC_901_912.port_a.Q_flow + TC_901_1660.port_a.Q_flow)))))) = 0.0; AIR0CabiA005012007.port.T = TC_680_901.port_b.T; AIR0CabiA005012007.port.T = TC_890_901.port_b.T; AIR0CabiA005012007.port.T = TC_900_901.port_b.T; AIR0CabiA005012007.port.T = TC_901_1660.port_a.T; AIR0CabiA005012007.port.T = TC_901_902.port_a.T; AIR0CabiA005012007.port.T = TC_901_912.port_a.T; AIR0CabiA005012007.port.T = TsAIR0CabiA005012007.port.T; TsAIR0CabiA004012007.port.Q_flow + (TC_899_900.port_b.Q_flow + (TC_889_900.port_b.Q_flow + (TC_679_900.port_b.Q_flow + (AIR0CabiA004012007.port.Q_flow + (TC_900_901.port_a.Q_flow + (TC_900_911.port_a.Q_flow + TC_900_1659.port_a.Q_flow)))))) = 0.0; AIR0CabiA004012007.port.T = TC_679_900.port_b.T; AIR0CabiA004012007.port.T = TC_889_900.port_b.T; AIR0CabiA004012007.port.T = TC_899_900.port_b.T; AIR0CabiA004012007.port.T = TC_900_1659.port_a.T; AIR0CabiA004012007.port.T = TC_900_901.port_a.T; AIR0CabiA004012007.port.T = TC_900_911.port_a.T; AIR0CabiA004012007.port.T = TsAIR0CabiA004012007.port.T; TsAIR0CabiA003012007.port.Q_flow + (TC_898_899.port_b.Q_flow + (TC_888_899.port_b.Q_flow + (TC_678_899.port_b.Q_flow + (AIR0CabiA003012007.port.Q_flow + (TC_899_900.port_a.Q_flow + (TC_899_910.port_a.Q_flow + TC_899_991.port_a.Q_flow)))))) = 0.0; AIR0CabiA003012007.port.T = TC_678_899.port_b.T; AIR0CabiA003012007.port.T = TC_888_899.port_b.T; AIR0CabiA003012007.port.T = TC_898_899.port_b.T; AIR0CabiA003012007.port.T = TC_899_900.port_a.T; AIR0CabiA003012007.port.T = TC_899_910.port_a.T; AIR0CabiA003012007.port.T = TC_899_991.port_a.T; AIR0CabiA003012007.port.T = TsAIR0CabiA003012007.port.T; TsAIR0CabiA002012007.port.Q_flow + (TC_887_898.port_b.Q_flow + (TC_677_898.port_b.Q_flow + (TC_512_898.port_b.Q_flow + (AIR0CabiA002012007.port.Q_flow + (TC_898_899.port_a.Q_flow + (TC_898_909.port_a.Q_flow + TC_898_990.port_a.Q_flow)))))) = 0.0; AIR0CabiA002012007.port.T = TC_512_898.port_b.T; AIR0CabiA002012007.port.T = TC_677_898.port_b.T; AIR0CabiA002012007.port.T = TC_887_898.port_b.T; AIR0CabiA002012007.port.T = TC_898_899.port_a.T; AIR0CabiA002012007.port.T = TC_898_909.port_a.T; AIR0CabiA002012007.port.T = TC_898_990.port_a.T; AIR0CabiA002012007.port.T = TsAIR0CabiA002012007.port.T; TsAIR0CabiA012011007.port.Q_flow + (TC_896_897.port_b.Q_flow + (TC_886_897.port_b.Q_flow + (TC_674_897.port_b.Q_flow + (TC_511_897.port_b.Q_flow + (AIR0CabiA012011007.port.Q_flow + (TC_897_908.port_a.Q_flow + TC_897_989.port_a.Q_flow)))))) = 0.0; AIR0CabiA012011007.port.T = TC_511_897.port_b.T; AIR0CabiA012011007.port.T = TC_674_897.port_b.T; AIR0CabiA012011007.port.T = TC_886_897.port_b.T; AIR0CabiA012011007.port.T = TC_896_897.port_b.T; AIR0CabiA012011007.port.T = TC_897_908.port_a.T; AIR0CabiA012011007.port.T = TC_897_989.port_a.T; AIR0CabiA012011007.port.T = TsAIR0CabiA012011007.port.T; TsAIR0CabiA011011007.port.Q_flow + (TC_895_896.port_b.Q_flow + (TC_885_896.port_b.Q_flow + (TC_673_896.port_b.Q_flow + (AIR0CabiA011011007.port.Q_flow + (TC_896_897.port_a.Q_flow + (TC_896_907.port_a.Q_flow + TC_896_988.port_a.Q_flow)))))) = 0.0; AIR0CabiA011011007.port.T = TC_673_896.port_b.T; AIR0CabiA011011007.port.T = TC_885_896.port_b.T; AIR0CabiA011011007.port.T = TC_895_896.port_b.T; AIR0CabiA011011007.port.T = TC_896_897.port_a.T; AIR0CabiA011011007.port.T = TC_896_907.port_a.T; AIR0CabiA011011007.port.T = TC_896_988.port_a.T; AIR0CabiA011011007.port.T = TsAIR0CabiA011011007.port.T; TsAIR0CabiA010011007.port.Q_flow + (TC_894_895.port_b.Q_flow + (TC_884_895.port_b.Q_flow + (TC_672_895.port_b.Q_flow + (AIR0CabiA010011007.port.Q_flow + (TC_895_896.port_a.Q_flow + (TC_895_906.port_a.Q_flow + TC_895_1655.port_a.Q_flow)))))) = 0.0; AIR0CabiA010011007.port.T = TC_672_895.port_b.T; AIR0CabiA010011007.port.T = TC_884_895.port_b.T; AIR0CabiA010011007.port.T = TC_894_895.port_b.T; AIR0CabiA010011007.port.T = TC_895_1655.port_a.T; AIR0CabiA010011007.port.T = TC_895_896.port_a.T; AIR0CabiA010011007.port.T = TC_895_906.port_a.T; AIR0CabiA010011007.port.T = TsAIR0CabiA010011007.port.T; TsAIR0CabiA009011007.port.Q_flow + (TC_893_894.port_b.Q_flow + (TC_883_894.port_b.Q_flow + (TC_671_894.port_b.Q_flow + (AIR0CabiA009011007.port.Q_flow + (TC_894_895.port_a.Q_flow + (TC_894_905.port_a.Q_flow + TC_894_1654.port_a.Q_flow)))))) = 0.0; AIR0CabiA009011007.port.T = TC_671_894.port_b.T; AIR0CabiA009011007.port.T = TC_883_894.port_b.T; AIR0CabiA009011007.port.T = TC_893_894.port_b.T; AIR0CabiA009011007.port.T = TC_894_1654.port_a.T; AIR0CabiA009011007.port.T = TC_894_895.port_a.T; AIR0CabiA009011007.port.T = TC_894_905.port_a.T; AIR0CabiA009011007.port.T = TsAIR0CabiA009011007.port.T; TsAIR0CabiA008011007.port.Q_flow + (TC_892_893.port_b.Q_flow + (TC_882_893.port_b.Q_flow + (TC_670_893.port_b.Q_flow + (AIR0CabiA008011007.port.Q_flow + (TC_893_894.port_a.Q_flow + (TC_893_904.port_a.Q_flow + TC_893_1653.port_a.Q_flow)))))) = 0.0; AIR0CabiA008011007.port.T = TC_670_893.port_b.T; AIR0CabiA008011007.port.T = TC_882_893.port_b.T; AIR0CabiA008011007.port.T = TC_892_893.port_b.T; AIR0CabiA008011007.port.T = TC_893_1653.port_a.T; AIR0CabiA008011007.port.T = TC_893_894.port_a.T; AIR0CabiA008011007.port.T = TC_893_904.port_a.T; AIR0CabiA008011007.port.T = TsAIR0CabiA008011007.port.T; TsAIR0CabiA007011007.port.Q_flow + (TC_891_892.port_b.Q_flow + (TC_881_892.port_b.Q_flow + (TC_669_892.port_b.Q_flow + (AIR0CabiA007011007.port.Q_flow + (TC_892_893.port_a.Q_flow + (TC_892_903.port_a.Q_flow + TC_892_987.port_a.Q_flow)))))) = 0.0; AIR0CabiA007011007.port.T = TC_669_892.port_b.T; AIR0CabiA007011007.port.T = TC_881_892.port_b.T; AIR0CabiA007011007.port.T = TC_891_892.port_b.T; AIR0CabiA007011007.port.T = TC_892_893.port_a.T; AIR0CabiA007011007.port.T = TC_892_903.port_a.T; AIR0CabiA007011007.port.T = TC_892_987.port_a.T; AIR0CabiA007011007.port.T = TsAIR0CabiA007011007.port.T; TsAIR0CabiA006011007.port.Q_flow + (TC_890_891.port_b.Q_flow + (TC_880_891.port_b.Q_flow + (TC_668_891.port_b.Q_flow + (AIR0CabiA006011007.port.Q_flow + (TC_891_892.port_a.Q_flow + (TC_891_902.port_a.Q_flow + TC_891_1658.port_a.Q_flow)))))) = 0.0; AIR0CabiA006011007.port.T = TC_668_891.port_b.T; AIR0CabiA006011007.port.T = TC_880_891.port_b.T; AIR0CabiA006011007.port.T = TC_890_891.port_b.T; AIR0CabiA006011007.port.T = TC_891_1658.port_a.T; AIR0CabiA006011007.port.T = TC_891_892.port_a.T; AIR0CabiA006011007.port.T = TC_891_902.port_a.T; AIR0CabiA006011007.port.T = TsAIR0CabiA006011007.port.T; TsAIR0CabiA005011007.port.Q_flow + (TC_889_890.port_b.Q_flow + (TC_879_890.port_b.Q_flow + (TC_667_890.port_b.Q_flow + (AIR0CabiA005011007.port.Q_flow + (TC_890_891.port_a.Q_flow + (TC_890_901.port_a.Q_flow + TC_890_1657.port_a.Q_flow)))))) = 0.0; AIR0CabiA005011007.port.T = TC_667_890.port_b.T; AIR0CabiA005011007.port.T = TC_879_890.port_b.T; AIR0CabiA005011007.port.T = TC_889_890.port_b.T; AIR0CabiA005011007.port.T = TC_890_1657.port_a.T; AIR0CabiA005011007.port.T = TC_890_891.port_a.T; AIR0CabiA005011007.port.T = TC_890_901.port_a.T; AIR0CabiA005011007.port.T = TsAIR0CabiA005011007.port.T; TsAIR0CabiA004011007.port.Q_flow + (TC_888_889.port_b.Q_flow + (TC_878_889.port_b.Q_flow + (TC_666_889.port_b.Q_flow + (AIR0CabiA004011007.port.Q_flow + (TC_889_890.port_a.Q_flow + (TC_889_900.port_a.Q_flow + TC_889_1656.port_a.Q_flow)))))) = 0.0; AIR0CabiA004011007.port.T = TC_666_889.port_b.T; AIR0CabiA004011007.port.T = TC_878_889.port_b.T; AIR0CabiA004011007.port.T = TC_888_889.port_b.T; AIR0CabiA004011007.port.T = TC_889_1656.port_a.T; AIR0CabiA004011007.port.T = TC_889_890.port_a.T; AIR0CabiA004011007.port.T = TC_889_900.port_a.T; AIR0CabiA004011007.port.T = TsAIR0CabiA004011007.port.T; TsAIR0CabiA003011007.port.Q_flow + (TC_887_888.port_b.Q_flow + (TC_877_888.port_b.Q_flow + (TC_665_888.port_b.Q_flow + (AIR0CabiA003011007.port.Q_flow + (TC_888_889.port_a.Q_flow + (TC_888_899.port_a.Q_flow + TC_888_986.port_a.Q_flow)))))) = 0.0; AIR0CabiA003011007.port.T = TC_665_888.port_b.T; AIR0CabiA003011007.port.T = TC_877_888.port_b.T; AIR0CabiA003011007.port.T = TC_887_888.port_b.T; AIR0CabiA003011007.port.T = TC_888_889.port_a.T; AIR0CabiA003011007.port.T = TC_888_899.port_a.T; AIR0CabiA003011007.port.T = TC_888_986.port_a.T; AIR0CabiA003011007.port.T = TsAIR0CabiA003011007.port.T; TsAIR0CabiA002011007.port.Q_flow + (TC_876_887.port_b.Q_flow + (TC_664_887.port_b.Q_flow + (TC_510_887.port_b.Q_flow + (AIR0CabiA002011007.port.Q_flow + (TC_887_888.port_a.Q_flow + (TC_887_898.port_a.Q_flow + TC_887_985.port_a.Q_flow)))))) = 0.0; AIR0CabiA002011007.port.T = TC_510_887.port_b.T; AIR0CabiA002011007.port.T = TC_664_887.port_b.T; AIR0CabiA002011007.port.T = TC_876_887.port_b.T; AIR0CabiA002011007.port.T = TC_887_888.port_a.T; AIR0CabiA002011007.port.T = TC_887_898.port_a.T; AIR0CabiA002011007.port.T = TC_887_985.port_a.T; AIR0CabiA002011007.port.T = TsAIR0CabiA002011007.port.T; TsAIR0CabiA012010007.port.Q_flow + (TC_885_886.port_b.Q_flow + (TC_875_886.port_b.Q_flow + (TC_661_886.port_b.Q_flow + (TC_509_886.port_b.Q_flow + (AIR0CabiA012010007.port.Q_flow + (TC_886_897.port_a.Q_flow + TC_886_984.port_a.Q_flow)))))) = 0.0; AIR0CabiA012010007.port.T = TC_509_886.port_b.T; AIR0CabiA012010007.port.T = TC_661_886.port_b.T; AIR0CabiA012010007.port.T = TC_875_886.port_b.T; AIR0CabiA012010007.port.T = TC_885_886.port_b.T; AIR0CabiA012010007.port.T = TC_886_897.port_a.T; AIR0CabiA012010007.port.T = TC_886_984.port_a.T; AIR0CabiA012010007.port.T = TsAIR0CabiA012010007.port.T; TsAIR0CabiA011010007.port.Q_flow + (TC_884_885.port_b.Q_flow + (TC_874_885.port_b.Q_flow + (TC_660_885.port_b.Q_flow + (AIR0CabiA011010007.port.Q_flow + (TC_885_886.port_a.Q_flow + (TC_885_896.port_a.Q_flow + TC_885_983.port_a.Q_flow)))))) = 0.0; AIR0CabiA011010007.port.T = TC_660_885.port_b.T; AIR0CabiA011010007.port.T = TC_874_885.port_b.T; AIR0CabiA011010007.port.T = TC_884_885.port_b.T; AIR0CabiA011010007.port.T = TC_885_886.port_a.T; AIR0CabiA011010007.port.T = TC_885_896.port_a.T; AIR0CabiA011010007.port.T = TC_885_983.port_a.T; AIR0CabiA011010007.port.T = TsAIR0CabiA011010007.port.T; TsAIR0CabiA010010007.port.Q_flow + (TC_883_884.port_b.Q_flow + (TC_873_884.port_b.Q_flow + (TC_659_884.port_b.Q_flow + (AIR0CabiA010010007.port.Q_flow + (TC_884_885.port_a.Q_flow + (TC_884_895.port_a.Q_flow + TC_884_1652.port_a.Q_flow)))))) = 0.0; AIR0CabiA010010007.port.T = TC_659_884.port_b.T; AIR0CabiA010010007.port.T = TC_873_884.port_b.T; AIR0CabiA010010007.port.T = TC_883_884.port_b.T; AIR0CabiA010010007.port.T = TC_884_1652.port_a.T; AIR0CabiA010010007.port.T = TC_884_885.port_a.T; AIR0CabiA010010007.port.T = TC_884_895.port_a.T; AIR0CabiA010010007.port.T = TsAIR0CabiA010010007.port.T; TsAIR0CabiA009010007.port.Q_flow + (TC_882_883.port_b.Q_flow + (TC_872_883.port_b.Q_flow + (TC_658_883.port_b.Q_flow + (AIR0CabiA009010007.port.Q_flow + (TC_883_884.port_a.Q_flow + (TC_883_894.port_a.Q_flow + TC_883_1651.port_a.Q_flow)))))) = 0.0; AIR0CabiA009010007.port.T = TC_658_883.port_b.T; AIR0CabiA009010007.port.T = TC_872_883.port_b.T; AIR0CabiA009010007.port.T = TC_882_883.port_b.T; AIR0CabiA009010007.port.T = TC_883_1651.port_a.T; AIR0CabiA009010007.port.T = TC_883_884.port_a.T; AIR0CabiA009010007.port.T = TC_883_894.port_a.T; AIR0CabiA009010007.port.T = TsAIR0CabiA009010007.port.T; TsAIR0CabiA008010007.port.Q_flow + (TC_881_882.port_b.Q_flow + (TC_871_882.port_b.Q_flow + (TC_657_882.port_b.Q_flow + (AIR0CabiA008010007.port.Q_flow + (TC_882_883.port_a.Q_flow + (TC_882_893.port_a.Q_flow + TC_882_1650.port_a.Q_flow)))))) = 0.0; AIR0CabiA008010007.port.T = TC_657_882.port_b.T; AIR0CabiA008010007.port.T = TC_871_882.port_b.T; AIR0CabiA008010007.port.T = TC_881_882.port_b.T; AIR0CabiA008010007.port.T = TC_882_1650.port_a.T; AIR0CabiA008010007.port.T = TC_882_883.port_a.T; AIR0CabiA008010007.port.T = TC_882_893.port_a.T; AIR0CabiA008010007.port.T = TsAIR0CabiA008010007.port.T; TsAIR0CabiA007010007.port.Q_flow + (TC_880_881.port_b.Q_flow + (TC_870_881.port_b.Q_flow + (TC_656_881.port_b.Q_flow + (AIR0CabiA007010007.port.Q_flow + (TC_881_882.port_a.Q_flow + (TC_881_892.port_a.Q_flow + TC_881_982.port_a.Q_flow)))))) = 0.0; AIR0CabiA007010007.port.T = TC_656_881.port_b.T; AIR0CabiA007010007.port.T = TC_870_881.port_b.T; AIR0CabiA007010007.port.T = TC_880_881.port_b.T; AIR0CabiA007010007.port.T = TC_881_882.port_a.T; AIR0CabiA007010007.port.T = TC_881_892.port_a.T; AIR0CabiA007010007.port.T = TC_881_982.port_a.T; AIR0CabiA007010007.port.T = TsAIR0CabiA007010007.port.T; TsAIR0CabiA006010007.port.Q_flow + (TC_879_880.port_b.Q_flow + (TC_869_880.port_b.Q_flow + (TC_655_880.port_b.Q_flow + (AIR0CabiA006010007.port.Q_flow + (TC_880_881.port_a.Q_flow + (TC_880_891.port_a.Q_flow + TC_880_981.port_a.Q_flow)))))) = 0.0; AIR0CabiA006010007.port.T = TC_655_880.port_b.T; AIR0CabiA006010007.port.T = TC_869_880.port_b.T; AIR0CabiA006010007.port.T = TC_879_880.port_b.T; AIR0CabiA006010007.port.T = TC_880_881.port_a.T; AIR0CabiA006010007.port.T = TC_880_891.port_a.T; AIR0CabiA006010007.port.T = TC_880_981.port_a.T; AIR0CabiA006010007.port.T = TsAIR0CabiA006010007.port.T; TsAIR0CabiA005010007.port.Q_flow + (TC_878_879.port_b.Q_flow + (TC_868_879.port_b.Q_flow + (TC_654_879.port_b.Q_flow + (AIR0CabiA005010007.port.Q_flow + (TC_879_880.port_a.Q_flow + (TC_879_890.port_a.Q_flow + TC_879_980.port_a.Q_flow)))))) = 0.0; AIR0CabiA005010007.port.T = TC_654_879.port_b.T; AIR0CabiA005010007.port.T = TC_868_879.port_b.T; AIR0CabiA005010007.port.T = TC_878_879.port_b.T; AIR0CabiA005010007.port.T = TC_879_880.port_a.T; AIR0CabiA005010007.port.T = TC_879_890.port_a.T; AIR0CabiA005010007.port.T = TC_879_980.port_a.T; AIR0CabiA005010007.port.T = TsAIR0CabiA005010007.port.T; TsAIR0CabiA004010007.port.Q_flow + (TC_877_878.port_b.Q_flow + (TC_867_878.port_b.Q_flow + (TC_653_878.port_b.Q_flow + (AIR0CabiA004010007.port.Q_flow + (TC_878_879.port_a.Q_flow + (TC_878_889.port_a.Q_flow + TC_878_979.port_a.Q_flow)))))) = 0.0; AIR0CabiA004010007.port.T = TC_653_878.port_b.T; AIR0CabiA004010007.port.T = TC_867_878.port_b.T; AIR0CabiA004010007.port.T = TC_877_878.port_b.T; AIR0CabiA004010007.port.T = TC_878_879.port_a.T; AIR0CabiA004010007.port.T = TC_878_889.port_a.T; AIR0CabiA004010007.port.T = TC_878_979.port_a.T; AIR0CabiA004010007.port.T = TsAIR0CabiA004010007.port.T; TsAIR0CabiA003010007.port.Q_flow + (TC_876_877.port_b.Q_flow + (TC_866_877.port_b.Q_flow + (TC_652_877.port_b.Q_flow + (AIR0CabiA003010007.port.Q_flow + (TC_877_878.port_a.Q_flow + (TC_877_888.port_a.Q_flow + TC_877_978.port_a.Q_flow)))))) = 0.0; AIR0CabiA003010007.port.T = TC_652_877.port_b.T; AIR0CabiA003010007.port.T = TC_866_877.port_b.T; AIR0CabiA003010007.port.T = TC_876_877.port_b.T; AIR0CabiA003010007.port.T = TC_877_878.port_a.T; AIR0CabiA003010007.port.T = TC_877_888.port_a.T; AIR0CabiA003010007.port.T = TC_877_978.port_a.T; AIR0CabiA003010007.port.T = TsAIR0CabiA003010007.port.T; TsAIR0CabiA002010007.port.Q_flow + (TC_865_876.port_b.Q_flow + (TC_651_876.port_b.Q_flow + (TC_508_876.port_b.Q_flow + (AIR0CabiA002010007.port.Q_flow + (TC_876_877.port_a.Q_flow + (TC_876_887.port_a.Q_flow + TC_876_977.port_a.Q_flow)))))) = 0.0; AIR0CabiA002010007.port.T = TC_508_876.port_b.T; AIR0CabiA002010007.port.T = TC_651_876.port_b.T; AIR0CabiA002010007.port.T = TC_865_876.port_b.T; AIR0CabiA002010007.port.T = TC_876_877.port_a.T; AIR0CabiA002010007.port.T = TC_876_887.port_a.T; AIR0CabiA002010007.port.T = TC_876_977.port_a.T; AIR0CabiA002010007.port.T = TsAIR0CabiA002010007.port.T; TsAIR0CabiA012009007.port.Q_flow + (TC_874_875.port_b.Q_flow + (TC_864_875.port_b.Q_flow + (TC_648_875.port_b.Q_flow + (TC_507_875.port_b.Q_flow + (AIR0CabiA012009007.port.Q_flow + (TC_875_886.port_a.Q_flow + TC_875_976.port_a.Q_flow)))))) = 0.0; AIR0CabiA012009007.port.T = TC_507_875.port_b.T; AIR0CabiA012009007.port.T = TC_648_875.port_b.T; AIR0CabiA012009007.port.T = TC_864_875.port_b.T; AIR0CabiA012009007.port.T = TC_874_875.port_b.T; AIR0CabiA012009007.port.T = TC_875_886.port_a.T; AIR0CabiA012009007.port.T = TC_875_976.port_a.T; AIR0CabiA012009007.port.T = TsAIR0CabiA012009007.port.T; TsAIR0CabiA011009007.port.Q_flow + (TC_873_874.port_b.Q_flow + (TC_863_874.port_b.Q_flow + (TC_647_874.port_b.Q_flow + (AIR0CabiA011009007.port.Q_flow + (TC_874_875.port_a.Q_flow + (TC_874_885.port_a.Q_flow + TC_874_975.port_a.Q_flow)))))) = 0.0; AIR0CabiA011009007.port.T = TC_647_874.port_b.T; AIR0CabiA011009007.port.T = TC_863_874.port_b.T; AIR0CabiA011009007.port.T = TC_873_874.port_b.T; AIR0CabiA011009007.port.T = TC_874_875.port_a.T; AIR0CabiA011009007.port.T = TC_874_885.port_a.T; AIR0CabiA011009007.port.T = TC_874_975.port_a.T; AIR0CabiA011009007.port.T = TsAIR0CabiA011009007.port.T; TsAIR0CabiA010009007.port.Q_flow + (TC_872_873.port_b.Q_flow + (TC_862_873.port_b.Q_flow + (TC_646_873.port_b.Q_flow + (AIR0CabiA010009007.port.Q_flow + (TC_873_874.port_a.Q_flow + (TC_873_884.port_a.Q_flow + TC_873_1649.port_a.Q_flow)))))) = 0.0; AIR0CabiA010009007.port.T = TC_646_873.port_b.T; AIR0CabiA010009007.port.T = TC_862_873.port_b.T; AIR0CabiA010009007.port.T = TC_872_873.port_b.T; AIR0CabiA010009007.port.T = TC_873_1649.port_a.T; AIR0CabiA010009007.port.T = TC_873_874.port_a.T; AIR0CabiA010009007.port.T = TC_873_884.port_a.T; AIR0CabiA010009007.port.T = TsAIR0CabiA010009007.port.T; TsAIR0CabiA009009007.port.Q_flow + (TC_871_872.port_b.Q_flow + (TC_861_872.port_b.Q_flow + (TC_645_872.port_b.Q_flow + (AIR0CabiA009009007.port.Q_flow + (TC_872_873.port_a.Q_flow + (TC_872_883.port_a.Q_flow + TC_872_1648.port_a.Q_flow)))))) = 0.0; AIR0CabiA009009007.port.T = TC_645_872.port_b.T; AIR0CabiA009009007.port.T = TC_861_872.port_b.T; AIR0CabiA009009007.port.T = TC_871_872.port_b.T; AIR0CabiA009009007.port.T = TC_872_1648.port_a.T; AIR0CabiA009009007.port.T = TC_872_873.port_a.T; AIR0CabiA009009007.port.T = TC_872_883.port_a.T; AIR0CabiA009009007.port.T = TsAIR0CabiA009009007.port.T; TsAIR0CabiA008009007.port.Q_flow + (TC_870_871.port_b.Q_flow + (TC_860_871.port_b.Q_flow + (TC_644_871.port_b.Q_flow + (AIR0CabiA008009007.port.Q_flow + (TC_871_872.port_a.Q_flow + (TC_871_882.port_a.Q_flow + TC_871_1647.port_a.Q_flow)))))) = 0.0; AIR0CabiA008009007.port.T = TC_644_871.port_b.T; AIR0CabiA008009007.port.T = TC_860_871.port_b.T; AIR0CabiA008009007.port.T = TC_870_871.port_b.T; AIR0CabiA008009007.port.T = TC_871_1647.port_a.T; AIR0CabiA008009007.port.T = TC_871_872.port_a.T; AIR0CabiA008009007.port.T = TC_871_882.port_a.T; AIR0CabiA008009007.port.T = TsAIR0CabiA008009007.port.T; TsAIR0CabiA007009007.port.Q_flow + (TC_869_870.port_b.Q_flow + (TC_859_870.port_b.Q_flow + (TC_643_870.port_b.Q_flow + (AIR0CabiA007009007.port.Q_flow + (TC_870_871.port_a.Q_flow + (TC_870_881.port_a.Q_flow + TC_870_1065.port_a.Q_flow)))))) = 0.0; AIR0CabiA007009007.port.T = TC_643_870.port_b.T; AIR0CabiA007009007.port.T = TC_859_870.port_b.T; AIR0CabiA007009007.port.T = TC_869_870.port_b.T; AIR0CabiA007009007.port.T = TC_870_1065.port_a.T; AIR0CabiA007009007.port.T = TC_870_871.port_a.T; AIR0CabiA007009007.port.T = TC_870_881.port_a.T; AIR0CabiA007009007.port.T = TsAIR0CabiA007009007.port.T; TsAIR0CabiA006009007.port.Q_flow + (TC_868_869.port_b.Q_flow + (TC_858_869.port_b.Q_flow + (TC_642_869.port_b.Q_flow + (AIR0CabiA006009007.port.Q_flow + (TC_869_870.port_a.Q_flow + (TC_869_880.port_a.Q_flow + TC_869_1064.port_a.Q_flow)))))) = 0.0; AIR0CabiA006009007.port.T = TC_642_869.port_b.T; AIR0CabiA006009007.port.T = TC_858_869.port_b.T; AIR0CabiA006009007.port.T = TC_868_869.port_b.T; AIR0CabiA006009007.port.T = TC_869_1064.port_a.T; AIR0CabiA006009007.port.T = TC_869_870.port_a.T; AIR0CabiA006009007.port.T = TC_869_880.port_a.T; AIR0CabiA006009007.port.T = TsAIR0CabiA006009007.port.T; TsAIR0CabiA005009007.port.Q_flow + (TC_867_868.port_b.Q_flow + (TC_857_868.port_b.Q_flow + (TC_641_868.port_b.Q_flow + (AIR0CabiA005009007.port.Q_flow + (TC_868_869.port_a.Q_flow + (TC_868_879.port_a.Q_flow + TC_868_1063.port_a.Q_flow)))))) = 0.0; AIR0CabiA005009007.port.T = TC_641_868.port_b.T; AIR0CabiA005009007.port.T = TC_857_868.port_b.T; AIR0CabiA005009007.port.T = TC_867_868.port_b.T; AIR0CabiA005009007.port.T = TC_868_1063.port_a.T; AIR0CabiA005009007.port.T = TC_868_869.port_a.T; AIR0CabiA005009007.port.T = TC_868_879.port_a.T; AIR0CabiA005009007.port.T = TsAIR0CabiA005009007.port.T; TsAIR0CabiA004009007.port.Q_flow + (TC_866_867.port_b.Q_flow + (TC_856_867.port_b.Q_flow + (TC_640_867.port_b.Q_flow + (AIR0CabiA004009007.port.Q_flow + (TC_867_868.port_a.Q_flow + (TC_867_878.port_a.Q_flow + TC_867_1062.port_a.Q_flow)))))) = 0.0; AIR0CabiA004009007.port.T = TC_640_867.port_b.T; AIR0CabiA004009007.port.T = TC_856_867.port_b.T; AIR0CabiA004009007.port.T = TC_866_867.port_b.T; AIR0CabiA004009007.port.T = TC_867_1062.port_a.T; AIR0CabiA004009007.port.T = TC_867_868.port_a.T; AIR0CabiA004009007.port.T = TC_867_878.port_a.T; AIR0CabiA004009007.port.T = TsAIR0CabiA004009007.port.T; TsAIR0CabiA003009007.port.Q_flow + (TC_865_866.port_b.Q_flow + (TC_855_866.port_b.Q_flow + (TC_639_866.port_b.Q_flow + (AIR0CabiA003009007.port.Q_flow + (TC_866_867.port_a.Q_flow + (TC_866_877.port_a.Q_flow + TC_866_1061.port_a.Q_flow)))))) = 0.0; AIR0CabiA003009007.port.T = TC_639_866.port_b.T; AIR0CabiA003009007.port.T = TC_855_866.port_b.T; AIR0CabiA003009007.port.T = TC_865_866.port_b.T; AIR0CabiA003009007.port.T = TC_866_1061.port_a.T; AIR0CabiA003009007.port.T = TC_866_867.port_a.T; AIR0CabiA003009007.port.T = TC_866_877.port_a.T; AIR0CabiA003009007.port.T = TsAIR0CabiA003009007.port.T; TsAIR0CabiA002009007.port.Q_flow + (TC_854_865.port_b.Q_flow + (TC_638_865.port_b.Q_flow + (TC_506_865.port_b.Q_flow + (AIR0CabiA002009007.port.Q_flow + (TC_865_866.port_a.Q_flow + (TC_865_876.port_a.Q_flow + TC_865_1060.port_a.Q_flow)))))) = 0.0; AIR0CabiA002009007.port.T = TC_506_865.port_b.T; AIR0CabiA002009007.port.T = TC_638_865.port_b.T; AIR0CabiA002009007.port.T = TC_854_865.port_b.T; AIR0CabiA002009007.port.T = TC_865_1060.port_a.T; AIR0CabiA002009007.port.T = TC_865_866.port_a.T; AIR0CabiA002009007.port.T = TC_865_876.port_a.T; AIR0CabiA002009007.port.T = TsAIR0CabiA002009007.port.T; TsAIR0CabiA012008007.port.Q_flow + (TC_863_864.port_b.Q_flow + (TC_853_864.port_b.Q_flow + (TC_635_864.port_b.Q_flow + (TC_505_864.port_b.Q_flow + (AIR0CabiA012008007.port.Q_flow + (TC_864_875.port_a.Q_flow + TC_864_1059.port_a.Q_flow)))))) = 0.0; AIR0CabiA012008007.port.T = TC_505_864.port_b.T; AIR0CabiA012008007.port.T = TC_635_864.port_b.T; AIR0CabiA012008007.port.T = TC_853_864.port_b.T; AIR0CabiA012008007.port.T = TC_863_864.port_b.T; AIR0CabiA012008007.port.T = TC_864_1059.port_a.T; AIR0CabiA012008007.port.T = TC_864_875.port_a.T; AIR0CabiA012008007.port.T = TsAIR0CabiA012008007.port.T; TsAIR0CabiA011008007.port.Q_flow + (TC_862_863.port_b.Q_flow + (TC_852_863.port_b.Q_flow + (TC_634_863.port_b.Q_flow + (AIR0CabiA011008007.port.Q_flow + (TC_863_864.port_a.Q_flow + (TC_863_874.port_a.Q_flow + TC_863_1058.port_a.Q_flow)))))) = 0.0; AIR0CabiA011008007.port.T = TC_634_863.port_b.T; AIR0CabiA011008007.port.T = TC_852_863.port_b.T; AIR0CabiA011008007.port.T = TC_862_863.port_b.T; AIR0CabiA011008007.port.T = TC_863_1058.port_a.T; AIR0CabiA011008007.port.T = TC_863_864.port_a.T; AIR0CabiA011008007.port.T = TC_863_874.port_a.T; AIR0CabiA011008007.port.T = TsAIR0CabiA011008007.port.T; TsAIR0CabiA010008007.port.Q_flow + (TC_861_862.port_b.Q_flow + (TC_851_862.port_b.Q_flow + (TC_633_862.port_b.Q_flow + (AIR0CabiA010008007.port.Q_flow + (TC_862_863.port_a.Q_flow + (TC_862_873.port_a.Q_flow + TC_862_1057.port_a.Q_flow)))))) = 0.0; AIR0CabiA010008007.port.T = TC_633_862.port_b.T; AIR0CabiA010008007.port.T = TC_851_862.port_b.T; AIR0CabiA010008007.port.T = TC_861_862.port_b.T; AIR0CabiA010008007.port.T = TC_862_1057.port_a.T; AIR0CabiA010008007.port.T = TC_862_863.port_a.T; AIR0CabiA010008007.port.T = TC_862_873.port_a.T; AIR0CabiA010008007.port.T = TsAIR0CabiA010008007.port.T; TsAIR0CabiA009008007.port.Q_flow + (TC_860_861.port_b.Q_flow + (TC_850_861.port_b.Q_flow + (TC_632_861.port_b.Q_flow + (AIR0CabiA009008007.port.Q_flow + (TC_861_862.port_a.Q_flow + (TC_861_872.port_a.Q_flow + TC_861_1056.port_a.Q_flow)))))) = 0.0; AIR0CabiA009008007.port.T = TC_632_861.port_b.T; AIR0CabiA009008007.port.T = TC_850_861.port_b.T; AIR0CabiA009008007.port.T = TC_860_861.port_b.T; AIR0CabiA009008007.port.T = TC_861_1056.port_a.T; AIR0CabiA009008007.port.T = TC_861_862.port_a.T; AIR0CabiA009008007.port.T = TC_861_872.port_a.T; AIR0CabiA009008007.port.T = TsAIR0CabiA009008007.port.T; TsAIR0CabiA008008007.port.Q_flow + (TC_859_860.port_b.Q_flow + (TC_849_860.port_b.Q_flow + (TC_631_860.port_b.Q_flow + (AIR0CabiA008008007.port.Q_flow + (TC_860_861.port_a.Q_flow + (TC_860_871.port_a.Q_flow + TC_860_1055.port_a.Q_flow)))))) = 0.0; AIR0CabiA008008007.port.T = TC_631_860.port_b.T; AIR0CabiA008008007.port.T = TC_849_860.port_b.T; AIR0CabiA008008007.port.T = TC_859_860.port_b.T; AIR0CabiA008008007.port.T = TC_860_1055.port_a.T; AIR0CabiA008008007.port.T = TC_860_861.port_a.T; AIR0CabiA008008007.port.T = TC_860_871.port_a.T; AIR0CabiA008008007.port.T = TsAIR0CabiA008008007.port.T; TsAIR0CabiA007008007.port.Q_flow + (TC_858_859.port_b.Q_flow + (TC_848_859.port_b.Q_flow + (TC_630_859.port_b.Q_flow + (AIR0CabiA007008007.port.Q_flow + (TC_859_860.port_a.Q_flow + (TC_859_870.port_a.Q_flow + TC_859_1054.port_a.Q_flow)))))) = 0.0; AIR0CabiA007008007.port.T = TC_630_859.port_b.T; AIR0CabiA007008007.port.T = TC_848_859.port_b.T; AIR0CabiA007008007.port.T = TC_858_859.port_b.T; AIR0CabiA007008007.port.T = TC_859_1054.port_a.T; AIR0CabiA007008007.port.T = TC_859_860.port_a.T; AIR0CabiA007008007.port.T = TC_859_870.port_a.T; AIR0CabiA007008007.port.T = TsAIR0CabiA007008007.port.T; TsAIR0CabiA006008007.port.Q_flow + (TC_857_858.port_b.Q_flow + (TC_847_858.port_b.Q_flow + (TC_629_858.port_b.Q_flow + (AIR0CabiA006008007.port.Q_flow + (TC_858_859.port_a.Q_flow + (TC_858_869.port_a.Q_flow + TC_858_1053.port_a.Q_flow)))))) = 0.0; AIR0CabiA006008007.port.T = TC_629_858.port_b.T; AIR0CabiA006008007.port.T = TC_847_858.port_b.T; AIR0CabiA006008007.port.T = TC_857_858.port_b.T; AIR0CabiA006008007.port.T = TC_858_1053.port_a.T; AIR0CabiA006008007.port.T = TC_858_859.port_a.T; AIR0CabiA006008007.port.T = TC_858_869.port_a.T; AIR0CabiA006008007.port.T = TsAIR0CabiA006008007.port.T; TsAIR0CabiA005008007.port.Q_flow + (TC_856_857.port_b.Q_flow + (TC_846_857.port_b.Q_flow + (TC_628_857.port_b.Q_flow + (AIR0CabiA005008007.port.Q_flow + (TC_857_858.port_a.Q_flow + (TC_857_868.port_a.Q_flow + TC_857_1052.port_a.Q_flow)))))) = 0.0; AIR0CabiA005008007.port.T = TC_628_857.port_b.T; AIR0CabiA005008007.port.T = TC_846_857.port_b.T; AIR0CabiA005008007.port.T = TC_856_857.port_b.T; AIR0CabiA005008007.port.T = TC_857_1052.port_a.T; AIR0CabiA005008007.port.T = TC_857_858.port_a.T; AIR0CabiA005008007.port.T = TC_857_868.port_a.T; AIR0CabiA005008007.port.T = TsAIR0CabiA005008007.port.T; TsAIR0CabiA004008007.port.Q_flow + (TC_855_856.port_b.Q_flow + (TC_845_856.port_b.Q_flow + (TC_627_856.port_b.Q_flow + (AIR0CabiA004008007.port.Q_flow + (TC_856_857.port_a.Q_flow + (TC_856_867.port_a.Q_flow + TC_856_1051.port_a.Q_flow)))))) = 0.0; AIR0CabiA004008007.port.T = TC_627_856.port_b.T; AIR0CabiA004008007.port.T = TC_845_856.port_b.T; AIR0CabiA004008007.port.T = TC_855_856.port_b.T; AIR0CabiA004008007.port.T = TC_856_1051.port_a.T; AIR0CabiA004008007.port.T = TC_856_857.port_a.T; AIR0CabiA004008007.port.T = TC_856_867.port_a.T; AIR0CabiA004008007.port.T = TsAIR0CabiA004008007.port.T; TsAIR0CabiA003008007.port.Q_flow + (TC_854_855.port_b.Q_flow + (TC_844_855.port_b.Q_flow + (TC_626_855.port_b.Q_flow + (AIR0CabiA003008007.port.Q_flow + (TC_855_856.port_a.Q_flow + (TC_855_866.port_a.Q_flow + TC_855_1050.port_a.Q_flow)))))) = 0.0; AIR0CabiA003008007.port.T = TC_626_855.port_b.T; AIR0CabiA003008007.port.T = TC_844_855.port_b.T; AIR0CabiA003008007.port.T = TC_854_855.port_b.T; AIR0CabiA003008007.port.T = TC_855_1050.port_a.T; AIR0CabiA003008007.port.T = TC_855_856.port_a.T; AIR0CabiA003008007.port.T = TC_855_866.port_a.T; AIR0CabiA003008007.port.T = TsAIR0CabiA003008007.port.T; TsAIR0CabiA002008007.port.Q_flow + (TC_843_854.port_b.Q_flow + (TC_625_854.port_b.Q_flow + (TC_504_854.port_b.Q_flow + (AIR0CabiA002008007.port.Q_flow + (TC_854_855.port_a.Q_flow + (TC_854_865.port_a.Q_flow + TC_854_1049.port_a.Q_flow)))))) = 0.0; AIR0CabiA002008007.port.T = TC_504_854.port_b.T; AIR0CabiA002008007.port.T = TC_625_854.port_b.T; AIR0CabiA002008007.port.T = TC_843_854.port_b.T; AIR0CabiA002008007.port.T = TC_854_1049.port_a.T; AIR0CabiA002008007.port.T = TC_854_855.port_a.T; AIR0CabiA002008007.port.T = TC_854_865.port_a.T; AIR0CabiA002008007.port.T = TsAIR0CabiA002008007.port.T; TsAIR0CabiA012007007.port.Q_flow + (TC_852_853.port_b.Q_flow + (TC_622_853.port_b.Q_flow + (TC_503_853.port_b.Q_flow + (AIR0CabiA012007007.port.Q_flow + (TC_853_864.port_a.Q_flow + (TC_853_974.port_a.Q_flow + TC_853_1048.port_a.Q_flow)))))) = 0.0; AIR0CabiA012007007.port.T = TC_503_853.port_b.T; AIR0CabiA012007007.port.T = TC_622_853.port_b.T; AIR0CabiA012007007.port.T = TC_852_853.port_b.T; AIR0CabiA012007007.port.T = TC_853_1048.port_a.T; AIR0CabiA012007007.port.T = TC_853_864.port_a.T; AIR0CabiA012007007.port.T = TC_853_974.port_a.T; AIR0CabiA012007007.port.T = TsAIR0CabiA012007007.port.T; TsAIR0CabiA011007007.port.Q_flow + (TC_851_852.port_b.Q_flow + (TC_621_852.port_b.Q_flow + (AIR0CabiA011007007.port.Q_flow + (TC_852_853.port_a.Q_flow + (TC_852_863.port_a.Q_flow + (TC_852_973.port_a.Q_flow + TC_852_1047.port_a.Q_flow)))))) = 0.0; AIR0CabiA011007007.port.T = TC_621_852.port_b.T; AIR0CabiA011007007.port.T = TC_851_852.port_b.T; AIR0CabiA011007007.port.T = TC_852_1047.port_a.T; AIR0CabiA011007007.port.T = TC_852_853.port_a.T; AIR0CabiA011007007.port.T = TC_852_863.port_a.T; AIR0CabiA011007007.port.T = TC_852_973.port_a.T; AIR0CabiA011007007.port.T = TsAIR0CabiA011007007.port.T; TsAIR0CabiA010007007.port.Q_flow + (TC_850_851.port_b.Q_flow + (TC_620_851.port_b.Q_flow + (AIR0CabiA010007007.port.Q_flow + (TC_851_852.port_a.Q_flow + (TC_851_862.port_a.Q_flow + (TC_851_972.port_a.Q_flow + TC_851_1046.port_a.Q_flow)))))) = 0.0; AIR0CabiA010007007.port.T = TC_620_851.port_b.T; AIR0CabiA010007007.port.T = TC_850_851.port_b.T; AIR0CabiA010007007.port.T = TC_851_1046.port_a.T; AIR0CabiA010007007.port.T = TC_851_852.port_a.T; AIR0CabiA010007007.port.T = TC_851_862.port_a.T; AIR0CabiA010007007.port.T = TC_851_972.port_a.T; AIR0CabiA010007007.port.T = TsAIR0CabiA010007007.port.T; TsAIR0CabiA009007007.port.Q_flow + (TC_849_850.port_b.Q_flow + (TC_619_850.port_b.Q_flow + (AIR0CabiA009007007.port.Q_flow + (TC_850_851.port_a.Q_flow + (TC_850_861.port_a.Q_flow + (TC_850_971.port_a.Q_flow + TC_850_1045.port_a.Q_flow)))))) = 0.0; AIR0CabiA009007007.port.T = TC_619_850.port_b.T; AIR0CabiA009007007.port.T = TC_849_850.port_b.T; AIR0CabiA009007007.port.T = TC_850_1045.port_a.T; AIR0CabiA009007007.port.T = TC_850_851.port_a.T; AIR0CabiA009007007.port.T = TC_850_861.port_a.T; AIR0CabiA009007007.port.T = TC_850_971.port_a.T; AIR0CabiA009007007.port.T = TsAIR0CabiA009007007.port.T; TsAIR0CabiA008007007.port.Q_flow + (TC_848_849.port_b.Q_flow + (TC_618_849.port_b.Q_flow + (AIR0CabiA008007007.port.Q_flow + (TC_849_850.port_a.Q_flow + (TC_849_860.port_a.Q_flow + (TC_849_970.port_a.Q_flow + TC_849_1044.port_a.Q_flow)))))) = 0.0; AIR0CabiA008007007.port.T = TC_618_849.port_b.T; AIR0CabiA008007007.port.T = TC_848_849.port_b.T; AIR0CabiA008007007.port.T = TC_849_1044.port_a.T; AIR0CabiA008007007.port.T = TC_849_850.port_a.T; AIR0CabiA008007007.port.T = TC_849_860.port_a.T; AIR0CabiA008007007.port.T = TC_849_970.port_a.T; AIR0CabiA008007007.port.T = TsAIR0CabiA008007007.port.T; TsAIR0CabiA007007007.port.Q_flow + (TC_847_848.port_b.Q_flow + (TC_617_848.port_b.Q_flow + (AIR0CabiA007007007.port.Q_flow + (TC_848_849.port_a.Q_flow + (TC_848_859.port_a.Q_flow + (TC_848_969.port_a.Q_flow + TC_848_1043.port_a.Q_flow)))))) = 0.0; AIR0CabiA007007007.port.T = TC_617_848.port_b.T; AIR0CabiA007007007.port.T = TC_847_848.port_b.T; AIR0CabiA007007007.port.T = TC_848_1043.port_a.T; AIR0CabiA007007007.port.T = TC_848_849.port_a.T; AIR0CabiA007007007.port.T = TC_848_859.port_a.T; AIR0CabiA007007007.port.T = TC_848_969.port_a.T; AIR0CabiA007007007.port.T = TsAIR0CabiA007007007.port.T; TsAIR0CabiA006007007.port.Q_flow + (TC_846_847.port_b.Q_flow + (TC_616_847.port_b.Q_flow + (AIR0CabiA006007007.port.Q_flow + (TC_847_848.port_a.Q_flow + (TC_847_858.port_a.Q_flow + (TC_847_968.port_a.Q_flow + TC_847_1042.port_a.Q_flow)))))) = 0.0; AIR0CabiA006007007.port.T = TC_616_847.port_b.T; AIR0CabiA006007007.port.T = TC_846_847.port_b.T; AIR0CabiA006007007.port.T = TC_847_1042.port_a.T; AIR0CabiA006007007.port.T = TC_847_848.port_a.T; AIR0CabiA006007007.port.T = TC_847_858.port_a.T; AIR0CabiA006007007.port.T = TC_847_968.port_a.T; AIR0CabiA006007007.port.T = TsAIR0CabiA006007007.port.T; TsAIR0CabiA005007007.port.Q_flow + (TC_845_846.port_b.Q_flow + (TC_615_846.port_b.Q_flow + (AIR0CabiA005007007.port.Q_flow + (TC_846_847.port_a.Q_flow + (TC_846_857.port_a.Q_flow + (TC_846_967.port_a.Q_flow + TC_846_1041.port_a.Q_flow)))))) = 0.0; AIR0CabiA005007007.port.T = TC_615_846.port_b.T; AIR0CabiA005007007.port.T = TC_845_846.port_b.T; AIR0CabiA005007007.port.T = TC_846_1041.port_a.T; AIR0CabiA005007007.port.T = TC_846_847.port_a.T; AIR0CabiA005007007.port.T = TC_846_857.port_a.T; AIR0CabiA005007007.port.T = TC_846_967.port_a.T; AIR0CabiA005007007.port.T = TsAIR0CabiA005007007.port.T; TsAIR0CabiA004007007.port.Q_flow + (TC_844_845.port_b.Q_flow + (TC_614_845.port_b.Q_flow + (AIR0CabiA004007007.port.Q_flow + (TC_845_846.port_a.Q_flow + (TC_845_856.port_a.Q_flow + (TC_845_966.port_a.Q_flow + TC_845_1040.port_a.Q_flow)))))) = 0.0; AIR0CabiA004007007.port.T = TC_614_845.port_b.T; AIR0CabiA004007007.port.T = TC_844_845.port_b.T; AIR0CabiA004007007.port.T = TC_845_1040.port_a.T; AIR0CabiA004007007.port.T = TC_845_846.port_a.T; AIR0CabiA004007007.port.T = TC_845_856.port_a.T; AIR0CabiA004007007.port.T = TC_845_966.port_a.T; AIR0CabiA004007007.port.T = TsAIR0CabiA004007007.port.T; TsAIR0CabiA003007007.port.Q_flow + (TC_843_844.port_b.Q_flow + (TC_613_844.port_b.Q_flow + (AIR0CabiA003007007.port.Q_flow + (TC_844_845.port_a.Q_flow + (TC_844_855.port_a.Q_flow + (TC_844_965.port_a.Q_flow + TC_844_1039.port_a.Q_flow)))))) = 0.0; AIR0CabiA003007007.port.T = TC_613_844.port_b.T; AIR0CabiA003007007.port.T = TC_843_844.port_b.T; AIR0CabiA003007007.port.T = TC_844_1039.port_a.T; AIR0CabiA003007007.port.T = TC_844_845.port_a.T; AIR0CabiA003007007.port.T = TC_844_855.port_a.T; AIR0CabiA003007007.port.T = TC_844_965.port_a.T; AIR0CabiA003007007.port.T = TsAIR0CabiA003007007.port.T; TsAIR0CabiA002007007.port.Q_flow + (TC_612_843.port_b.Q_flow + (TC_502_843.port_b.Q_flow + (AIR0CabiA002007007.port.Q_flow + (TC_843_844.port_a.Q_flow + (TC_843_854.port_a.Q_flow + (TC_843_964.port_a.Q_flow + TC_843_1038.port_a.Q_flow)))))) = 0.0; AIR0CabiA002007007.port.T = TC_502_843.port_b.T; AIR0CabiA002007007.port.T = TC_612_843.port_b.T; AIR0CabiA002007007.port.T = TC_843_1038.port_a.T; AIR0CabiA002007007.port.T = TC_843_844.port_a.T; AIR0CabiA002007007.port.T = TC_843_854.port_a.T; AIR0CabiA002007007.port.T = TC_843_964.port_a.T; AIR0CabiA002007007.port.T = TsAIR0CabiA002007007.port.T; TsAIR0CabiA012014007.port.Q_flow + (TC_841_842.port_b.Q_flow + (TC_831_842.port_b.Q_flow + (TC_713_842.port_b.Q_flow + (TC_517_842.port_b.Q_flow + (AIR0CabiA012014007.port.Q_flow + (TC_842_919.port_a.Q_flow + TC_842_1016.port_a.Q_flow)))))) = 0.0; AIR0CabiA012014007.port.T = TC_517_842.port_b.T; AIR0CabiA012014007.port.T = TC_713_842.port_b.T; AIR0CabiA012014007.port.T = TC_831_842.port_b.T; AIR0CabiA012014007.port.T = TC_841_842.port_b.T; AIR0CabiA012014007.port.T = TC_842_1016.port_a.T; AIR0CabiA012014007.port.T = TC_842_919.port_a.T; AIR0CabiA012014007.port.T = TsAIR0CabiA012014007.port.T; TsAIR0CabiA011014007.port.Q_flow + (TC_840_841.port_b.Q_flow + (TC_830_841.port_b.Q_flow + (TC_712_841.port_b.Q_flow + (AIR0CabiA011014007.port.Q_flow + (TC_841_842.port_a.Q_flow + (TC_841_918.port_a.Q_flow + TC_841_1015.port_a.Q_flow)))))) = 0.0; AIR0CabiA011014007.port.T = TC_712_841.port_b.T; AIR0CabiA011014007.port.T = TC_830_841.port_b.T; AIR0CabiA011014007.port.T = TC_840_841.port_b.T; AIR0CabiA011014007.port.T = TC_841_1015.port_a.T; AIR0CabiA011014007.port.T = TC_841_842.port_a.T; AIR0CabiA011014007.port.T = TC_841_918.port_a.T; AIR0CabiA011014007.port.T = TsAIR0CabiA011014007.port.T; TsAIR0CabiA010014007.port.Q_flow + (TC_839_840.port_b.Q_flow + (TC_829_840.port_b.Q_flow + (TC_711_840.port_b.Q_flow + (AIR0CabiA010014007.port.Q_flow + (TC_840_841.port_a.Q_flow + (TC_840_917.port_a.Q_flow + TC_840_1014.port_a.Q_flow)))))) = 0.0; AIR0CabiA010014007.port.T = TC_711_840.port_b.T; AIR0CabiA010014007.port.T = TC_829_840.port_b.T; AIR0CabiA010014007.port.T = TC_839_840.port_b.T; AIR0CabiA010014007.port.T = TC_840_1014.port_a.T; AIR0CabiA010014007.port.T = TC_840_841.port_a.T; AIR0CabiA010014007.port.T = TC_840_917.port_a.T; AIR0CabiA010014007.port.T = TsAIR0CabiA010014007.port.T; TsAIR0CabiA009014007.port.Q_flow + (TC_838_839.port_b.Q_flow + (TC_828_839.port_b.Q_flow + (TC_710_839.port_b.Q_flow + (AIR0CabiA009014007.port.Q_flow + (TC_839_840.port_a.Q_flow + (TC_839_916.port_a.Q_flow + TC_839_1013.port_a.Q_flow)))))) = 0.0; AIR0CabiA009014007.port.T = TC_710_839.port_b.T; AIR0CabiA009014007.port.T = TC_828_839.port_b.T; AIR0CabiA009014007.port.T = TC_838_839.port_b.T; AIR0CabiA009014007.port.T = TC_839_1013.port_a.T; AIR0CabiA009014007.port.T = TC_839_840.port_a.T; AIR0CabiA009014007.port.T = TC_839_916.port_a.T; AIR0CabiA009014007.port.T = TsAIR0CabiA009014007.port.T; TsAIR0CabiA008014007.port.Q_flow + (TC_837_838.port_b.Q_flow + (TC_827_838.port_b.Q_flow + (TC_709_838.port_b.Q_flow + (AIR0CabiA008014007.port.Q_flow + (TC_838_839.port_a.Q_flow + (TC_838_915.port_a.Q_flow + TC_838_1012.port_a.Q_flow)))))) = 0.0; AIR0CabiA008014007.port.T = TC_709_838.port_b.T; AIR0CabiA008014007.port.T = TC_827_838.port_b.T; AIR0CabiA008014007.port.T = TC_837_838.port_b.T; AIR0CabiA008014007.port.T = TC_838_1012.port_a.T; AIR0CabiA008014007.port.T = TC_838_839.port_a.T; AIR0CabiA008014007.port.T = TC_838_915.port_a.T; AIR0CabiA008014007.port.T = TsAIR0CabiA008014007.port.T; TsAIR0CabiA007014007.port.Q_flow + (TC_836_837.port_b.Q_flow + (TC_826_837.port_b.Q_flow + (TC_708_837.port_b.Q_flow + (AIR0CabiA007014007.port.Q_flow + (TC_837_838.port_a.Q_flow + (TC_837_914.port_a.Q_flow + TC_837_1011.port_a.Q_flow)))))) = 0.0; AIR0CabiA007014007.port.T = TC_708_837.port_b.T; AIR0CabiA007014007.port.T = TC_826_837.port_b.T; AIR0CabiA007014007.port.T = TC_836_837.port_b.T; AIR0CabiA007014007.port.T = TC_837_1011.port_a.T; AIR0CabiA007014007.port.T = TC_837_838.port_a.T; AIR0CabiA007014007.port.T = TC_837_914.port_a.T; AIR0CabiA007014007.port.T = TsAIR0CabiA007014007.port.T; TsAIR0CabiA006014007.port.Q_flow + (TC_835_836.port_b.Q_flow + (TC_825_836.port_b.Q_flow + (TC_707_836.port_b.Q_flow + (AIR0CabiA006014007.port.Q_flow + (TC_836_837.port_a.Q_flow + (TC_836_913.port_a.Q_flow + TC_836_1010.port_a.Q_flow)))))) = 0.0; AIR0CabiA006014007.port.T = TC_707_836.port_b.T; AIR0CabiA006014007.port.T = TC_825_836.port_b.T; AIR0CabiA006014007.port.T = TC_835_836.port_b.T; AIR0CabiA006014007.port.T = TC_836_1010.port_a.T; AIR0CabiA006014007.port.T = TC_836_837.port_a.T; AIR0CabiA006014007.port.T = TC_836_913.port_a.T; AIR0CabiA006014007.port.T = TsAIR0CabiA006014007.port.T; TsAIR0CabiA005014007.port.Q_flow + (TC_834_835.port_b.Q_flow + (TC_824_835.port_b.Q_flow + (TC_706_835.port_b.Q_flow + (AIR0CabiA005014007.port.Q_flow + (TC_835_836.port_a.Q_flow + (TC_835_912.port_a.Q_flow + TC_835_1009.port_a.Q_flow)))))) = 0.0; AIR0CabiA005014007.port.T = TC_706_835.port_b.T; AIR0CabiA005014007.port.T = TC_824_835.port_b.T; AIR0CabiA005014007.port.T = TC_834_835.port_b.T; AIR0CabiA005014007.port.T = TC_835_1009.port_a.T; AIR0CabiA005014007.port.T = TC_835_836.port_a.T; AIR0CabiA005014007.port.T = TC_835_912.port_a.T; AIR0CabiA005014007.port.T = TsAIR0CabiA005014007.port.T; TsAIR0CabiA004014007.port.Q_flow + (TC_833_834.port_b.Q_flow + (TC_823_834.port_b.Q_flow + (TC_705_834.port_b.Q_flow + (AIR0CabiA004014007.port.Q_flow + (TC_834_835.port_a.Q_flow + (TC_834_911.port_a.Q_flow + TC_834_1008.port_a.Q_flow)))))) = 0.0; AIR0CabiA004014007.port.T = TC_705_834.port_b.T; AIR0CabiA004014007.port.T = TC_823_834.port_b.T; AIR0CabiA004014007.port.T = TC_833_834.port_b.T; AIR0CabiA004014007.port.T = TC_834_1008.port_a.T; AIR0CabiA004014007.port.T = TC_834_835.port_a.T; AIR0CabiA004014007.port.T = TC_834_911.port_a.T; AIR0CabiA004014007.port.T = TsAIR0CabiA004014007.port.T; TsAIR0CabiA003014007.port.Q_flow + (TC_832_833.port_b.Q_flow + (TC_822_833.port_b.Q_flow + (TC_704_833.port_b.Q_flow + (AIR0CabiA003014007.port.Q_flow + (TC_833_834.port_a.Q_flow + (TC_833_910.port_a.Q_flow + TC_833_1007.port_a.Q_flow)))))) = 0.0; AIR0CabiA003014007.port.T = TC_704_833.port_b.T; AIR0CabiA003014007.port.T = TC_822_833.port_b.T; AIR0CabiA003014007.port.T = TC_832_833.port_b.T; AIR0CabiA003014007.port.T = TC_833_1007.port_a.T; AIR0CabiA003014007.port.T = TC_833_834.port_a.T; AIR0CabiA003014007.port.T = TC_833_910.port_a.T; AIR0CabiA003014007.port.T = TsAIR0CabiA003014007.port.T; TsAIR0CabiA002014007.port.Q_flow + (TC_821_832.port_b.Q_flow + (TC_703_832.port_b.Q_flow + (TC_516_832.port_b.Q_flow + (AIR0CabiA002014007.port.Q_flow + (TC_832_833.port_a.Q_flow + (TC_832_909.port_a.Q_flow + TC_832_1006.port_a.Q_flow)))))) = 0.0; AIR0CabiA002014007.port.T = TC_516_832.port_b.T; AIR0CabiA002014007.port.T = TC_703_832.port_b.T; AIR0CabiA002014007.port.T = TC_821_832.port_b.T; AIR0CabiA002014007.port.T = TC_832_1006.port_a.T; AIR0CabiA002014007.port.T = TC_832_833.port_a.T; AIR0CabiA002014007.port.T = TC_832_909.port_a.T; AIR0CabiA002014007.port.T = TsAIR0CabiA002014007.port.T; TsAIR0CabiA012015007.port.Q_flow + (TC_830_831.port_b.Q_flow + (TC_726_831.port_b.Q_flow + (TC_531_831.port_b.Q_flow + (TC_519_831.port_b.Q_flow + (AIR0CabiA012015007.port.Q_flow + (TC_831_842.port_a.Q_flow + TC_831_1027.port_a.Q_flow)))))) = 0.0; AIR0CabiA012015007.port.T = TC_519_831.port_b.T; AIR0CabiA012015007.port.T = TC_531_831.port_b.T; AIR0CabiA012015007.port.T = TC_726_831.port_b.T; AIR0CabiA012015007.port.T = TC_830_831.port_b.T; AIR0CabiA012015007.port.T = TC_831_1027.port_a.T; AIR0CabiA012015007.port.T = TC_831_842.port_a.T; AIR0CabiA012015007.port.T = TsAIR0CabiA012015007.port.T; TsAIR0CabiA011015007.port.Q_flow + (TC_829_830.port_b.Q_flow + (TC_725_830.port_b.Q_flow + (TC_530_830.port_b.Q_flow + (AIR0CabiA011015007.port.Q_flow + (TC_830_831.port_a.Q_flow + (TC_830_841.port_a.Q_flow + TC_830_1026.port_a.Q_flow)))))) = 0.0; AIR0CabiA011015007.port.T = TC_530_830.port_b.T; AIR0CabiA011015007.port.T = TC_725_830.port_b.T; AIR0CabiA011015007.port.T = TC_829_830.port_b.T; AIR0CabiA011015007.port.T = TC_830_1026.port_a.T; AIR0CabiA011015007.port.T = TC_830_831.port_a.T; AIR0CabiA011015007.port.T = TC_830_841.port_a.T; AIR0CabiA011015007.port.T = TsAIR0CabiA011015007.port.T; TsAIR0CabiA010015007.port.Q_flow + (TC_828_829.port_b.Q_flow + (TC_724_829.port_b.Q_flow + (TC_529_829.port_b.Q_flow + (AIR0CabiA010015007.port.Q_flow + (TC_829_830.port_a.Q_flow + (TC_829_840.port_a.Q_flow + TC_829_1025.port_a.Q_flow)))))) = 0.0; AIR0CabiA010015007.port.T = TC_529_829.port_b.T; AIR0CabiA010015007.port.T = TC_724_829.port_b.T; AIR0CabiA010015007.port.T = TC_828_829.port_b.T; AIR0CabiA010015007.port.T = TC_829_1025.port_a.T; AIR0CabiA010015007.port.T = TC_829_830.port_a.T; AIR0CabiA010015007.port.T = TC_829_840.port_a.T; AIR0CabiA010015007.port.T = TsAIR0CabiA010015007.port.T; TsAIR0CabiA009015007.port.Q_flow + (TC_827_828.port_b.Q_flow + (TC_723_828.port_b.Q_flow + (TC_528_828.port_b.Q_flow + (AIR0CabiA009015007.port.Q_flow + (TC_828_829.port_a.Q_flow + (TC_828_839.port_a.Q_flow + TC_828_1024.port_a.Q_flow)))))) = 0.0; AIR0CabiA009015007.port.T = TC_528_828.port_b.T; AIR0CabiA009015007.port.T = TC_723_828.port_b.T; AIR0CabiA009015007.port.T = TC_827_828.port_b.T; AIR0CabiA009015007.port.T = TC_828_1024.port_a.T; AIR0CabiA009015007.port.T = TC_828_829.port_a.T; AIR0CabiA009015007.port.T = TC_828_839.port_a.T; AIR0CabiA009015007.port.T = TsAIR0CabiA009015007.port.T; TsAIR0CabiA008015007.port.Q_flow + (TC_826_827.port_b.Q_flow + (TC_722_827.port_b.Q_flow + (TC_527_827.port_b.Q_flow + (AIR0CabiA008015007.port.Q_flow + (TC_827_828.port_a.Q_flow + (TC_827_838.port_a.Q_flow + TC_827_1023.port_a.Q_flow)))))) = 0.0; AIR0CabiA008015007.port.T = TC_527_827.port_b.T; AIR0CabiA008015007.port.T = TC_722_827.port_b.T; AIR0CabiA008015007.port.T = TC_826_827.port_b.T; AIR0CabiA008015007.port.T = TC_827_1023.port_a.T; AIR0CabiA008015007.port.T = TC_827_828.port_a.T; AIR0CabiA008015007.port.T = TC_827_838.port_a.T; AIR0CabiA008015007.port.T = TsAIR0CabiA008015007.port.T; TsAIR0CabiA007015007.port.Q_flow + (TC_825_826.port_b.Q_flow + (TC_721_826.port_b.Q_flow + (TC_526_826.port_b.Q_flow + (AIR0CabiA007015007.port.Q_flow + (TC_826_827.port_a.Q_flow + (TC_826_837.port_a.Q_flow + TC_826_1022.port_a.Q_flow)))))) = 0.0; AIR0CabiA007015007.port.T = TC_526_826.port_b.T; AIR0CabiA007015007.port.T = TC_721_826.port_b.T; AIR0CabiA007015007.port.T = TC_825_826.port_b.T; AIR0CabiA007015007.port.T = TC_826_1022.port_a.T; AIR0CabiA007015007.port.T = TC_826_827.port_a.T; AIR0CabiA007015007.port.T = TC_826_837.port_a.T; AIR0CabiA007015007.port.T = TsAIR0CabiA007015007.port.T; TsAIR0CabiA006015007.port.Q_flow + (TC_824_825.port_b.Q_flow + (TC_720_825.port_b.Q_flow + (TC_525_825.port_b.Q_flow + (AIR0CabiA006015007.port.Q_flow + (TC_825_826.port_a.Q_flow + (TC_825_836.port_a.Q_flow + TC_825_1021.port_a.Q_flow)))))) = 0.0; AIR0CabiA006015007.port.T = TC_525_825.port_b.T; AIR0CabiA006015007.port.T = TC_720_825.port_b.T; AIR0CabiA006015007.port.T = TC_824_825.port_b.T; AIR0CabiA006015007.port.T = TC_825_1021.port_a.T; AIR0CabiA006015007.port.T = TC_825_826.port_a.T; AIR0CabiA006015007.port.T = TC_825_836.port_a.T; AIR0CabiA006015007.port.T = TsAIR0CabiA006015007.port.T; TsAIR0CabiA005015007.port.Q_flow + (TC_823_824.port_b.Q_flow + (TC_719_824.port_b.Q_flow + (TC_524_824.port_b.Q_flow + (AIR0CabiA005015007.port.Q_flow + (TC_824_825.port_a.Q_flow + (TC_824_835.port_a.Q_flow + TC_824_1020.port_a.Q_flow)))))) = 0.0; AIR0CabiA005015007.port.T = TC_524_824.port_b.T; AIR0CabiA005015007.port.T = TC_719_824.port_b.T; AIR0CabiA005015007.port.T = TC_823_824.port_b.T; AIR0CabiA005015007.port.T = TC_824_1020.port_a.T; AIR0CabiA005015007.port.T = TC_824_825.port_a.T; AIR0CabiA005015007.port.T = TC_824_835.port_a.T; AIR0CabiA005015007.port.T = TsAIR0CabiA005015007.port.T; TsAIR0CabiA004015007.port.Q_flow + (TC_822_823.port_b.Q_flow + (TC_718_823.port_b.Q_flow + (TC_523_823.port_b.Q_flow + (AIR0CabiA004015007.port.Q_flow + (TC_823_824.port_a.Q_flow + (TC_823_834.port_a.Q_flow + TC_823_1019.port_a.Q_flow)))))) = 0.0; AIR0CabiA004015007.port.T = TC_523_823.port_b.T; AIR0CabiA004015007.port.T = TC_718_823.port_b.T; AIR0CabiA004015007.port.T = TC_822_823.port_b.T; AIR0CabiA004015007.port.T = TC_823_1019.port_a.T; AIR0CabiA004015007.port.T = TC_823_824.port_a.T; AIR0CabiA004015007.port.T = TC_823_834.port_a.T; AIR0CabiA004015007.port.T = TsAIR0CabiA004015007.port.T; TsAIR0CabiA003015007.port.Q_flow + (TC_821_822.port_b.Q_flow + (TC_717_822.port_b.Q_flow + (TC_522_822.port_b.Q_flow + (AIR0CabiA003015007.port.Q_flow + (TC_822_823.port_a.Q_flow + (TC_822_833.port_a.Q_flow + TC_822_1018.port_a.Q_flow)))))) = 0.0; AIR0CabiA003015007.port.T = TC_522_822.port_b.T; AIR0CabiA003015007.port.T = TC_717_822.port_b.T; AIR0CabiA003015007.port.T = TC_821_822.port_b.T; AIR0CabiA003015007.port.T = TC_822_1018.port_a.T; AIR0CabiA003015007.port.T = TC_822_823.port_a.T; AIR0CabiA003015007.port.T = TC_822_833.port_a.T; AIR0CabiA003015007.port.T = TsAIR0CabiA003015007.port.T; TsAIR0CabiA002015007.port.Q_flow + (TC_716_821.port_b.Q_flow + (TC_521_821.port_b.Q_flow + (TC_518_821.port_b.Q_flow + (AIR0CabiA002015007.port.Q_flow + (TC_821_822.port_a.Q_flow + (TC_821_832.port_a.Q_flow + TC_821_1017.port_a.Q_flow)))))) = 0.0; AIR0CabiA002015007.port.T = TC_518_821.port_b.T; AIR0CabiA002015007.port.T = TC_521_821.port_b.T; AIR0CabiA002015007.port.T = TC_716_821.port_b.T; AIR0CabiA002015007.port.T = TC_821_1017.port_a.T; AIR0CabiA002015007.port.T = TC_821_822.port_a.T; AIR0CabiA002015007.port.T = TC_821_832.port_a.T; AIR0CabiA002015007.port.T = TsAIR0CabiA002015007.port.T; TsGS0CabiA011004002.port.Q_flow + (TC_819_820.port_b.Q_flow + (TC_748_820.port_b.Q_flow + (TC_50_820.port_b.Q_flow + (GS0CabiA011004002.port.Q_flow + (TC_820_1300.port_a.Q_flow + (TC_820_1463.port_a.Q_flow + TC_820_1475.port_a.Q_flow)))))) = 0.0; GS0CabiA011004002.port.T = TC_50_820.port_b.T; GS0CabiA011004002.port.T = TC_748_820.port_b.T; GS0CabiA011004002.port.T = TC_819_820.port_b.T; GS0CabiA011004002.port.T = TC_820_1300.port_a.T; GS0CabiA011004002.port.T = TC_820_1463.port_a.T; GS0CabiA011004002.port.T = TC_820_1475.port_a.T; GS0CabiA011004002.port.T = TsGS0CabiA011004002.port.T; TsGS0CabiA010004002.port.Q_flow + (TC_818_819.port_b.Q_flow + (TC_747_819.port_b.Q_flow + (TC_49_819.port_b.Q_flow + (GS0CabiA010004002.port.Q_flow + (TC_819_820.port_a.Q_flow + (TC_819_1299.port_a.Q_flow + TC_819_1474.port_a.Q_flow)))))) = 0.0; GS0CabiA010004002.port.T = TC_49_819.port_b.T; GS0CabiA010004002.port.T = TC_747_819.port_b.T; GS0CabiA010004002.port.T = TC_818_819.port_b.T; GS0CabiA010004002.port.T = TC_819_1299.port_a.T; GS0CabiA010004002.port.T = TC_819_1474.port_a.T; GS0CabiA010004002.port.T = TC_819_820.port_a.T; GS0CabiA010004002.port.T = TsGS0CabiA010004002.port.T; TsGS0CabiA009004002.port.Q_flow + (TC_817_818.port_b.Q_flow + (TC_746_818.port_b.Q_flow + (TC_48_818.port_b.Q_flow + (GS0CabiA009004002.port.Q_flow + (TC_818_819.port_a.Q_flow + (TC_818_1298.port_a.Q_flow + TC_818_1473.port_a.Q_flow)))))) = 0.0; GS0CabiA009004002.port.T = TC_48_818.port_b.T; GS0CabiA009004002.port.T = TC_746_818.port_b.T; GS0CabiA009004002.port.T = TC_817_818.port_b.T; GS0CabiA009004002.port.T = TC_818_1298.port_a.T; GS0CabiA009004002.port.T = TC_818_1473.port_a.T; GS0CabiA009004002.port.T = TC_818_819.port_a.T; GS0CabiA009004002.port.T = TsGS0CabiA009004002.port.T; TsGS0CabiA008004002.port.Q_flow + (TC_816_817.port_b.Q_flow + (TC_745_817.port_b.Q_flow + (TC_47_817.port_b.Q_flow + (GS0CabiA008004002.port.Q_flow + (TC_817_818.port_a.Q_flow + (TC_817_1297.port_a.Q_flow + TC_817_1472.port_a.Q_flow)))))) = 0.0; GS0CabiA008004002.port.T = TC_47_817.port_b.T; GS0CabiA008004002.port.T = TC_745_817.port_b.T; GS0CabiA008004002.port.T = TC_816_817.port_b.T; GS0CabiA008004002.port.T = TC_817_1297.port_a.T; GS0CabiA008004002.port.T = TC_817_1472.port_a.T; GS0CabiA008004002.port.T = TC_817_818.port_a.T; GS0CabiA008004002.port.T = TsGS0CabiA008004002.port.T; TsGS0CabiA007004002.port.Q_flow + (TC_815_816.port_b.Q_flow + (TC_744_816.port_b.Q_flow + (TC_46_816.port_b.Q_flow + (GS0CabiA007004002.port.Q_flow + (TC_816_817.port_a.Q_flow + (TC_816_1296.port_a.Q_flow + TC_816_1471.port_a.Q_flow)))))) = 0.0; GS0CabiA007004002.port.T = TC_46_816.port_b.T; GS0CabiA007004002.port.T = TC_744_816.port_b.T; GS0CabiA007004002.port.T = TC_815_816.port_b.T; GS0CabiA007004002.port.T = TC_816_1296.port_a.T; GS0CabiA007004002.port.T = TC_816_1471.port_a.T; GS0CabiA007004002.port.T = TC_816_817.port_a.T; GS0CabiA007004002.port.T = TsGS0CabiA007004002.port.T; TsGS0CabiA006004002.port.Q_flow + (TC_814_815.port_b.Q_flow + (TC_743_815.port_b.Q_flow + (TC_45_815.port_b.Q_flow + (GS0CabiA006004002.port.Q_flow + (TC_815_816.port_a.Q_flow + (TC_815_1295.port_a.Q_flow + TC_815_1470.port_a.Q_flow)))))) = 0.0; GS0CabiA006004002.port.T = TC_45_815.port_b.T; GS0CabiA006004002.port.T = TC_743_815.port_b.T; GS0CabiA006004002.port.T = TC_814_815.port_b.T; GS0CabiA006004002.port.T = TC_815_1295.port_a.T; GS0CabiA006004002.port.T = TC_815_1470.port_a.T; GS0CabiA006004002.port.T = TC_815_816.port_a.T; GS0CabiA006004002.port.T = TsGS0CabiA006004002.port.T; TsGS0CabiA005004002.port.Q_flow + (TC_813_814.port_b.Q_flow + (TC_742_814.port_b.Q_flow + (TC_44_814.port_b.Q_flow + (GS0CabiA005004002.port.Q_flow + (TC_814_815.port_a.Q_flow + (TC_814_1294.port_a.Q_flow + TC_814_1469.port_a.Q_flow)))))) = 0.0; GS0CabiA005004002.port.T = TC_44_814.port_b.T; GS0CabiA005004002.port.T = TC_742_814.port_b.T; GS0CabiA005004002.port.T = TC_813_814.port_b.T; GS0CabiA005004002.port.T = TC_814_1294.port_a.T; GS0CabiA005004002.port.T = TC_814_1469.port_a.T; GS0CabiA005004002.port.T = TC_814_815.port_a.T; GS0CabiA005004002.port.T = TsGS0CabiA005004002.port.T; TsGS0CabiA004004002.port.Q_flow + (TC_741_813.port_b.Q_flow + (TC_43_813.port_b.Q_flow + (GS0CabiA004004002.port.Q_flow + (TC_813_814.port_a.Q_flow + (TC_813_1293.port_a.Q_flow + (TC_813_1462.port_a.Q_flow + TC_813_1468.port_a.Q_flow)))))) = 0.0; GS0CabiA004004002.port.T = TC_43_813.port_b.T; GS0CabiA004004002.port.T = TC_741_813.port_b.T; GS0CabiA004004002.port.T = TC_813_1293.port_a.T; GS0CabiA004004002.port.T = TC_813_1462.port_a.T; GS0CabiA004004002.port.T = TC_813_1468.port_a.T; GS0CabiA004004002.port.T = TC_813_814.port_a.T; GS0CabiA004004002.port.T = TsGS0CabiA004004002.port.T; TsGS0CabiA011013002.port.Q_flow + (TC_811_812.port_b.Q_flow + (TC_804_812.port_b.Q_flow + (TC_167_812.port_b.Q_flow + (GS0CabiA011013002.port.Q_flow + (TC_812_1390.port_a.Q_flow + (TC_812_1438.port_a.Q_flow + TC_812_1448.port_a.Q_flow)))))) = 0.0; GS0CabiA011013002.port.T = TC_167_812.port_b.T; GS0CabiA011013002.port.T = TC_804_812.port_b.T; GS0CabiA011013002.port.T = TC_811_812.port_b.T; GS0CabiA011013002.port.T = TC_812_1390.port_a.T; GS0CabiA011013002.port.T = TC_812_1438.port_a.T; GS0CabiA011013002.port.T = TC_812_1448.port_a.T; GS0CabiA011013002.port.T = TsGS0CabiA011013002.port.T; TsGS0CabiA010013002.port.Q_flow + (TC_810_811.port_b.Q_flow + (TC_803_811.port_b.Q_flow + (TC_166_811.port_b.Q_flow + (GS0CabiA010013002.port.Q_flow + (TC_811_812.port_a.Q_flow + (TC_811_1389.port_a.Q_flow + TC_811_1447.port_a.Q_flow)))))) = 0.0; GS0CabiA010013002.port.T = TC_166_811.port_b.T; GS0CabiA010013002.port.T = TC_803_811.port_b.T; GS0CabiA010013002.port.T = TC_810_811.port_b.T; GS0CabiA010013002.port.T = TC_811_1389.port_a.T; GS0CabiA010013002.port.T = TC_811_1447.port_a.T; GS0CabiA010013002.port.T = TC_811_812.port_a.T; GS0CabiA010013002.port.T = TsGS0CabiA010013002.port.T; TsGS0CabiA009013002.port.Q_flow + (TC_809_810.port_b.Q_flow + (TC_802_810.port_b.Q_flow + (TC_165_810.port_b.Q_flow + (GS0CabiA009013002.port.Q_flow + (TC_810_811.port_a.Q_flow + (TC_810_1388.port_a.Q_flow + TC_810_1446.port_a.Q_flow)))))) = 0.0; GS0CabiA009013002.port.T = TC_165_810.port_b.T; GS0CabiA009013002.port.T = TC_802_810.port_b.T; GS0CabiA009013002.port.T = TC_809_810.port_b.T; GS0CabiA009013002.port.T = TC_810_1388.port_a.T; GS0CabiA009013002.port.T = TC_810_1446.port_a.T; GS0CabiA009013002.port.T = TC_810_811.port_a.T; GS0CabiA009013002.port.T = TsGS0CabiA009013002.port.T; TsGS0CabiA008013002.port.Q_flow + (TC_808_809.port_b.Q_flow + (TC_801_809.port_b.Q_flow + (TC_164_809.port_b.Q_flow + (GS0CabiA008013002.port.Q_flow + (TC_809_810.port_a.Q_flow + (TC_809_1387.port_a.Q_flow + TC_809_1445.port_a.Q_flow)))))) = 0.0; GS0CabiA008013002.port.T = TC_164_809.port_b.T; GS0CabiA008013002.port.T = TC_801_809.port_b.T; GS0CabiA008013002.port.T = TC_808_809.port_b.T; GS0CabiA008013002.port.T = TC_809_1387.port_a.T; GS0CabiA008013002.port.T = TC_809_1445.port_a.T; GS0CabiA008013002.port.T = TC_809_810.port_a.T; GS0CabiA008013002.port.T = TsGS0CabiA008013002.port.T; TsGS0CabiA007013002.port.Q_flow + (TC_807_808.port_b.Q_flow + (TC_800_808.port_b.Q_flow + (TC_163_808.port_b.Q_flow + (GS0CabiA007013002.port.Q_flow + (TC_808_809.port_a.Q_flow + (TC_808_1386.port_a.Q_flow + TC_808_1444.port_a.Q_flow)))))) = 0.0; GS0CabiA007013002.port.T = TC_163_808.port_b.T; GS0CabiA007013002.port.T = TC_800_808.port_b.T; GS0CabiA007013002.port.T = TC_807_808.port_b.T; GS0CabiA007013002.port.T = TC_808_1386.port_a.T; GS0CabiA007013002.port.T = TC_808_1444.port_a.T; GS0CabiA007013002.port.T = TC_808_809.port_a.T; GS0CabiA007013002.port.T = TsGS0CabiA007013002.port.T; TsGS0CabiA006013002.port.Q_flow + (TC_806_807.port_b.Q_flow + (TC_799_807.port_b.Q_flow + (TC_162_807.port_b.Q_flow + (GS0CabiA006013002.port.Q_flow + (TC_807_808.port_a.Q_flow + (TC_807_1385.port_a.Q_flow + TC_807_1443.port_a.Q_flow)))))) = 0.0; GS0CabiA006013002.port.T = TC_162_807.port_b.T; GS0CabiA006013002.port.T = TC_799_807.port_b.T; GS0CabiA006013002.port.T = TC_806_807.port_b.T; GS0CabiA006013002.port.T = TC_807_1385.port_a.T; GS0CabiA006013002.port.T = TC_807_1443.port_a.T; GS0CabiA006013002.port.T = TC_807_808.port_a.T; GS0CabiA006013002.port.T = TsGS0CabiA006013002.port.T; TsGS0CabiA005013002.port.Q_flow + (TC_805_806.port_b.Q_flow + (TC_798_806.port_b.Q_flow + (TC_161_806.port_b.Q_flow + (GS0CabiA005013002.port.Q_flow + (TC_806_807.port_a.Q_flow + (TC_806_1384.port_a.Q_flow + TC_806_1442.port_a.Q_flow)))))) = 0.0; GS0CabiA005013002.port.T = TC_161_806.port_b.T; GS0CabiA005013002.port.T = TC_798_806.port_b.T; GS0CabiA005013002.port.T = TC_805_806.port_b.T; GS0CabiA005013002.port.T = TC_806_1384.port_a.T; GS0CabiA005013002.port.T = TC_806_1442.port_a.T; GS0CabiA005013002.port.T = TC_806_807.port_a.T; GS0CabiA005013002.port.T = TsGS0CabiA005013002.port.T; TsGS0CabiA004013002.port.Q_flow + (TC_797_805.port_b.Q_flow + (TC_160_805.port_b.Q_flow + (GS0CabiA004013002.port.Q_flow + (TC_805_806.port_a.Q_flow + (TC_805_1383.port_a.Q_flow + (TC_805_1437.port_a.Q_flow + TC_805_1441.port_a.Q_flow)))))) = 0.0; GS0CabiA004013002.port.T = TC_160_805.port_b.T; GS0CabiA004013002.port.T = TC_797_805.port_b.T; GS0CabiA004013002.port.T = TC_805_1383.port_a.T; GS0CabiA004013002.port.T = TC_805_1437.port_a.T; GS0CabiA004013002.port.T = TC_805_1441.port_a.T; GS0CabiA004013002.port.T = TC_805_806.port_a.T; GS0CabiA004013002.port.T = TsGS0CabiA004013002.port.T; TsGS0CabiA011012002.port.Q_flow + (TC_803_804.port_b.Q_flow + (TC_796_804.port_b.Q_flow + (TC_154_804.port_b.Q_flow + (GS0CabiA011012002.port.Q_flow + (TC_804_812.port_a.Q_flow + (TC_804_1379.port_a.Q_flow + TC_804_1435.port_a.Q_flow)))))) = 0.0; GS0CabiA011012002.port.T = TC_154_804.port_b.T; GS0CabiA011012002.port.T = TC_796_804.port_b.T; GS0CabiA011012002.port.T = TC_803_804.port_b.T; GS0CabiA011012002.port.T = TC_804_1379.port_a.T; GS0CabiA011012002.port.T = TC_804_1435.port_a.T; GS0CabiA011012002.port.T = TC_804_812.port_a.T; GS0CabiA011012002.port.T = TsGS0CabiA011012002.port.T; TsGS0CabiA010012002.port.Q_flow + (TC_802_803.port_b.Q_flow + (TC_795_803.port_b.Q_flow + (TC_153_803.port_b.Q_flow + (GS0CabiA010012002.port.Q_flow + (TC_803_804.port_a.Q_flow + (TC_803_811.port_a.Q_flow + TC_803_1378.port_a.Q_flow)))))) = 0.0; GS0CabiA010012002.port.T = TC_153_803.port_b.T; GS0CabiA010012002.port.T = TC_795_803.port_b.T; GS0CabiA010012002.port.T = TC_802_803.port_b.T; GS0CabiA010012002.port.T = TC_803_1378.port_a.T; GS0CabiA010012002.port.T = TC_803_804.port_a.T; GS0CabiA010012002.port.T = TC_803_811.port_a.T; GS0CabiA010012002.port.T = TsGS0CabiA010012002.port.T; TsGS0CabiA009012002.port.Q_flow + (TC_801_802.port_b.Q_flow + (TC_794_802.port_b.Q_flow + (TC_152_802.port_b.Q_flow + (GS0CabiA009012002.port.Q_flow + (TC_802_803.port_a.Q_flow + (TC_802_810.port_a.Q_flow + TC_802_1377.port_a.Q_flow)))))) = 0.0; GS0CabiA009012002.port.T = TC_152_802.port_b.T; GS0CabiA009012002.port.T = TC_794_802.port_b.T; GS0CabiA009012002.port.T = TC_801_802.port_b.T; GS0CabiA009012002.port.T = TC_802_1377.port_a.T; GS0CabiA009012002.port.T = TC_802_803.port_a.T; GS0CabiA009012002.port.T = TC_802_810.port_a.T; GS0CabiA009012002.port.T = TsGS0CabiA009012002.port.T; TsGS0CabiA008012002.port.Q_flow + (TC_800_801.port_b.Q_flow + (TC_793_801.port_b.Q_flow + (TC_151_801.port_b.Q_flow + (GS0CabiA008012002.port.Q_flow + (TC_801_802.port_a.Q_flow + (TC_801_809.port_a.Q_flow + TC_801_1376.port_a.Q_flow)))))) = 0.0; GS0CabiA008012002.port.T = TC_151_801.port_b.T; GS0CabiA008012002.port.T = TC_793_801.port_b.T; GS0CabiA008012002.port.T = TC_800_801.port_b.T; GS0CabiA008012002.port.T = TC_801_1376.port_a.T; GS0CabiA008012002.port.T = TC_801_802.port_a.T; GS0CabiA008012002.port.T = TC_801_809.port_a.T; GS0CabiA008012002.port.T = TsGS0CabiA008012002.port.T; TsGS0CabiA007012002.port.Q_flow + (TC_799_800.port_b.Q_flow + (TC_792_800.port_b.Q_flow + (TC_150_800.port_b.Q_flow + (GS0CabiA007012002.port.Q_flow + (TC_800_801.port_a.Q_flow + (TC_800_808.port_a.Q_flow + TC_800_1375.port_a.Q_flow)))))) = 0.0; GS0CabiA007012002.port.T = TC_150_800.port_b.T; GS0CabiA007012002.port.T = TC_792_800.port_b.T; GS0CabiA007012002.port.T = TC_799_800.port_b.T; GS0CabiA007012002.port.T = TC_800_1375.port_a.T; GS0CabiA007012002.port.T = TC_800_801.port_a.T; GS0CabiA007012002.port.T = TC_800_808.port_a.T; GS0CabiA007012002.port.T = TsGS0CabiA007012002.port.T; TsGS0CabiA006012002.port.Q_flow + (TC_798_799.port_b.Q_flow + (TC_791_799.port_b.Q_flow + (TC_149_799.port_b.Q_flow + (GS0CabiA006012002.port.Q_flow + (TC_799_800.port_a.Q_flow + (TC_799_807.port_a.Q_flow + TC_799_1374.port_a.Q_flow)))))) = 0.0; GS0CabiA006012002.port.T = TC_149_799.port_b.T; GS0CabiA006012002.port.T = TC_791_799.port_b.T; GS0CabiA006012002.port.T = TC_798_799.port_b.T; GS0CabiA006012002.port.T = TC_799_1374.port_a.T; GS0CabiA006012002.port.T = TC_799_800.port_a.T; GS0CabiA006012002.port.T = TC_799_807.port_a.T; GS0CabiA006012002.port.T = TsGS0CabiA006012002.port.T; TsGS0CabiA005012002.port.Q_flow + (TC_797_798.port_b.Q_flow + (TC_790_798.port_b.Q_flow + (TC_148_798.port_b.Q_flow + (GS0CabiA005012002.port.Q_flow + (TC_798_799.port_a.Q_flow + (TC_798_806.port_a.Q_flow + TC_798_1373.port_a.Q_flow)))))) = 0.0; GS0CabiA005012002.port.T = TC_148_798.port_b.T; GS0CabiA005012002.port.T = TC_790_798.port_b.T; GS0CabiA005012002.port.T = TC_797_798.port_b.T; GS0CabiA005012002.port.T = TC_798_1373.port_a.T; GS0CabiA005012002.port.T = TC_798_799.port_a.T; GS0CabiA005012002.port.T = TC_798_806.port_a.T; GS0CabiA005012002.port.T = TsGS0CabiA005012002.port.T; TsGS0CabiA004012002.port.Q_flow + (TC_789_797.port_b.Q_flow + (TC_147_797.port_b.Q_flow + (GS0CabiA004012002.port.Q_flow + (TC_797_798.port_a.Q_flow + (TC_797_805.port_a.Q_flow + (TC_797_1372.port_a.Q_flow + TC_797_1434.port_a.Q_flow)))))) = 0.0; GS0CabiA004012002.port.T = TC_147_797.port_b.T; GS0CabiA004012002.port.T = TC_789_797.port_b.T; GS0CabiA004012002.port.T = TC_797_1372.port_a.T; GS0CabiA004012002.port.T = TC_797_1434.port_a.T; GS0CabiA004012002.port.T = TC_797_798.port_a.T; GS0CabiA004012002.port.T = TC_797_805.port_a.T; GS0CabiA004012002.port.T = TsGS0CabiA004012002.port.T; TsGS0CabiA011011002.port.Q_flow + (TC_795_796.port_b.Q_flow + (TC_788_796.port_b.Q_flow + (TC_141_796.port_b.Q_flow + (GS0CabiA011011002.port.Q_flow + (TC_796_804.port_a.Q_flow + (TC_796_1368.port_a.Q_flow + TC_796_1432.port_a.Q_flow)))))) = 0.0; GS0CabiA011011002.port.T = TC_141_796.port_b.T; GS0CabiA011011002.port.T = TC_788_796.port_b.T; GS0CabiA011011002.port.T = TC_795_796.port_b.T; GS0CabiA011011002.port.T = TC_796_1368.port_a.T; GS0CabiA011011002.port.T = TC_796_1432.port_a.T; GS0CabiA011011002.port.T = TC_796_804.port_a.T; GS0CabiA011011002.port.T = TsGS0CabiA011011002.port.T; TsGS0CabiA010011002.port.Q_flow + (TC_794_795.port_b.Q_flow + (TC_787_795.port_b.Q_flow + (TC_140_795.port_b.Q_flow + (GS0CabiA010011002.port.Q_flow + (TC_795_796.port_a.Q_flow + (TC_795_803.port_a.Q_flow + TC_795_1367.port_a.Q_flow)))))) = 0.0; GS0CabiA010011002.port.T = TC_140_795.port_b.T; GS0CabiA010011002.port.T = TC_787_795.port_b.T; GS0CabiA010011002.port.T = TC_794_795.port_b.T; GS0CabiA010011002.port.T = TC_795_1367.port_a.T; GS0CabiA010011002.port.T = TC_795_796.port_a.T; GS0CabiA010011002.port.T = TC_795_803.port_a.T; GS0CabiA010011002.port.T = TsGS0CabiA010011002.port.T; TsGS0CabiA009011002.port.Q_flow + (TC_793_794.port_b.Q_flow + (TC_786_794.port_b.Q_flow + (TC_139_794.port_b.Q_flow + (GS0CabiA009011002.port.Q_flow + (TC_794_795.port_a.Q_flow + (TC_794_802.port_a.Q_flow + TC_794_1366.port_a.Q_flow)))))) = 0.0; GS0CabiA009011002.port.T = TC_139_794.port_b.T; GS0CabiA009011002.port.T = TC_786_794.port_b.T; GS0CabiA009011002.port.T = TC_793_794.port_b.T; GS0CabiA009011002.port.T = TC_794_1366.port_a.T; GS0CabiA009011002.port.T = TC_794_795.port_a.T; GS0CabiA009011002.port.T = TC_794_802.port_a.T; GS0CabiA009011002.port.T = TsGS0CabiA009011002.port.T; TsGS0CabiA008011002.port.Q_flow + (TC_792_793.port_b.Q_flow + (TC_785_793.port_b.Q_flow + (TC_138_793.port_b.Q_flow + (GS0CabiA008011002.port.Q_flow + (TC_793_794.port_a.Q_flow + (TC_793_801.port_a.Q_flow + TC_793_1365.port_a.Q_flow)))))) = 0.0; GS0CabiA008011002.port.T = TC_138_793.port_b.T; GS0CabiA008011002.port.T = TC_785_793.port_b.T; GS0CabiA008011002.port.T = TC_792_793.port_b.T; GS0CabiA008011002.port.T = TC_793_1365.port_a.T; GS0CabiA008011002.port.T = TC_793_794.port_a.T; GS0CabiA008011002.port.T = TC_793_801.port_a.T; GS0CabiA008011002.port.T = TsGS0CabiA008011002.port.T; TsGS0CabiA007011002.port.Q_flow + (TC_791_792.port_b.Q_flow + (TC_784_792.port_b.Q_flow + (TC_137_792.port_b.Q_flow + (GS0CabiA007011002.port.Q_flow + (TC_792_793.port_a.Q_flow + (TC_792_800.port_a.Q_flow + TC_792_1364.port_a.Q_flow)))))) = 0.0; GS0CabiA007011002.port.T = TC_137_792.port_b.T; GS0CabiA007011002.port.T = TC_784_792.port_b.T; GS0CabiA007011002.port.T = TC_791_792.port_b.T; GS0CabiA007011002.port.T = TC_792_1364.port_a.T; GS0CabiA007011002.port.T = TC_792_793.port_a.T; GS0CabiA007011002.port.T = TC_792_800.port_a.T; GS0CabiA007011002.port.T = TsGS0CabiA007011002.port.T; TsGS0CabiA006011002.port.Q_flow + (TC_790_791.port_b.Q_flow + (TC_783_791.port_b.Q_flow + (TC_136_791.port_b.Q_flow + (GS0CabiA006011002.port.Q_flow + (TC_791_792.port_a.Q_flow + (TC_791_799.port_a.Q_flow + TC_791_1363.port_a.Q_flow)))))) = 0.0; GS0CabiA006011002.port.T = TC_136_791.port_b.T; GS0CabiA006011002.port.T = TC_783_791.port_b.T; GS0CabiA006011002.port.T = TC_790_791.port_b.T; GS0CabiA006011002.port.T = TC_791_1363.port_a.T; GS0CabiA006011002.port.T = TC_791_792.port_a.T; GS0CabiA006011002.port.T = TC_791_799.port_a.T; GS0CabiA006011002.port.T = TsGS0CabiA006011002.port.T; TsGS0CabiA005011002.port.Q_flow + (TC_789_790.port_b.Q_flow + (TC_782_790.port_b.Q_flow + (TC_135_790.port_b.Q_flow + (GS0CabiA005011002.port.Q_flow + (TC_790_791.port_a.Q_flow + (TC_790_798.port_a.Q_flow + TC_790_1362.port_a.Q_flow)))))) = 0.0; GS0CabiA005011002.port.T = TC_135_790.port_b.T; GS0CabiA005011002.port.T = TC_782_790.port_b.T; GS0CabiA005011002.port.T = TC_789_790.port_b.T; GS0CabiA005011002.port.T = TC_790_1362.port_a.T; GS0CabiA005011002.port.T = TC_790_791.port_a.T; GS0CabiA005011002.port.T = TC_790_798.port_a.T; GS0CabiA005011002.port.T = TsGS0CabiA005011002.port.T; TsGS0CabiA004011002.port.Q_flow + (TC_781_789.port_b.Q_flow + (TC_134_789.port_b.Q_flow + (GS0CabiA004011002.port.Q_flow + (TC_789_790.port_a.Q_flow + (TC_789_797.port_a.Q_flow + (TC_789_1361.port_a.Q_flow + TC_789_1431.port_a.Q_flow)))))) = 0.0; GS0CabiA004011002.port.T = TC_134_789.port_b.T; GS0CabiA004011002.port.T = TC_781_789.port_b.T; GS0CabiA004011002.port.T = TC_789_1361.port_a.T; GS0CabiA004011002.port.T = TC_789_1431.port_a.T; GS0CabiA004011002.port.T = TC_789_790.port_a.T; GS0CabiA004011002.port.T = TC_789_797.port_a.T; GS0CabiA004011002.port.T = TsGS0CabiA004011002.port.T; TsGS0CabiA011010002.port.Q_flow + (TC_787_788.port_b.Q_flow + (TC_780_788.port_b.Q_flow + (TC_128_788.port_b.Q_flow + (GS0CabiA011010002.port.Q_flow + (TC_788_796.port_a.Q_flow + (TC_788_1357.port_a.Q_flow + TC_788_1429.port_a.Q_flow)))))) = 0.0; GS0CabiA011010002.port.T = TC_128_788.port_b.T; GS0CabiA011010002.port.T = TC_780_788.port_b.T; GS0CabiA011010002.port.T = TC_787_788.port_b.T; GS0CabiA011010002.port.T = TC_788_1357.port_a.T; GS0CabiA011010002.port.T = TC_788_1429.port_a.T; GS0CabiA011010002.port.T = TC_788_796.port_a.T; GS0CabiA011010002.port.T = TsGS0CabiA011010002.port.T; TsGS0CabiA010010002.port.Q_flow + (TC_786_787.port_b.Q_flow + (TC_779_787.port_b.Q_flow + (TC_127_787.port_b.Q_flow + (GS0CabiA010010002.port.Q_flow + (TC_787_788.port_a.Q_flow + (TC_787_795.port_a.Q_flow + TC_787_1496.port_a.Q_flow)))))) = 0.0; GS0CabiA010010002.port.T = TC_127_787.port_b.T; GS0CabiA010010002.port.T = TC_779_787.port_b.T; GS0CabiA010010002.port.T = TC_786_787.port_b.T; GS0CabiA010010002.port.T = TC_787_1496.port_a.T; GS0CabiA010010002.port.T = TC_787_788.port_a.T; GS0CabiA010010002.port.T = TC_787_795.port_a.T; GS0CabiA010010002.port.T = TsGS0CabiA010010002.port.T; TsGS0CabiA009010002.port.Q_flow + (TC_785_786.port_b.Q_flow + (TC_778_786.port_b.Q_flow + (TC_126_786.port_b.Q_flow + (GS0CabiA009010002.port.Q_flow + (TC_786_787.port_a.Q_flow + (TC_786_794.port_a.Q_flow + TC_786_1495.port_a.Q_flow)))))) = 0.0; GS0CabiA009010002.port.T = TC_126_786.port_b.T; GS0CabiA009010002.port.T = TC_778_786.port_b.T; GS0CabiA009010002.port.T = TC_785_786.port_b.T; GS0CabiA009010002.port.T = TC_786_1495.port_a.T; GS0CabiA009010002.port.T = TC_786_787.port_a.T; GS0CabiA009010002.port.T = TC_786_794.port_a.T; GS0CabiA009010002.port.T = TsGS0CabiA009010002.port.T; TsGS0CabiA008010002.port.Q_flow + (TC_784_785.port_b.Q_flow + (TC_777_785.port_b.Q_flow + (TC_125_785.port_b.Q_flow + (GS0CabiA008010002.port.Q_flow + (TC_785_786.port_a.Q_flow + (TC_785_793.port_a.Q_flow + TC_785_1494.port_a.Q_flow)))))) = 0.0; GS0CabiA008010002.port.T = TC_125_785.port_b.T; GS0CabiA008010002.port.T = TC_777_785.port_b.T; GS0CabiA008010002.port.T = TC_784_785.port_b.T; GS0CabiA008010002.port.T = TC_785_1494.port_a.T; GS0CabiA008010002.port.T = TC_785_786.port_a.T; GS0CabiA008010002.port.T = TC_785_793.port_a.T; GS0CabiA008010002.port.T = TsGS0CabiA008010002.port.T; TsGS0CabiA007010002.port.Q_flow + (TC_783_784.port_b.Q_flow + (TC_776_784.port_b.Q_flow + (TC_124_784.port_b.Q_flow + (GS0CabiA007010002.port.Q_flow + (TC_784_785.port_a.Q_flow + (TC_784_792.port_a.Q_flow + TC_784_1356.port_a.Q_flow)))))) = 0.0; GS0CabiA007010002.port.T = TC_124_784.port_b.T; GS0CabiA007010002.port.T = TC_776_784.port_b.T; GS0CabiA007010002.port.T = TC_783_784.port_b.T; GS0CabiA007010002.port.T = TC_784_1356.port_a.T; GS0CabiA007010002.port.T = TC_784_785.port_a.T; GS0CabiA007010002.port.T = TC_784_792.port_a.T; GS0CabiA007010002.port.T = TsGS0CabiA007010002.port.T; TsGS0CabiA006010002.port.Q_flow + (TC_782_783.port_b.Q_flow + (TC_775_783.port_b.Q_flow + (TC_123_783.port_b.Q_flow + (GS0CabiA006010002.port.Q_flow + (TC_783_784.port_a.Q_flow + (TC_783_791.port_a.Q_flow + TC_783_1355.port_a.Q_flow)))))) = 0.0; GS0CabiA006010002.port.T = TC_123_783.port_b.T; GS0CabiA006010002.port.T = TC_775_783.port_b.T; GS0CabiA006010002.port.T = TC_782_783.port_b.T; GS0CabiA006010002.port.T = TC_783_1355.port_a.T; GS0CabiA006010002.port.T = TC_783_784.port_a.T; GS0CabiA006010002.port.T = TC_783_791.port_a.T; GS0CabiA006010002.port.T = TsGS0CabiA006010002.port.T; TsGS0CabiA005010002.port.Q_flow + (TC_781_782.port_b.Q_flow + (TC_774_782.port_b.Q_flow + (TC_122_782.port_b.Q_flow + (GS0CabiA005010002.port.Q_flow + (TC_782_783.port_a.Q_flow + (TC_782_790.port_a.Q_flow + TC_782_1354.port_a.Q_flow)))))) = 0.0; GS0CabiA005010002.port.T = TC_122_782.port_b.T; GS0CabiA005010002.port.T = TC_774_782.port_b.T; GS0CabiA005010002.port.T = TC_781_782.port_b.T; GS0CabiA005010002.port.T = TC_782_1354.port_a.T; GS0CabiA005010002.port.T = TC_782_783.port_a.T; GS0CabiA005010002.port.T = TC_782_790.port_a.T; GS0CabiA005010002.port.T = TsGS0CabiA005010002.port.T; TsGS0CabiA004010002.port.Q_flow + (TC_773_781.port_b.Q_flow + (TC_121_781.port_b.Q_flow + (GS0CabiA004010002.port.Q_flow + (TC_781_782.port_a.Q_flow + (TC_781_789.port_a.Q_flow + (TC_781_1353.port_a.Q_flow + TC_781_1428.port_a.Q_flow)))))) = 0.0; GS0CabiA004010002.port.T = TC_121_781.port_b.T; GS0CabiA004010002.port.T = TC_773_781.port_b.T; GS0CabiA004010002.port.T = TC_781_1353.port_a.T; GS0CabiA004010002.port.T = TC_781_1428.port_a.T; GS0CabiA004010002.port.T = TC_781_782.port_a.T; GS0CabiA004010002.port.T = TC_781_789.port_a.T; GS0CabiA004010002.port.T = TsGS0CabiA004010002.port.T; TsGS0CabiA011009002.port.Q_flow + (TC_779_780.port_b.Q_flow + (TC_772_780.port_b.Q_flow + (TC_115_780.port_b.Q_flow + (GS0CabiA011009002.port.Q_flow + (TC_780_788.port_a.Q_flow + (TC_780_1349.port_a.Q_flow + TC_780_1426.port_a.Q_flow)))))) = 0.0; GS0CabiA011009002.port.T = TC_115_780.port_b.T; GS0CabiA011009002.port.T = TC_772_780.port_b.T; GS0CabiA011009002.port.T = TC_779_780.port_b.T; GS0CabiA011009002.port.T = TC_780_1349.port_a.T; GS0CabiA011009002.port.T = TC_780_1426.port_a.T; GS0CabiA011009002.port.T = TC_780_788.port_a.T; GS0CabiA011009002.port.T = TsGS0CabiA011009002.port.T; TsGS0CabiA010009002.port.Q_flow + (TC_778_779.port_b.Q_flow + (TC_771_779.port_b.Q_flow + (TC_114_779.port_b.Q_flow + (GS0CabiA010009002.port.Q_flow + (TC_779_780.port_a.Q_flow + (TC_779_787.port_a.Q_flow + TC_779_1493.port_a.Q_flow)))))) = 0.0; GS0CabiA010009002.port.T = TC_114_779.port_b.T; GS0CabiA010009002.port.T = TC_771_779.port_b.T; GS0CabiA010009002.port.T = TC_778_779.port_b.T; GS0CabiA010009002.port.T = TC_779_1493.port_a.T; GS0CabiA010009002.port.T = TC_779_780.port_a.T; GS0CabiA010009002.port.T = TC_779_787.port_a.T; GS0CabiA010009002.port.T = TsGS0CabiA010009002.port.T; TsGS0CabiA009009002.port.Q_flow + (TC_777_778.port_b.Q_flow + (TC_770_778.port_b.Q_flow + (TC_113_778.port_b.Q_flow + (GS0CabiA009009002.port.Q_flow + (TC_778_779.port_a.Q_flow + (TC_778_786.port_a.Q_flow + TC_778_1492.port_a.Q_flow)))))) = 0.0; GS0CabiA009009002.port.T = TC_113_778.port_b.T; GS0CabiA009009002.port.T = TC_770_778.port_b.T; GS0CabiA009009002.port.T = TC_777_778.port_b.T; GS0CabiA009009002.port.T = TC_778_1492.port_a.T; GS0CabiA009009002.port.T = TC_778_779.port_a.T; GS0CabiA009009002.port.T = TC_778_786.port_a.T; GS0CabiA009009002.port.T = TsGS0CabiA009009002.port.T; TsGS0CabiA008009002.port.Q_flow + (TC_776_777.port_b.Q_flow + (TC_769_777.port_b.Q_flow + (TC_112_777.port_b.Q_flow + (GS0CabiA008009002.port.Q_flow + (TC_777_778.port_a.Q_flow + (TC_777_785.port_a.Q_flow + TC_777_1491.port_a.Q_flow)))))) = 0.0; GS0CabiA008009002.port.T = TC_112_777.port_b.T; GS0CabiA008009002.port.T = TC_769_777.port_b.T; GS0CabiA008009002.port.T = TC_776_777.port_b.T; GS0CabiA008009002.port.T = TC_777_1491.port_a.T; GS0CabiA008009002.port.T = TC_777_778.port_a.T; GS0CabiA008009002.port.T = TC_777_785.port_a.T; GS0CabiA008009002.port.T = TsGS0CabiA008009002.port.T; TsGS0CabiA007009002.port.Q_flow + (TC_775_776.port_b.Q_flow + (TC_768_776.port_b.Q_flow + (TC_111_776.port_b.Q_flow + (GS0CabiA007009002.port.Q_flow + (TC_776_777.port_a.Q_flow + (TC_776_784.port_a.Q_flow + TC_776_1348.port_a.Q_flow)))))) = 0.0; GS0CabiA007009002.port.T = TC_111_776.port_b.T; GS0CabiA007009002.port.T = TC_768_776.port_b.T; GS0CabiA007009002.port.T = TC_775_776.port_b.T; GS0CabiA007009002.port.T = TC_776_1348.port_a.T; GS0CabiA007009002.port.T = TC_776_777.port_a.T; GS0CabiA007009002.port.T = TC_776_784.port_a.T; GS0CabiA007009002.port.T = TsGS0CabiA007009002.port.T; TsGS0CabiA006009002.port.Q_flow + (TC_774_775.port_b.Q_flow + (TC_767_775.port_b.Q_flow + (TC_110_775.port_b.Q_flow + (GS0CabiA006009002.port.Q_flow + (TC_775_776.port_a.Q_flow + (TC_775_783.port_a.Q_flow + TC_775_1347.port_a.Q_flow)))))) = 0.0; GS0CabiA006009002.port.T = TC_110_775.port_b.T; GS0CabiA006009002.port.T = TC_767_775.port_b.T; GS0CabiA006009002.port.T = TC_774_775.port_b.T; GS0CabiA006009002.port.T = TC_775_1347.port_a.T; GS0CabiA006009002.port.T = TC_775_776.port_a.T; GS0CabiA006009002.port.T = TC_775_783.port_a.T; GS0CabiA006009002.port.T = TsGS0CabiA006009002.port.T; TsGS0CabiA005009002.port.Q_flow + (TC_773_774.port_b.Q_flow + (TC_766_774.port_b.Q_flow + (TC_109_774.port_b.Q_flow + (GS0CabiA005009002.port.Q_flow + (TC_774_775.port_a.Q_flow + (TC_774_782.port_a.Q_flow + TC_774_1346.port_a.Q_flow)))))) = 0.0; GS0CabiA005009002.port.T = TC_109_774.port_b.T; GS0CabiA005009002.port.T = TC_766_774.port_b.T; GS0CabiA005009002.port.T = TC_773_774.port_b.T; GS0CabiA005009002.port.T = TC_774_1346.port_a.T; GS0CabiA005009002.port.T = TC_774_775.port_a.T; GS0CabiA005009002.port.T = TC_774_782.port_a.T; GS0CabiA005009002.port.T = TsGS0CabiA005009002.port.T; TsGS0CabiA004009002.port.Q_flow + (TC_765_773.port_b.Q_flow + (TC_108_773.port_b.Q_flow + (GS0CabiA004009002.port.Q_flow + (TC_773_774.port_a.Q_flow + (TC_773_781.port_a.Q_flow + (TC_773_1345.port_a.Q_flow + TC_773_1425.port_a.Q_flow)))))) = 0.0; GS0CabiA004009002.port.T = TC_108_773.port_b.T; GS0CabiA004009002.port.T = TC_765_773.port_b.T; GS0CabiA004009002.port.T = TC_773_1345.port_a.T; GS0CabiA004009002.port.T = TC_773_1425.port_a.T; GS0CabiA004009002.port.T = TC_773_774.port_a.T; GS0CabiA004009002.port.T = TC_773_781.port_a.T; GS0CabiA004009002.port.T = TsGS0CabiA004009002.port.T; TsGS0CabiA011008002.port.Q_flow + (TC_771_772.port_b.Q_flow + (TC_764_772.port_b.Q_flow + (TC_102_772.port_b.Q_flow + (GS0CabiA011008002.port.Q_flow + (TC_772_780.port_a.Q_flow + (TC_772_1341.port_a.Q_flow + TC_772_1423.port_a.Q_flow)))))) = 0.0; GS0CabiA011008002.port.T = TC_102_772.port_b.T; GS0CabiA011008002.port.T = TC_764_772.port_b.T; GS0CabiA011008002.port.T = TC_771_772.port_b.T; GS0CabiA011008002.port.T = TC_772_1341.port_a.T; GS0CabiA011008002.port.T = TC_772_1423.port_a.T; GS0CabiA011008002.port.T = TC_772_780.port_a.T; GS0CabiA011008002.port.T = TsGS0CabiA011008002.port.T; TsGS0CabiA010008002.port.Q_flow + (TC_770_771.port_b.Q_flow + (TC_763_771.port_b.Q_flow + (TC_101_771.port_b.Q_flow + (GS0CabiA010008002.port.Q_flow + (TC_771_772.port_a.Q_flow + (TC_771_779.port_a.Q_flow + TC_771_1490.port_a.Q_flow)))))) = 0.0; GS0CabiA010008002.port.T = TC_101_771.port_b.T; GS0CabiA010008002.port.T = TC_763_771.port_b.T; GS0CabiA010008002.port.T = TC_770_771.port_b.T; GS0CabiA010008002.port.T = TC_771_1490.port_a.T; GS0CabiA010008002.port.T = TC_771_772.port_a.T; GS0CabiA010008002.port.T = TC_771_779.port_a.T; GS0CabiA010008002.port.T = TsGS0CabiA010008002.port.T; TsGS0CabiA009008002.port.Q_flow + (TC_769_770.port_b.Q_flow + (TC_762_770.port_b.Q_flow + (TC_100_770.port_b.Q_flow + (GS0CabiA009008002.port.Q_flow + (TC_770_771.port_a.Q_flow + (TC_770_778.port_a.Q_flow + TC_770_1489.port_a.Q_flow)))))) = 0.0; GS0CabiA009008002.port.T = TC_100_770.port_b.T; GS0CabiA009008002.port.T = TC_762_770.port_b.T; GS0CabiA009008002.port.T = TC_769_770.port_b.T; GS0CabiA009008002.port.T = TC_770_1489.port_a.T; GS0CabiA009008002.port.T = TC_770_771.port_a.T; GS0CabiA009008002.port.T = TC_770_778.port_a.T; GS0CabiA009008002.port.T = TsGS0CabiA009008002.port.T; TsGS0CabiA008008002.port.Q_flow + (TC_768_769.port_b.Q_flow + (TC_761_769.port_b.Q_flow + (TC_99_769.port_b.Q_flow + (GS0CabiA008008002.port.Q_flow + (TC_769_770.port_a.Q_flow + (TC_769_777.port_a.Q_flow + TC_769_1488.port_a.Q_flow)))))) = 0.0; GS0CabiA008008002.port.T = TC_761_769.port_b.T; GS0CabiA008008002.port.T = TC_768_769.port_b.T; GS0CabiA008008002.port.T = TC_769_1488.port_a.T; GS0CabiA008008002.port.T = TC_769_770.port_a.T; GS0CabiA008008002.port.T = TC_769_777.port_a.T; GS0CabiA008008002.port.T = TC_99_769.port_b.T; GS0CabiA008008002.port.T = TsGS0CabiA008008002.port.T; TsGS0CabiA007008002.port.Q_flow + (TC_767_768.port_b.Q_flow + (TC_760_768.port_b.Q_flow + (TC_98_768.port_b.Q_flow + (GS0CabiA007008002.port.Q_flow + (TC_768_769.port_a.Q_flow + (TC_768_776.port_a.Q_flow + TC_768_1340.port_a.Q_flow)))))) = 0.0; GS0CabiA007008002.port.T = TC_760_768.port_b.T; GS0CabiA007008002.port.T = TC_767_768.port_b.T; GS0CabiA007008002.port.T = TC_768_1340.port_a.T; GS0CabiA007008002.port.T = TC_768_769.port_a.T; GS0CabiA007008002.port.T = TC_768_776.port_a.T; GS0CabiA007008002.port.T = TC_98_768.port_b.T; GS0CabiA007008002.port.T = TsGS0CabiA007008002.port.T; TsGS0CabiA006008002.port.Q_flow + (TC_766_767.port_b.Q_flow + (TC_759_767.port_b.Q_flow + (TC_97_767.port_b.Q_flow + (GS0CabiA006008002.port.Q_flow + (TC_767_768.port_a.Q_flow + (TC_767_775.port_a.Q_flow + TC_767_1339.port_a.Q_flow)))))) = 0.0; GS0CabiA006008002.port.T = TC_759_767.port_b.T; GS0CabiA006008002.port.T = TC_766_767.port_b.T; GS0CabiA006008002.port.T = TC_767_1339.port_a.T; GS0CabiA006008002.port.T = TC_767_768.port_a.T; GS0CabiA006008002.port.T = TC_767_775.port_a.T; GS0CabiA006008002.port.T = TC_97_767.port_b.T; GS0CabiA006008002.port.T = TsGS0CabiA006008002.port.T; TsGS0CabiA005008002.port.Q_flow + (TC_765_766.port_b.Q_flow + (TC_758_766.port_b.Q_flow + (TC_96_766.port_b.Q_flow + (GS0CabiA005008002.port.Q_flow + (TC_766_767.port_a.Q_flow + (TC_766_774.port_a.Q_flow + TC_766_1338.port_a.Q_flow)))))) = 0.0; GS0CabiA005008002.port.T = TC_758_766.port_b.T; GS0CabiA005008002.port.T = TC_765_766.port_b.T; GS0CabiA005008002.port.T = TC_766_1338.port_a.T; GS0CabiA005008002.port.T = TC_766_767.port_a.T; GS0CabiA005008002.port.T = TC_766_774.port_a.T; GS0CabiA005008002.port.T = TC_96_766.port_b.T; GS0CabiA005008002.port.T = TsGS0CabiA005008002.port.T; TsGS0CabiA004008002.port.Q_flow + (TC_757_765.port_b.Q_flow + (TC_95_765.port_b.Q_flow + (GS0CabiA004008002.port.Q_flow + (TC_765_766.port_a.Q_flow + (TC_765_773.port_a.Q_flow + (TC_765_1337.port_a.Q_flow + TC_765_1422.port_a.Q_flow)))))) = 0.0; GS0CabiA004008002.port.T = TC_757_765.port_b.T; GS0CabiA004008002.port.T = TC_765_1337.port_a.T; GS0CabiA004008002.port.T = TC_765_1422.port_a.T; GS0CabiA004008002.port.T = TC_765_766.port_a.T; GS0CabiA004008002.port.T = TC_765_773.port_a.T; GS0CabiA004008002.port.T = TC_95_765.port_b.T; GS0CabiA004008002.port.T = TsGS0CabiA004008002.port.T; TsGS0CabiA011007002.port.Q_flow + (TC_763_764.port_b.Q_flow + (TC_756_764.port_b.Q_flow + (TC_89_764.port_b.Q_flow + (GS0CabiA011007002.port.Q_flow + (TC_764_772.port_a.Q_flow + (TC_764_1333.port_a.Q_flow + TC_764_1420.port_a.Q_flow)))))) = 0.0; GS0CabiA011007002.port.T = TC_756_764.port_b.T; GS0CabiA011007002.port.T = TC_763_764.port_b.T; GS0CabiA011007002.port.T = TC_764_1333.port_a.T; GS0CabiA011007002.port.T = TC_764_1420.port_a.T; GS0CabiA011007002.port.T = TC_764_772.port_a.T; GS0CabiA011007002.port.T = TC_89_764.port_b.T; GS0CabiA011007002.port.T = TsGS0CabiA011007002.port.T; TsGS0CabiA010007002.port.Q_flow + (TC_762_763.port_b.Q_flow + (TC_755_763.port_b.Q_flow + (TC_88_763.port_b.Q_flow + (GS0CabiA010007002.port.Q_flow + (TC_763_764.port_a.Q_flow + (TC_763_771.port_a.Q_flow + TC_763_1332.port_a.Q_flow)))))) = 0.0; GS0CabiA010007002.port.T = TC_755_763.port_b.T; GS0CabiA010007002.port.T = TC_762_763.port_b.T; GS0CabiA010007002.port.T = TC_763_1332.port_a.T; GS0CabiA010007002.port.T = TC_763_764.port_a.T; GS0CabiA010007002.port.T = TC_763_771.port_a.T; GS0CabiA010007002.port.T = TC_88_763.port_b.T; GS0CabiA010007002.port.T = TsGS0CabiA010007002.port.T; TsGS0CabiA009007002.port.Q_flow + (TC_761_762.port_b.Q_flow + (TC_754_762.port_b.Q_flow + (TC_87_762.port_b.Q_flow + (GS0CabiA009007002.port.Q_flow + (TC_762_763.port_a.Q_flow + (TC_762_770.port_a.Q_flow + TC_762_1331.port_a.Q_flow)))))) = 0.0; GS0CabiA009007002.port.T = TC_754_762.port_b.T; GS0CabiA009007002.port.T = TC_761_762.port_b.T; GS0CabiA009007002.port.T = TC_762_1331.port_a.T; GS0CabiA009007002.port.T = TC_762_763.port_a.T; GS0CabiA009007002.port.T = TC_762_770.port_a.T; GS0CabiA009007002.port.T = TC_87_762.port_b.T; GS0CabiA009007002.port.T = TsGS0CabiA009007002.port.T; TsGS0CabiA008007002.port.Q_flow + (TC_760_761.port_b.Q_flow + (TC_753_761.port_b.Q_flow + (TC_86_761.port_b.Q_flow + (GS0CabiA008007002.port.Q_flow + (TC_761_762.port_a.Q_flow + (TC_761_769.port_a.Q_flow + TC_761_1330.port_a.Q_flow)))))) = 0.0; GS0CabiA008007002.port.T = TC_753_761.port_b.T; GS0CabiA008007002.port.T = TC_760_761.port_b.T; GS0CabiA008007002.port.T = TC_761_1330.port_a.T; GS0CabiA008007002.port.T = TC_761_762.port_a.T; GS0CabiA008007002.port.T = TC_761_769.port_a.T; GS0CabiA008007002.port.T = TC_86_761.port_b.T; GS0CabiA008007002.port.T = TsGS0CabiA008007002.port.T; TsGS0CabiA007007002.port.Q_flow + (TC_759_760.port_b.Q_flow + (TC_752_760.port_b.Q_flow + (TC_85_760.port_b.Q_flow + (GS0CabiA007007002.port.Q_flow + (TC_760_761.port_a.Q_flow + (TC_760_768.port_a.Q_flow + TC_760_1329.port_a.Q_flow)))))) = 0.0; GS0CabiA007007002.port.T = TC_752_760.port_b.T; GS0CabiA007007002.port.T = TC_759_760.port_b.T; GS0CabiA007007002.port.T = TC_760_1329.port_a.T; GS0CabiA007007002.port.T = TC_760_761.port_a.T; GS0CabiA007007002.port.T = TC_760_768.port_a.T; GS0CabiA007007002.port.T = TC_85_760.port_b.T; GS0CabiA007007002.port.T = TsGS0CabiA007007002.port.T; TsGS0CabiA006007002.port.Q_flow + (TC_758_759.port_b.Q_flow + (TC_751_759.port_b.Q_flow + (TC_84_759.port_b.Q_flow + (GS0CabiA006007002.port.Q_flow + (TC_759_760.port_a.Q_flow + (TC_759_767.port_a.Q_flow + TC_759_1328.port_a.Q_flow)))))) = 0.0; GS0CabiA006007002.port.T = TC_751_759.port_b.T; GS0CabiA006007002.port.T = TC_758_759.port_b.T; GS0CabiA006007002.port.T = TC_759_1328.port_a.T; GS0CabiA006007002.port.T = TC_759_760.port_a.T; GS0CabiA006007002.port.T = TC_759_767.port_a.T; GS0CabiA006007002.port.T = TC_84_759.port_b.T; GS0CabiA006007002.port.T = TsGS0CabiA006007002.port.T; TsGS0CabiA005007002.port.Q_flow + (TC_757_758.port_b.Q_flow + (TC_750_758.port_b.Q_flow + (TC_83_758.port_b.Q_flow + (GS0CabiA005007002.port.Q_flow + (TC_758_759.port_a.Q_flow + (TC_758_766.port_a.Q_flow + TC_758_1327.port_a.Q_flow)))))) = 0.0; GS0CabiA005007002.port.T = TC_750_758.port_b.T; GS0CabiA005007002.port.T = TC_757_758.port_b.T; GS0CabiA005007002.port.T = TC_758_1327.port_a.T; GS0CabiA005007002.port.T = TC_758_759.port_a.T; GS0CabiA005007002.port.T = TC_758_766.port_a.T; GS0CabiA005007002.port.T = TC_83_758.port_b.T; GS0CabiA005007002.port.T = TsGS0CabiA005007002.port.T; TsGS0CabiA004007002.port.Q_flow + (TC_749_757.port_b.Q_flow + (TC_82_757.port_b.Q_flow + (GS0CabiA004007002.port.Q_flow + (TC_757_758.port_a.Q_flow + (TC_757_765.port_a.Q_flow + (TC_757_1326.port_a.Q_flow + TC_757_1419.port_a.Q_flow)))))) = 0.0; GS0CabiA004007002.port.T = TC_749_757.port_b.T; GS0CabiA004007002.port.T = TC_757_1326.port_a.T; GS0CabiA004007002.port.T = TC_757_1419.port_a.T; GS0CabiA004007002.port.T = TC_757_758.port_a.T; GS0CabiA004007002.port.T = TC_757_765.port_a.T; GS0CabiA004007002.port.T = TC_82_757.port_b.T; GS0CabiA004007002.port.T = TsGS0CabiA004007002.port.T; TsGS0CabiA011006002.port.Q_flow + (TC_755_756.port_b.Q_flow + (TC_748_756.port_b.Q_flow + (TC_76_756.port_b.Q_flow + (GS0CabiA011006002.port.Q_flow + (TC_756_764.port_a.Q_flow + (TC_756_1322.port_a.Q_flow + TC_756_1417.port_a.Q_flow)))))) = 0.0; GS0CabiA011006002.port.T = TC_748_756.port_b.T; GS0CabiA011006002.port.T = TC_755_756.port_b.T; GS0CabiA011006002.port.T = TC_756_1322.port_a.T; GS0CabiA011006002.port.T = TC_756_1417.port_a.T; GS0CabiA011006002.port.T = TC_756_764.port_a.T; GS0CabiA011006002.port.T = TC_76_756.port_b.T; GS0CabiA011006002.port.T = TsGS0CabiA011006002.port.T; TsGS0CabiA010006002.port.Q_flow + (TC_754_755.port_b.Q_flow + (TC_747_755.port_b.Q_flow + (TC_75_755.port_b.Q_flow + (GS0CabiA010006002.port.Q_flow + (TC_755_756.port_a.Q_flow + (TC_755_763.port_a.Q_flow + TC_755_1321.port_a.Q_flow)))))) = 0.0; GS0CabiA010006002.port.T = TC_747_755.port_b.T; GS0CabiA010006002.port.T = TC_754_755.port_b.T; GS0CabiA010006002.port.T = TC_755_1321.port_a.T; GS0CabiA010006002.port.T = TC_755_756.port_a.T; GS0CabiA010006002.port.T = TC_755_763.port_a.T; GS0CabiA010006002.port.T = TC_75_755.port_b.T; GS0CabiA010006002.port.T = TsGS0CabiA010006002.port.T; TsGS0CabiA009006002.port.Q_flow + (TC_753_754.port_b.Q_flow + (TC_746_754.port_b.Q_flow + (TC_74_754.port_b.Q_flow + (GS0CabiA009006002.port.Q_flow + (TC_754_755.port_a.Q_flow + (TC_754_762.port_a.Q_flow + TC_754_1320.port_a.Q_flow)))))) = 0.0; GS0CabiA009006002.port.T = TC_746_754.port_b.T; GS0CabiA009006002.port.T = TC_74_754.port_b.T; GS0CabiA009006002.port.T = TC_753_754.port_b.T; GS0CabiA009006002.port.T = TC_754_1320.port_a.T; GS0CabiA009006002.port.T = TC_754_755.port_a.T; GS0CabiA009006002.port.T = TC_754_762.port_a.T; GS0CabiA009006002.port.T = TsGS0CabiA009006002.port.T; TsGS0CabiA008006002.port.Q_flow + (TC_752_753.port_b.Q_flow + (TC_745_753.port_b.Q_flow + (TC_73_753.port_b.Q_flow + (GS0CabiA008006002.port.Q_flow + (TC_753_754.port_a.Q_flow + (TC_753_761.port_a.Q_flow + TC_753_1319.port_a.Q_flow)))))) = 0.0; GS0CabiA008006002.port.T = TC_73_753.port_b.T; GS0CabiA008006002.port.T = TC_745_753.port_b.T; GS0CabiA008006002.port.T = TC_752_753.port_b.T; GS0CabiA008006002.port.T = TC_753_1319.port_a.T; GS0CabiA008006002.port.T = TC_753_754.port_a.T; GS0CabiA008006002.port.T = TC_753_761.port_a.T; GS0CabiA008006002.port.T = TsGS0CabiA008006002.port.T; TsGS0CabiA007006002.port.Q_flow + (TC_751_752.port_b.Q_flow + (TC_744_752.port_b.Q_flow + (TC_72_752.port_b.Q_flow + (GS0CabiA007006002.port.Q_flow + (TC_752_753.port_a.Q_flow + (TC_752_760.port_a.Q_flow + TC_752_1318.port_a.Q_flow)))))) = 0.0; GS0CabiA007006002.port.T = TC_72_752.port_b.T; GS0CabiA007006002.port.T = TC_744_752.port_b.T; GS0CabiA007006002.port.T = TC_751_752.port_b.T; GS0CabiA007006002.port.T = TC_752_1318.port_a.T; GS0CabiA007006002.port.T = TC_752_753.port_a.T; GS0CabiA007006002.port.T = TC_752_760.port_a.T; GS0CabiA007006002.port.T = TsGS0CabiA007006002.port.T; TsGS0CabiA006006002.port.Q_flow + (TC_750_751.port_b.Q_flow + (TC_743_751.port_b.Q_flow + (TC_71_751.port_b.Q_flow + (GS0CabiA006006002.port.Q_flow + (TC_751_752.port_a.Q_flow + (TC_751_759.port_a.Q_flow + TC_751_1317.port_a.Q_flow)))))) = 0.0; GS0CabiA006006002.port.T = TC_71_751.port_b.T; GS0CabiA006006002.port.T = TC_743_751.port_b.T; GS0CabiA006006002.port.T = TC_750_751.port_b.T; GS0CabiA006006002.port.T = TC_751_1317.port_a.T; GS0CabiA006006002.port.T = TC_751_752.port_a.T; GS0CabiA006006002.port.T = TC_751_759.port_a.T; GS0CabiA006006002.port.T = TsGS0CabiA006006002.port.T; TsGS0CabiA005006002.port.Q_flow + (TC_749_750.port_b.Q_flow + (TC_742_750.port_b.Q_flow + (TC_70_750.port_b.Q_flow + (GS0CabiA005006002.port.Q_flow + (TC_750_751.port_a.Q_flow + (TC_750_758.port_a.Q_flow + TC_750_1316.port_a.Q_flow)))))) = 0.0; GS0CabiA005006002.port.T = TC_70_750.port_b.T; GS0CabiA005006002.port.T = TC_742_750.port_b.T; GS0CabiA005006002.port.T = TC_749_750.port_b.T; GS0CabiA005006002.port.T = TC_750_1316.port_a.T; GS0CabiA005006002.port.T = TC_750_751.port_a.T; GS0CabiA005006002.port.T = TC_750_758.port_a.T; GS0CabiA005006002.port.T = TsGS0CabiA005006002.port.T; TsGS0CabiA004006002.port.Q_flow + (TC_741_749.port_b.Q_flow + (TC_69_749.port_b.Q_flow + (GS0CabiA004006002.port.Q_flow + (TC_749_750.port_a.Q_flow + (TC_749_757.port_a.Q_flow + (TC_749_1315.port_a.Q_flow + TC_749_1416.port_a.Q_flow)))))) = 0.0; GS0CabiA004006002.port.T = TC_69_749.port_b.T; GS0CabiA004006002.port.T = TC_741_749.port_b.T; GS0CabiA004006002.port.T = TC_749_1315.port_a.T; GS0CabiA004006002.port.T = TC_749_1416.port_a.T; GS0CabiA004006002.port.T = TC_749_750.port_a.T; GS0CabiA004006002.port.T = TC_749_757.port_a.T; GS0CabiA004006002.port.T = TsGS0CabiA004006002.port.T; TsGS0CabiA011005002.port.Q_flow + (TC_747_748.port_b.Q_flow + (TC_63_748.port_b.Q_flow + (GS0CabiA011005002.port.Q_flow + (TC_748_756.port_a.Q_flow + (TC_748_820.port_a.Q_flow + (TC_748_1311.port_a.Q_flow + TC_748_1414.port_a.Q_flow)))))) = 0.0; GS0CabiA011005002.port.T = TC_63_748.port_b.T; GS0CabiA011005002.port.T = TC_747_748.port_b.T; GS0CabiA011005002.port.T = TC_748_1311.port_a.T; GS0CabiA011005002.port.T = TC_748_1414.port_a.T; GS0CabiA011005002.port.T = TC_748_756.port_a.T; GS0CabiA011005002.port.T = TC_748_820.port_a.T; GS0CabiA011005002.port.T = TsGS0CabiA011005002.port.T; TsGS0CabiA010005002.port.Q_flow + (TC_746_747.port_b.Q_flow + (TC_62_747.port_b.Q_flow + (GS0CabiA010005002.port.Q_flow + (TC_747_748.port_a.Q_flow + (TC_747_755.port_a.Q_flow + (TC_747_819.port_a.Q_flow + TC_747_1310.port_a.Q_flow)))))) = 0.0; GS0CabiA010005002.port.T = TC_62_747.port_b.T; GS0CabiA010005002.port.T = TC_746_747.port_b.T; GS0CabiA010005002.port.T = TC_747_1310.port_a.T; GS0CabiA010005002.port.T = TC_747_748.port_a.T; GS0CabiA010005002.port.T = TC_747_755.port_a.T; GS0CabiA010005002.port.T = TC_747_819.port_a.T; GS0CabiA010005002.port.T = TsGS0CabiA010005002.port.T; TsGS0CabiA009005002.port.Q_flow + (TC_745_746.port_b.Q_flow + (TC_61_746.port_b.Q_flow + (GS0CabiA009005002.port.Q_flow + (TC_746_747.port_a.Q_flow + (TC_746_754.port_a.Q_flow + (TC_746_818.port_a.Q_flow + TC_746_1309.port_a.Q_flow)))))) = 0.0; GS0CabiA009005002.port.T = TC_61_746.port_b.T; GS0CabiA009005002.port.T = TC_745_746.port_b.T; GS0CabiA009005002.port.T = TC_746_1309.port_a.T; GS0CabiA009005002.port.T = TC_746_747.port_a.T; GS0CabiA009005002.port.T = TC_746_754.port_a.T; GS0CabiA009005002.port.T = TC_746_818.port_a.T; GS0CabiA009005002.port.T = TsGS0CabiA009005002.port.T; TsGS0CabiA008005002.port.Q_flow + (TC_744_745.port_b.Q_flow + (TC_60_745.port_b.Q_flow + (GS0CabiA008005002.port.Q_flow + (TC_745_746.port_a.Q_flow + (TC_745_753.port_a.Q_flow + (TC_745_817.port_a.Q_flow + TC_745_1308.port_a.Q_flow)))))) = 0.0; GS0CabiA008005002.port.T = TC_60_745.port_b.T; GS0CabiA008005002.port.T = TC_744_745.port_b.T; GS0CabiA008005002.port.T = TC_745_1308.port_a.T; GS0CabiA008005002.port.T = TC_745_746.port_a.T; GS0CabiA008005002.port.T = TC_745_753.port_a.T; GS0CabiA008005002.port.T = TC_745_817.port_a.T; GS0CabiA008005002.port.T = TsGS0CabiA008005002.port.T; TsGS0CabiA007005002.port.Q_flow + (TC_743_744.port_b.Q_flow + (TC_59_744.port_b.Q_flow + (GS0CabiA007005002.port.Q_flow + (TC_744_745.port_a.Q_flow + (TC_744_752.port_a.Q_flow + (TC_744_816.port_a.Q_flow + TC_744_1307.port_a.Q_flow)))))) = 0.0; GS0CabiA007005002.port.T = TC_59_744.port_b.T; GS0CabiA007005002.port.T = TC_743_744.port_b.T; GS0CabiA007005002.port.T = TC_744_1307.port_a.T; GS0CabiA007005002.port.T = TC_744_745.port_a.T; GS0CabiA007005002.port.T = TC_744_752.port_a.T; GS0CabiA007005002.port.T = TC_744_816.port_a.T; GS0CabiA007005002.port.T = TsGS0CabiA007005002.port.T; TsGS0CabiA006005002.port.Q_flow + (TC_742_743.port_b.Q_flow + (TC_58_743.port_b.Q_flow + (GS0CabiA006005002.port.Q_flow + (TC_743_744.port_a.Q_flow + (TC_743_751.port_a.Q_flow + (TC_743_815.port_a.Q_flow + TC_743_1306.port_a.Q_flow)))))) = 0.0; GS0CabiA006005002.port.T = TC_58_743.port_b.T; GS0CabiA006005002.port.T = TC_742_743.port_b.T; GS0CabiA006005002.port.T = TC_743_1306.port_a.T; GS0CabiA006005002.port.T = TC_743_744.port_a.T; GS0CabiA006005002.port.T = TC_743_751.port_a.T; GS0CabiA006005002.port.T = TC_743_815.port_a.T; GS0CabiA006005002.port.T = TsGS0CabiA006005002.port.T; TsGS0CabiA005005002.port.Q_flow + (TC_741_742.port_b.Q_flow + (TC_57_742.port_b.Q_flow + (GS0CabiA005005002.port.Q_flow + (TC_742_743.port_a.Q_flow + (TC_742_750.port_a.Q_flow + (TC_742_814.port_a.Q_flow + TC_742_1305.port_a.Q_flow)))))) = 0.0; GS0CabiA005005002.port.T = TC_57_742.port_b.T; GS0CabiA005005002.port.T = TC_741_742.port_b.T; GS0CabiA005005002.port.T = TC_742_1305.port_a.T; GS0CabiA005005002.port.T = TC_742_743.port_a.T; GS0CabiA005005002.port.T = TC_742_750.port_a.T; GS0CabiA005005002.port.T = TC_742_814.port_a.T; GS0CabiA005005002.port.T = TsGS0CabiA005005002.port.T; TsGS0CabiA004005002.port.Q_flow + (TC_56_741.port_b.Q_flow + (GS0CabiA004005002.port.Q_flow + (TC_741_742.port_a.Q_flow + (TC_741_749.port_a.Q_flow + (TC_741_813.port_a.Q_flow + (TC_741_1304.port_a.Q_flow + TC_741_1465.port_a.Q_flow)))))) = 0.0; GS0CabiA004005002.port.T = TC_56_741.port_b.T; GS0CabiA004005002.port.T = TC_741_1304.port_a.T; GS0CabiA004005002.port.T = TC_741_1465.port_a.T; GS0CabiA004005002.port.T = TC_741_742.port_a.T; GS0CabiA004005002.port.T = TC_741_749.port_a.T; GS0CabiA004005002.port.T = TC_741_813.port_a.T; GS0CabiA004005002.port.T = TsGS0CabiA004005002.port.T; TsCABI0CabiA013016008.port.Q_flow + (TC_739_740.port_b.Q_flow + (TC_727_740.port_b.Q_flow + (TC_532_740.port_b.Q_flow + (CABI0CabiA013016008.port.Q_flow + TC_740_0.port_a.Q_flow)))) = 0.0; CABI0CabiA013016008.port.T = TC_532_740.port_b.T; CABI0CabiA013016008.port.T = TC_727_740.port_b.T; CABI0CabiA013016008.port.T = TC_739_740.port_b.T; CABI0CabiA013016008.port.T = TC_740_0.port_a.T; CABI0CabiA013016008.port.T = TsCABI0CabiA013016008.port.T; TsCABI0CabiA012016008.port.Q_flow + (TC_738_739.port_b.Q_flow + (TC_726_739.port_b.Q_flow + (TC_531_739.port_b.Q_flow + (CABI0CabiA012016008.port.Q_flow + (TC_739_740.port_a.Q_flow + TC_739_0.port_a.Q_flow))))) = 0.0; CABI0CabiA012016008.port.T = TC_531_739.port_b.T; CABI0CabiA012016008.port.T = TC_726_739.port_b.T; CABI0CabiA012016008.port.T = TC_738_739.port_b.T; CABI0CabiA012016008.port.T = TC_739_0.port_a.T; CABI0CabiA012016008.port.T = TC_739_740.port_a.T; CABI0CabiA012016008.port.T = TsCABI0CabiA012016008.port.T; TsCABI0CabiA011016008.port.Q_flow + (TC_737_738.port_b.Q_flow + (TC_725_738.port_b.Q_flow + (TC_530_738.port_b.Q_flow + (CABI0CabiA011016008.port.Q_flow + (TC_738_739.port_a.Q_flow + TC_738_0.port_a.Q_flow))))) = 0.0; CABI0CabiA011016008.port.T = TC_530_738.port_b.T; CABI0CabiA011016008.port.T = TC_725_738.port_b.T; CABI0CabiA011016008.port.T = TC_737_738.port_b.T; CABI0CabiA011016008.port.T = TC_738_0.port_a.T; CABI0CabiA011016008.port.T = TC_738_739.port_a.T; CABI0CabiA011016008.port.T = TsCABI0CabiA011016008.port.T; TsCABI0CabiA010016008.port.Q_flow + (TC_736_737.port_b.Q_flow + (TC_724_737.port_b.Q_flow + (TC_529_737.port_b.Q_flow + (CABI0CabiA010016008.port.Q_flow + (TC_737_738.port_a.Q_flow + TC_737_0.port_a.Q_flow))))) = 0.0; CABI0CabiA010016008.port.T = TC_529_737.port_b.T; CABI0CabiA010016008.port.T = TC_724_737.port_b.T; CABI0CabiA010016008.port.T = TC_736_737.port_b.T; CABI0CabiA010016008.port.T = TC_737_0.port_a.T; CABI0CabiA010016008.port.T = TC_737_738.port_a.T; CABI0CabiA010016008.port.T = TsCABI0CabiA010016008.port.T; TsCABI0CabiA009016008.port.Q_flow + (TC_735_736.port_b.Q_flow + (TC_723_736.port_b.Q_flow + (TC_528_736.port_b.Q_flow + (CABI0CabiA009016008.port.Q_flow + (TC_736_737.port_a.Q_flow + TC_736_0.port_a.Q_flow))))) = 0.0; CABI0CabiA009016008.port.T = TC_528_736.port_b.T; CABI0CabiA009016008.port.T = TC_723_736.port_b.T; CABI0CabiA009016008.port.T = TC_735_736.port_b.T; CABI0CabiA009016008.port.T = TC_736_0.port_a.T; CABI0CabiA009016008.port.T = TC_736_737.port_a.T; CABI0CabiA009016008.port.T = TsCABI0CabiA009016008.port.T; TsCABI0CabiA008016008.port.Q_flow + (TC_734_735.port_b.Q_flow + (TC_722_735.port_b.Q_flow + (TC_527_735.port_b.Q_flow + (CABI0CabiA008016008.port.Q_flow + (TC_735_736.port_a.Q_flow + TC_735_0.port_a.Q_flow))))) = 0.0; CABI0CabiA008016008.port.T = TC_527_735.port_b.T; CABI0CabiA008016008.port.T = TC_722_735.port_b.T; CABI0CabiA008016008.port.T = TC_734_735.port_b.T; CABI0CabiA008016008.port.T = TC_735_0.port_a.T; CABI0CabiA008016008.port.T = TC_735_736.port_a.T; CABI0CabiA008016008.port.T = TsCABI0CabiA008016008.port.T; TsCABI0CabiA007016008.port.Q_flow + (TC_733_734.port_b.Q_flow + (TC_721_734.port_b.Q_flow + (TC_526_734.port_b.Q_flow + (CABI0CabiA007016008.port.Q_flow + (TC_734_735.port_a.Q_flow + TC_734_0.port_a.Q_flow))))) = 0.0; CABI0CabiA007016008.port.T = TC_526_734.port_b.T; CABI0CabiA007016008.port.T = TC_721_734.port_b.T; CABI0CabiA007016008.port.T = TC_733_734.port_b.T; CABI0CabiA007016008.port.T = TC_734_0.port_a.T; CABI0CabiA007016008.port.T = TC_734_735.port_a.T; CABI0CabiA007016008.port.T = TsCABI0CabiA007016008.port.T; TsCABI0CabiA006016008.port.Q_flow + (TC_732_733.port_b.Q_flow + (TC_720_733.port_b.Q_flow + (TC_525_733.port_b.Q_flow + (CABI0CabiA006016008.port.Q_flow + (TC_733_734.port_a.Q_flow + TC_733_0.port_a.Q_flow))))) = 0.0; CABI0CabiA006016008.port.T = TC_525_733.port_b.T; CABI0CabiA006016008.port.T = TC_720_733.port_b.T; CABI0CabiA006016008.port.T = TC_732_733.port_b.T; CABI0CabiA006016008.port.T = TC_733_0.port_a.T; CABI0CabiA006016008.port.T = TC_733_734.port_a.T; CABI0CabiA006016008.port.T = TsCABI0CabiA006016008.port.T; TsCABI0CabiA005016008.port.Q_flow + (TC_731_732.port_b.Q_flow + (TC_719_732.port_b.Q_flow + (TC_524_732.port_b.Q_flow + (CABI0CabiA005016008.port.Q_flow + (TC_732_733.port_a.Q_flow + TC_732_0.port_a.Q_flow))))) = 0.0; CABI0CabiA005016008.port.T = TC_524_732.port_b.T; CABI0CabiA005016008.port.T = TC_719_732.port_b.T; CABI0CabiA005016008.port.T = TC_731_732.port_b.T; CABI0CabiA005016008.port.T = TC_732_0.port_a.T; CABI0CabiA005016008.port.T = TC_732_733.port_a.T; CABI0CabiA005016008.port.T = TsCABI0CabiA005016008.port.T; TsCABI0CabiA004016008.port.Q_flow + (TC_730_731.port_b.Q_flow + (TC_718_731.port_b.Q_flow + (TC_523_731.port_b.Q_flow + (CABI0CabiA004016008.port.Q_flow + (TC_731_732.port_a.Q_flow + TC_731_0.port_a.Q_flow))))) = 0.0; CABI0CabiA004016008.port.T = TC_523_731.port_b.T; CABI0CabiA004016008.port.T = TC_718_731.port_b.T; CABI0CabiA004016008.port.T = TC_730_731.port_b.T; CABI0CabiA004016008.port.T = TC_731_0.port_a.T; CABI0CabiA004016008.port.T = TC_731_732.port_a.T; CABI0CabiA004016008.port.T = TsCABI0CabiA004016008.port.T; TsCABI0CabiA003016008.port.Q_flow + (TC_729_730.port_b.Q_flow + (TC_717_730.port_b.Q_flow + (TC_522_730.port_b.Q_flow + (CABI0CabiA003016008.port.Q_flow + (TC_730_731.port_a.Q_flow + TC_730_0.port_a.Q_flow))))) = 0.0; CABI0CabiA003016008.port.T = TC_522_730.port_b.T; CABI0CabiA003016008.port.T = TC_717_730.port_b.T; CABI0CabiA003016008.port.T = TC_729_730.port_b.T; CABI0CabiA003016008.port.T = TC_730_0.port_a.T; CABI0CabiA003016008.port.T = TC_730_731.port_a.T; CABI0CabiA003016008.port.T = TsCABI0CabiA003016008.port.T; TsCABI0CabiA002016008.port.Q_flow + (TC_728_729.port_b.Q_flow + (TC_716_729.port_b.Q_flow + (TC_521_729.port_b.Q_flow + (CABI0CabiA002016008.port.Q_flow + (TC_729_730.port_a.Q_flow + TC_729_0.port_a.Q_flow))))) = 0.0; CABI0CabiA002016008.port.T = TC_521_729.port_b.T; CABI0CabiA002016008.port.T = TC_716_729.port_b.T; CABI0CabiA002016008.port.T = TC_728_729.port_b.T; CABI0CabiA002016008.port.T = TC_729_0.port_a.T; CABI0CabiA002016008.port.T = TC_729_730.port_a.T; CABI0CabiA002016008.port.T = TsCABI0CabiA002016008.port.T; TsCABI0CabiA001016008.port.Q_flow + (TC_715_728.port_b.Q_flow + (TC_520_728.port_b.Q_flow + (CABI0CabiA001016008.port.Q_flow + (TC_728_729.port_a.Q_flow + TC_728_0.port_a.Q_flow)))) = 0.0; CABI0CabiA001016008.port.T = TC_520_728.port_b.T; CABI0CabiA001016008.port.T = TC_715_728.port_b.T; CABI0CabiA001016008.port.T = TC_728_0.port_a.T; CABI0CabiA001016008.port.T = TC_728_729.port_a.T; CABI0CabiA001016008.port.T = TsCABI0CabiA001016008.port.T; TsCABI0CabiA013015008.port.Q_flow + (TC_726_727.port_b.Q_flow + (TC_714_727.port_b.Q_flow + (TC_519_727.port_b.Q_flow + (CABI0CabiA013015008.port.Q_flow + (TC_727_740.port_a.Q_flow + TC_727_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013015008.port.T = TC_519_727.port_b.T; CABI0CabiA013015008.port.T = TC_714_727.port_b.T; CABI0CabiA013015008.port.T = TC_726_727.port_b.T; CABI0CabiA013015008.port.T = TC_727_0.port_a.T; CABI0CabiA013015008.port.T = TC_727_740.port_a.T; CABI0CabiA013015008.port.T = TsCABI0CabiA013015008.port.T; TsCABI0CabiA012015008.port.Q_flow + (TC_725_726.port_b.Q_flow + (TC_713_726.port_b.Q_flow + (CABI0CabiA012015008.port.Q_flow + (TC_726_727.port_a.Q_flow + (TC_726_739.port_a.Q_flow + (TC_726_831.port_a.Q_flow + TC_726_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012015008.port.T = TC_713_726.port_b.T; CABI0CabiA012015008.port.T = TC_725_726.port_b.T; CABI0CabiA012015008.port.T = TC_726_0.port_a.T; CABI0CabiA012015008.port.T = TC_726_727.port_a.T; CABI0CabiA012015008.port.T = TC_726_739.port_a.T; CABI0CabiA012015008.port.T = TC_726_831.port_a.T; CABI0CabiA012015008.port.T = TsCABI0CabiA012015008.port.T; TsCABI0CabiA011015008.port.Q_flow + (TC_724_725.port_b.Q_flow + (TC_712_725.port_b.Q_flow + (CABI0CabiA011015008.port.Q_flow + (TC_725_726.port_a.Q_flow + (TC_725_738.port_a.Q_flow + (TC_725_830.port_a.Q_flow + TC_725_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011015008.port.T = TC_712_725.port_b.T; CABI0CabiA011015008.port.T = TC_724_725.port_b.T; CABI0CabiA011015008.port.T = TC_725_0.port_a.T; CABI0CabiA011015008.port.T = TC_725_726.port_a.T; CABI0CabiA011015008.port.T = TC_725_738.port_a.T; CABI0CabiA011015008.port.T = TC_725_830.port_a.T; CABI0CabiA011015008.port.T = TsCABI0CabiA011015008.port.T; TsCABI0CabiA010015008.port.Q_flow + (TC_723_724.port_b.Q_flow + (TC_711_724.port_b.Q_flow + (CABI0CabiA010015008.port.Q_flow + (TC_724_725.port_a.Q_flow + (TC_724_737.port_a.Q_flow + (TC_724_829.port_a.Q_flow + TC_724_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010015008.port.T = TC_711_724.port_b.T; CABI0CabiA010015008.port.T = TC_723_724.port_b.T; CABI0CabiA010015008.port.T = TC_724_0.port_a.T; CABI0CabiA010015008.port.T = TC_724_725.port_a.T; CABI0CabiA010015008.port.T = TC_724_737.port_a.T; CABI0CabiA010015008.port.T = TC_724_829.port_a.T; CABI0CabiA010015008.port.T = TsCABI0CabiA010015008.port.T; TsCABI0CabiA009015008.port.Q_flow + (TC_722_723.port_b.Q_flow + (TC_710_723.port_b.Q_flow + (CABI0CabiA009015008.port.Q_flow + (TC_723_724.port_a.Q_flow + (TC_723_736.port_a.Q_flow + (TC_723_828.port_a.Q_flow + TC_723_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009015008.port.T = TC_710_723.port_b.T; CABI0CabiA009015008.port.T = TC_722_723.port_b.T; CABI0CabiA009015008.port.T = TC_723_0.port_a.T; CABI0CabiA009015008.port.T = TC_723_724.port_a.T; CABI0CabiA009015008.port.T = TC_723_736.port_a.T; CABI0CabiA009015008.port.T = TC_723_828.port_a.T; CABI0CabiA009015008.port.T = TsCABI0CabiA009015008.port.T; TsCABI0CabiA008015008.port.Q_flow + (TC_721_722.port_b.Q_flow + (TC_709_722.port_b.Q_flow + (CABI0CabiA008015008.port.Q_flow + (TC_722_723.port_a.Q_flow + (TC_722_735.port_a.Q_flow + (TC_722_827.port_a.Q_flow + TC_722_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008015008.port.T = TC_709_722.port_b.T; CABI0CabiA008015008.port.T = TC_721_722.port_b.T; CABI0CabiA008015008.port.T = TC_722_0.port_a.T; CABI0CabiA008015008.port.T = TC_722_723.port_a.T; CABI0CabiA008015008.port.T = TC_722_735.port_a.T; CABI0CabiA008015008.port.T = TC_722_827.port_a.T; CABI0CabiA008015008.port.T = TsCABI0CabiA008015008.port.T; TsCABI0CabiA007015008.port.Q_flow + (TC_720_721.port_b.Q_flow + (TC_708_721.port_b.Q_flow + (CABI0CabiA007015008.port.Q_flow + (TC_721_722.port_a.Q_flow + (TC_721_734.port_a.Q_flow + (TC_721_826.port_a.Q_flow + TC_721_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007015008.port.T = TC_708_721.port_b.T; CABI0CabiA007015008.port.T = TC_720_721.port_b.T; CABI0CabiA007015008.port.T = TC_721_0.port_a.T; CABI0CabiA007015008.port.T = TC_721_722.port_a.T; CABI0CabiA007015008.port.T = TC_721_734.port_a.T; CABI0CabiA007015008.port.T = TC_721_826.port_a.T; CABI0CabiA007015008.port.T = TsCABI0CabiA007015008.port.T; TsCABI0CabiA006015008.port.Q_flow + (TC_719_720.port_b.Q_flow + (TC_707_720.port_b.Q_flow + (CABI0CabiA006015008.port.Q_flow + (TC_720_721.port_a.Q_flow + (TC_720_733.port_a.Q_flow + (TC_720_825.port_a.Q_flow + TC_720_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006015008.port.T = TC_707_720.port_b.T; CABI0CabiA006015008.port.T = TC_719_720.port_b.T; CABI0CabiA006015008.port.T = TC_720_0.port_a.T; CABI0CabiA006015008.port.T = TC_720_721.port_a.T; CABI0CabiA006015008.port.T = TC_720_733.port_a.T; CABI0CabiA006015008.port.T = TC_720_825.port_a.T; CABI0CabiA006015008.port.T = TsCABI0CabiA006015008.port.T; TsCABI0CabiA005015008.port.Q_flow + (TC_718_719.port_b.Q_flow + (TC_706_719.port_b.Q_flow + (CABI0CabiA005015008.port.Q_flow + (TC_719_720.port_a.Q_flow + (TC_719_732.port_a.Q_flow + (TC_719_824.port_a.Q_flow + TC_719_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005015008.port.T = TC_706_719.port_b.T; CABI0CabiA005015008.port.T = TC_718_719.port_b.T; CABI0CabiA005015008.port.T = TC_719_0.port_a.T; CABI0CabiA005015008.port.T = TC_719_720.port_a.T; CABI0CabiA005015008.port.T = TC_719_732.port_a.T; CABI0CabiA005015008.port.T = TC_719_824.port_a.T; CABI0CabiA005015008.port.T = TsCABI0CabiA005015008.port.T; TsCABI0CabiA004015008.port.Q_flow + (TC_717_718.port_b.Q_flow + (TC_705_718.port_b.Q_flow + (CABI0CabiA004015008.port.Q_flow + (TC_718_719.port_a.Q_flow + (TC_718_731.port_a.Q_flow + (TC_718_823.port_a.Q_flow + TC_718_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004015008.port.T = TC_705_718.port_b.T; CABI0CabiA004015008.port.T = TC_717_718.port_b.T; CABI0CabiA004015008.port.T = TC_718_0.port_a.T; CABI0CabiA004015008.port.T = TC_718_719.port_a.T; CABI0CabiA004015008.port.T = TC_718_731.port_a.T; CABI0CabiA004015008.port.T = TC_718_823.port_a.T; CABI0CabiA004015008.port.T = TsCABI0CabiA004015008.port.T; TsCABI0CabiA003015008.port.Q_flow + (TC_716_717.port_b.Q_flow + (TC_704_717.port_b.Q_flow + (CABI0CabiA003015008.port.Q_flow + (TC_717_718.port_a.Q_flow + (TC_717_730.port_a.Q_flow + (TC_717_822.port_a.Q_flow + TC_717_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003015008.port.T = TC_704_717.port_b.T; CABI0CabiA003015008.port.T = TC_716_717.port_b.T; CABI0CabiA003015008.port.T = TC_717_0.port_a.T; CABI0CabiA003015008.port.T = TC_717_718.port_a.T; CABI0CabiA003015008.port.T = TC_717_730.port_a.T; CABI0CabiA003015008.port.T = TC_717_822.port_a.T; CABI0CabiA003015008.port.T = TsCABI0CabiA003015008.port.T; TsCABI0CabiA002015008.port.Q_flow + (TC_715_716.port_b.Q_flow + (TC_703_716.port_b.Q_flow + (CABI0CabiA002015008.port.Q_flow + (TC_716_717.port_a.Q_flow + (TC_716_729.port_a.Q_flow + (TC_716_821.port_a.Q_flow + TC_716_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002015008.port.T = TC_703_716.port_b.T; CABI0CabiA002015008.port.T = TC_715_716.port_b.T; CABI0CabiA002015008.port.T = TC_716_0.port_a.T; CABI0CabiA002015008.port.T = TC_716_717.port_a.T; CABI0CabiA002015008.port.T = TC_716_729.port_a.T; CABI0CabiA002015008.port.T = TC_716_821.port_a.T; CABI0CabiA002015008.port.T = TsCABI0CabiA002015008.port.T; TsCABI0CabiA001015008.port.Q_flow + (TC_702_715.port_b.Q_flow + (TC_518_715.port_b.Q_flow + (CABI0CabiA001015008.port.Q_flow + (TC_715_716.port_a.Q_flow + (TC_715_728.port_a.Q_flow + TC_715_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001015008.port.T = TC_518_715.port_b.T; CABI0CabiA001015008.port.T = TC_702_715.port_b.T; CABI0CabiA001015008.port.T = TC_715_0.port_a.T; CABI0CabiA001015008.port.T = TC_715_716.port_a.T; CABI0CabiA001015008.port.T = TC_715_728.port_a.T; CABI0CabiA001015008.port.T = TsCABI0CabiA001015008.port.T; TsCABI0CabiA013014008.port.Q_flow + (TC_713_714.port_b.Q_flow + (TC_701_714.port_b.Q_flow + (TC_517_714.port_b.Q_flow + (CABI0CabiA013014008.port.Q_flow + (TC_714_727.port_a.Q_flow + TC_714_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013014008.port.T = TC_517_714.port_b.T; CABI0CabiA013014008.port.T = TC_701_714.port_b.T; CABI0CabiA013014008.port.T = TC_713_714.port_b.T; CABI0CabiA013014008.port.T = TC_714_0.port_a.T; CABI0CabiA013014008.port.T = TC_714_727.port_a.T; CABI0CabiA013014008.port.T = TsCABI0CabiA013014008.port.T; TsCABI0CabiA012014008.port.Q_flow + (TC_712_713.port_b.Q_flow + (TC_700_713.port_b.Q_flow + (CABI0CabiA012014008.port.Q_flow + (TC_713_714.port_a.Q_flow + (TC_713_726.port_a.Q_flow + (TC_713_842.port_a.Q_flow + TC_713_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012014008.port.T = TC_700_713.port_b.T; CABI0CabiA012014008.port.T = TC_712_713.port_b.T; CABI0CabiA012014008.port.T = TC_713_0.port_a.T; CABI0CabiA012014008.port.T = TC_713_714.port_a.T; CABI0CabiA012014008.port.T = TC_713_726.port_a.T; CABI0CabiA012014008.port.T = TC_713_842.port_a.T; CABI0CabiA012014008.port.T = TsCABI0CabiA012014008.port.T; TsCABI0CabiA011014008.port.Q_flow + (TC_711_712.port_b.Q_flow + (TC_699_712.port_b.Q_flow + (CABI0CabiA011014008.port.Q_flow + (TC_712_713.port_a.Q_flow + (TC_712_725.port_a.Q_flow + (TC_712_841.port_a.Q_flow + TC_712_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011014008.port.T = TC_699_712.port_b.T; CABI0CabiA011014008.port.T = TC_711_712.port_b.T; CABI0CabiA011014008.port.T = TC_712_0.port_a.T; CABI0CabiA011014008.port.T = TC_712_713.port_a.T; CABI0CabiA011014008.port.T = TC_712_725.port_a.T; CABI0CabiA011014008.port.T = TC_712_841.port_a.T; CABI0CabiA011014008.port.T = TsCABI0CabiA011014008.port.T; TsCABI0CabiA010014008.port.Q_flow + (TC_710_711.port_b.Q_flow + (TC_698_711.port_b.Q_flow + (CABI0CabiA010014008.port.Q_flow + (TC_711_712.port_a.Q_flow + (TC_711_724.port_a.Q_flow + (TC_711_840.port_a.Q_flow + TC_711_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010014008.port.T = TC_698_711.port_b.T; CABI0CabiA010014008.port.T = TC_710_711.port_b.T; CABI0CabiA010014008.port.T = TC_711_0.port_a.T; CABI0CabiA010014008.port.T = TC_711_712.port_a.T; CABI0CabiA010014008.port.T = TC_711_724.port_a.T; CABI0CabiA010014008.port.T = TC_711_840.port_a.T; CABI0CabiA010014008.port.T = TsCABI0CabiA010014008.port.T; TsCABI0CabiA009014008.port.Q_flow + (TC_709_710.port_b.Q_flow + (TC_697_710.port_b.Q_flow + (CABI0CabiA009014008.port.Q_flow + (TC_710_711.port_a.Q_flow + (TC_710_723.port_a.Q_flow + (TC_710_839.port_a.Q_flow + TC_710_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009014008.port.T = TC_697_710.port_b.T; CABI0CabiA009014008.port.T = TC_709_710.port_b.T; CABI0CabiA009014008.port.T = TC_710_0.port_a.T; CABI0CabiA009014008.port.T = TC_710_711.port_a.T; CABI0CabiA009014008.port.T = TC_710_723.port_a.T; CABI0CabiA009014008.port.T = TC_710_839.port_a.T; CABI0CabiA009014008.port.T = TsCABI0CabiA009014008.port.T; TsCABI0CabiA008014008.port.Q_flow + (TC_708_709.port_b.Q_flow + (TC_696_709.port_b.Q_flow + (CABI0CabiA008014008.port.Q_flow + (TC_709_710.port_a.Q_flow + (TC_709_722.port_a.Q_flow + (TC_709_838.port_a.Q_flow + TC_709_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008014008.port.T = TC_696_709.port_b.T; CABI0CabiA008014008.port.T = TC_708_709.port_b.T; CABI0CabiA008014008.port.T = TC_709_0.port_a.T; CABI0CabiA008014008.port.T = TC_709_710.port_a.T; CABI0CabiA008014008.port.T = TC_709_722.port_a.T; CABI0CabiA008014008.port.T = TC_709_838.port_a.T; CABI0CabiA008014008.port.T = TsCABI0CabiA008014008.port.T; TsCABI0CabiA007014008.port.Q_flow + (TC_707_708.port_b.Q_flow + (TC_695_708.port_b.Q_flow + (CABI0CabiA007014008.port.Q_flow + (TC_708_709.port_a.Q_flow + (TC_708_721.port_a.Q_flow + (TC_708_837.port_a.Q_flow + TC_708_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007014008.port.T = TC_695_708.port_b.T; CABI0CabiA007014008.port.T = TC_707_708.port_b.T; CABI0CabiA007014008.port.T = TC_708_0.port_a.T; CABI0CabiA007014008.port.T = TC_708_709.port_a.T; CABI0CabiA007014008.port.T = TC_708_721.port_a.T; CABI0CabiA007014008.port.T = TC_708_837.port_a.T; CABI0CabiA007014008.port.T = TsCABI0CabiA007014008.port.T; TsCABI0CabiA006014008.port.Q_flow + (TC_706_707.port_b.Q_flow + (TC_694_707.port_b.Q_flow + (CABI0CabiA006014008.port.Q_flow + (TC_707_708.port_a.Q_flow + (TC_707_720.port_a.Q_flow + (TC_707_836.port_a.Q_flow + TC_707_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006014008.port.T = TC_694_707.port_b.T; CABI0CabiA006014008.port.T = TC_706_707.port_b.T; CABI0CabiA006014008.port.T = TC_707_0.port_a.T; CABI0CabiA006014008.port.T = TC_707_708.port_a.T; CABI0CabiA006014008.port.T = TC_707_720.port_a.T; CABI0CabiA006014008.port.T = TC_707_836.port_a.T; CABI0CabiA006014008.port.T = TsCABI0CabiA006014008.port.T; TsCABI0CabiA005014008.port.Q_flow + (TC_705_706.port_b.Q_flow + (TC_693_706.port_b.Q_flow + (CABI0CabiA005014008.port.Q_flow + (TC_706_707.port_a.Q_flow + (TC_706_719.port_a.Q_flow + (TC_706_835.port_a.Q_flow + TC_706_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005014008.port.T = TC_693_706.port_b.T; CABI0CabiA005014008.port.T = TC_705_706.port_b.T; CABI0CabiA005014008.port.T = TC_706_0.port_a.T; CABI0CabiA005014008.port.T = TC_706_707.port_a.T; CABI0CabiA005014008.port.T = TC_706_719.port_a.T; CABI0CabiA005014008.port.T = TC_706_835.port_a.T; CABI0CabiA005014008.port.T = TsCABI0CabiA005014008.port.T; TsCABI0CabiA004014008.port.Q_flow + (TC_704_705.port_b.Q_flow + (TC_692_705.port_b.Q_flow + (CABI0CabiA004014008.port.Q_flow + (TC_705_706.port_a.Q_flow + (TC_705_718.port_a.Q_flow + (TC_705_834.port_a.Q_flow + TC_705_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004014008.port.T = TC_692_705.port_b.T; CABI0CabiA004014008.port.T = TC_704_705.port_b.T; CABI0CabiA004014008.port.T = TC_705_0.port_a.T; CABI0CabiA004014008.port.T = TC_705_706.port_a.T; CABI0CabiA004014008.port.T = TC_705_718.port_a.T; CABI0CabiA004014008.port.T = TC_705_834.port_a.T; CABI0CabiA004014008.port.T = TsCABI0CabiA004014008.port.T; TsCABI0CabiA003014008.port.Q_flow + (TC_703_704.port_b.Q_flow + (TC_691_704.port_b.Q_flow + (CABI0CabiA003014008.port.Q_flow + (TC_704_705.port_a.Q_flow + (TC_704_717.port_a.Q_flow + (TC_704_833.port_a.Q_flow + TC_704_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003014008.port.T = TC_691_704.port_b.T; CABI0CabiA003014008.port.T = TC_703_704.port_b.T; CABI0CabiA003014008.port.T = TC_704_0.port_a.T; CABI0CabiA003014008.port.T = TC_704_705.port_a.T; CABI0CabiA003014008.port.T = TC_704_717.port_a.T; CABI0CabiA003014008.port.T = TC_704_833.port_a.T; CABI0CabiA003014008.port.T = TsCABI0CabiA003014008.port.T; TsCABI0CabiA002014008.port.Q_flow + (TC_702_703.port_b.Q_flow + (TC_690_703.port_b.Q_flow + (CABI0CabiA002014008.port.Q_flow + (TC_703_704.port_a.Q_flow + (TC_703_716.port_a.Q_flow + (TC_703_832.port_a.Q_flow + TC_703_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002014008.port.T = TC_690_703.port_b.T; CABI0CabiA002014008.port.T = TC_702_703.port_b.T; CABI0CabiA002014008.port.T = TC_703_0.port_a.T; CABI0CabiA002014008.port.T = TC_703_704.port_a.T; CABI0CabiA002014008.port.T = TC_703_716.port_a.T; CABI0CabiA002014008.port.T = TC_703_832.port_a.T; CABI0CabiA002014008.port.T = TsCABI0CabiA002014008.port.T; TsCABI0CabiA001014008.port.Q_flow + (TC_689_702.port_b.Q_flow + (TC_516_702.port_b.Q_flow + (CABI0CabiA001014008.port.Q_flow + (TC_702_703.port_a.Q_flow + (TC_702_715.port_a.Q_flow + TC_702_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001014008.port.T = TC_516_702.port_b.T; CABI0CabiA001014008.port.T = TC_689_702.port_b.T; CABI0CabiA001014008.port.T = TC_702_0.port_a.T; CABI0CabiA001014008.port.T = TC_702_703.port_a.T; CABI0CabiA001014008.port.T = TC_702_715.port_a.T; CABI0CabiA001014008.port.T = TsCABI0CabiA001014008.port.T; TsCABI0CabiA013013008.port.Q_flow + (TC_700_701.port_b.Q_flow + (TC_688_701.port_b.Q_flow + (TC_515_701.port_b.Q_flow + (CABI0CabiA013013008.port.Q_flow + (TC_701_714.port_a.Q_flow + TC_701_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013013008.port.T = TC_515_701.port_b.T; CABI0CabiA013013008.port.T = TC_688_701.port_b.T; CABI0CabiA013013008.port.T = TC_700_701.port_b.T; CABI0CabiA013013008.port.T = TC_701_0.port_a.T; CABI0CabiA013013008.port.T = TC_701_714.port_a.T; CABI0CabiA013013008.port.T = TsCABI0CabiA013013008.port.T; TsCABI0CabiA012013008.port.Q_flow + (TC_699_700.port_b.Q_flow + (TC_687_700.port_b.Q_flow + (CABI0CabiA012013008.port.Q_flow + (TC_700_701.port_a.Q_flow + (TC_700_713.port_a.Q_flow + (TC_700_919.port_a.Q_flow + TC_700_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012013008.port.T = TC_687_700.port_b.T; CABI0CabiA012013008.port.T = TC_699_700.port_b.T; CABI0CabiA012013008.port.T = TC_700_0.port_a.T; CABI0CabiA012013008.port.T = TC_700_701.port_a.T; CABI0CabiA012013008.port.T = TC_700_713.port_a.T; CABI0CabiA012013008.port.T = TC_700_919.port_a.T; CABI0CabiA012013008.port.T = TsCABI0CabiA012013008.port.T; TsCABI0CabiA011013008.port.Q_flow + (TC_698_699.port_b.Q_flow + (TC_686_699.port_b.Q_flow + (CABI0CabiA011013008.port.Q_flow + (TC_699_700.port_a.Q_flow + (TC_699_712.port_a.Q_flow + (TC_699_918.port_a.Q_flow + TC_699_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011013008.port.T = TC_686_699.port_b.T; CABI0CabiA011013008.port.T = TC_698_699.port_b.T; CABI0CabiA011013008.port.T = TC_699_0.port_a.T; CABI0CabiA011013008.port.T = TC_699_700.port_a.T; CABI0CabiA011013008.port.T = TC_699_712.port_a.T; CABI0CabiA011013008.port.T = TC_699_918.port_a.T; CABI0CabiA011013008.port.T = TsCABI0CabiA011013008.port.T; TsCABI0CabiA010013008.port.Q_flow + (TC_697_698.port_b.Q_flow + (TC_685_698.port_b.Q_flow + (CABI0CabiA010013008.port.Q_flow + (TC_698_699.port_a.Q_flow + (TC_698_711.port_a.Q_flow + (TC_698_917.port_a.Q_flow + TC_698_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010013008.port.T = TC_685_698.port_b.T; CABI0CabiA010013008.port.T = TC_697_698.port_b.T; CABI0CabiA010013008.port.T = TC_698_0.port_a.T; CABI0CabiA010013008.port.T = TC_698_699.port_a.T; CABI0CabiA010013008.port.T = TC_698_711.port_a.T; CABI0CabiA010013008.port.T = TC_698_917.port_a.T; CABI0CabiA010013008.port.T = TsCABI0CabiA010013008.port.T; TsCABI0CabiA009013008.port.Q_flow + (TC_696_697.port_b.Q_flow + (TC_684_697.port_b.Q_flow + (CABI0CabiA009013008.port.Q_flow + (TC_697_698.port_a.Q_flow + (TC_697_710.port_a.Q_flow + (TC_697_916.port_a.Q_flow + TC_697_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009013008.port.T = TC_684_697.port_b.T; CABI0CabiA009013008.port.T = TC_696_697.port_b.T; CABI0CabiA009013008.port.T = TC_697_0.port_a.T; CABI0CabiA009013008.port.T = TC_697_698.port_a.T; CABI0CabiA009013008.port.T = TC_697_710.port_a.T; CABI0CabiA009013008.port.T = TC_697_916.port_a.T; CABI0CabiA009013008.port.T = TsCABI0CabiA009013008.port.T; TsCABI0CabiA008013008.port.Q_flow + (TC_695_696.port_b.Q_flow + (TC_683_696.port_b.Q_flow + (CABI0CabiA008013008.port.Q_flow + (TC_696_697.port_a.Q_flow + (TC_696_709.port_a.Q_flow + (TC_696_915.port_a.Q_flow + TC_696_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008013008.port.T = TC_683_696.port_b.T; CABI0CabiA008013008.port.T = TC_695_696.port_b.T; CABI0CabiA008013008.port.T = TC_696_0.port_a.T; CABI0CabiA008013008.port.T = TC_696_697.port_a.T; CABI0CabiA008013008.port.T = TC_696_709.port_a.T; CABI0CabiA008013008.port.T = TC_696_915.port_a.T; CABI0CabiA008013008.port.T = TsCABI0CabiA008013008.port.T; TsCABI0CabiA007013008.port.Q_flow + (TC_694_695.port_b.Q_flow + (TC_682_695.port_b.Q_flow + (CABI0CabiA007013008.port.Q_flow + (TC_695_696.port_a.Q_flow + (TC_695_708.port_a.Q_flow + (TC_695_914.port_a.Q_flow + TC_695_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007013008.port.T = TC_682_695.port_b.T; CABI0CabiA007013008.port.T = TC_694_695.port_b.T; CABI0CabiA007013008.port.T = TC_695_0.port_a.T; CABI0CabiA007013008.port.T = TC_695_696.port_a.T; CABI0CabiA007013008.port.T = TC_695_708.port_a.T; CABI0CabiA007013008.port.T = TC_695_914.port_a.T; CABI0CabiA007013008.port.T = TsCABI0CabiA007013008.port.T; TsCABI0CabiA006013008.port.Q_flow + (TC_693_694.port_b.Q_flow + (TC_681_694.port_b.Q_flow + (CABI0CabiA006013008.port.Q_flow + (TC_694_695.port_a.Q_flow + (TC_694_707.port_a.Q_flow + (TC_694_913.port_a.Q_flow + TC_694_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006013008.port.T = TC_681_694.port_b.T; CABI0CabiA006013008.port.T = TC_693_694.port_b.T; CABI0CabiA006013008.port.T = TC_694_0.port_a.T; CABI0CabiA006013008.port.T = TC_694_695.port_a.T; CABI0CabiA006013008.port.T = TC_694_707.port_a.T; CABI0CabiA006013008.port.T = TC_694_913.port_a.T; CABI0CabiA006013008.port.T = TsCABI0CabiA006013008.port.T; TsCABI0CabiA005013008.port.Q_flow + (TC_692_693.port_b.Q_flow + (TC_680_693.port_b.Q_flow + (CABI0CabiA005013008.port.Q_flow + (TC_693_694.port_a.Q_flow + (TC_693_706.port_a.Q_flow + (TC_693_912.port_a.Q_flow + TC_693_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005013008.port.T = TC_680_693.port_b.T; CABI0CabiA005013008.port.T = TC_692_693.port_b.T; CABI0CabiA005013008.port.T = TC_693_0.port_a.T; CABI0CabiA005013008.port.T = TC_693_694.port_a.T; CABI0CabiA005013008.port.T = TC_693_706.port_a.T; CABI0CabiA005013008.port.T = TC_693_912.port_a.T; CABI0CabiA005013008.port.T = TsCABI0CabiA005013008.port.T; TsCABI0CabiA004013008.port.Q_flow + (TC_691_692.port_b.Q_flow + (TC_679_692.port_b.Q_flow + (CABI0CabiA004013008.port.Q_flow + (TC_692_693.port_a.Q_flow + (TC_692_705.port_a.Q_flow + (TC_692_911.port_a.Q_flow + TC_692_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004013008.port.T = TC_679_692.port_b.T; CABI0CabiA004013008.port.T = TC_691_692.port_b.T; CABI0CabiA004013008.port.T = TC_692_0.port_a.T; CABI0CabiA004013008.port.T = TC_692_693.port_a.T; CABI0CabiA004013008.port.T = TC_692_705.port_a.T; CABI0CabiA004013008.port.T = TC_692_911.port_a.T; CABI0CabiA004013008.port.T = TsCABI0CabiA004013008.port.T; TsCABI0CabiA003013008.port.Q_flow + (TC_690_691.port_b.Q_flow + (TC_678_691.port_b.Q_flow + (CABI0CabiA003013008.port.Q_flow + (TC_691_692.port_a.Q_flow + (TC_691_704.port_a.Q_flow + (TC_691_910.port_a.Q_flow + TC_691_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003013008.port.T = TC_678_691.port_b.T; CABI0CabiA003013008.port.T = TC_690_691.port_b.T; CABI0CabiA003013008.port.T = TC_691_0.port_a.T; CABI0CabiA003013008.port.T = TC_691_692.port_a.T; CABI0CabiA003013008.port.T = TC_691_704.port_a.T; CABI0CabiA003013008.port.T = TC_691_910.port_a.T; CABI0CabiA003013008.port.T = TsCABI0CabiA003013008.port.T; TsCABI0CabiA002013008.port.Q_flow + (TC_689_690.port_b.Q_flow + (TC_677_690.port_b.Q_flow + (CABI0CabiA002013008.port.Q_flow + (TC_690_691.port_a.Q_flow + (TC_690_703.port_a.Q_flow + (TC_690_909.port_a.Q_flow + TC_690_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002013008.port.T = TC_677_690.port_b.T; CABI0CabiA002013008.port.T = TC_689_690.port_b.T; CABI0CabiA002013008.port.T = TC_690_0.port_a.T; CABI0CabiA002013008.port.T = TC_690_691.port_a.T; CABI0CabiA002013008.port.T = TC_690_703.port_a.T; CABI0CabiA002013008.port.T = TC_690_909.port_a.T; CABI0CabiA002013008.port.T = TsCABI0CabiA002013008.port.T; TsCABI0CabiA001013008.port.Q_flow + (TC_676_689.port_b.Q_flow + (TC_514_689.port_b.Q_flow + (CABI0CabiA001013008.port.Q_flow + (TC_689_690.port_a.Q_flow + (TC_689_702.port_a.Q_flow + TC_689_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001013008.port.T = TC_514_689.port_b.T; CABI0CabiA001013008.port.T = TC_676_689.port_b.T; CABI0CabiA001013008.port.T = TC_689_0.port_a.T; CABI0CabiA001013008.port.T = TC_689_690.port_a.T; CABI0CabiA001013008.port.T = TC_689_702.port_a.T; CABI0CabiA001013008.port.T = TsCABI0CabiA001013008.port.T; TsCABI0CabiA013012008.port.Q_flow + (TC_687_688.port_b.Q_flow + (TC_675_688.port_b.Q_flow + (TC_513_688.port_b.Q_flow + (CABI0CabiA013012008.port.Q_flow + (TC_688_701.port_a.Q_flow + TC_688_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013012008.port.T = TC_513_688.port_b.T; CABI0CabiA013012008.port.T = TC_675_688.port_b.T; CABI0CabiA013012008.port.T = TC_687_688.port_b.T; CABI0CabiA013012008.port.T = TC_688_0.port_a.T; CABI0CabiA013012008.port.T = TC_688_701.port_a.T; CABI0CabiA013012008.port.T = TsCABI0CabiA013012008.port.T; TsCABI0CabiA012012008.port.Q_flow + (TC_686_687.port_b.Q_flow + (TC_674_687.port_b.Q_flow + (CABI0CabiA012012008.port.Q_flow + (TC_687_688.port_a.Q_flow + (TC_687_700.port_a.Q_flow + (TC_687_908.port_a.Q_flow + TC_687_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012012008.port.T = TC_674_687.port_b.T; CABI0CabiA012012008.port.T = TC_686_687.port_b.T; CABI0CabiA012012008.port.T = TC_687_0.port_a.T; CABI0CabiA012012008.port.T = TC_687_688.port_a.T; CABI0CabiA012012008.port.T = TC_687_700.port_a.T; CABI0CabiA012012008.port.T = TC_687_908.port_a.T; CABI0CabiA012012008.port.T = TsCABI0CabiA012012008.port.T; TsCABI0CabiA011012008.port.Q_flow + (TC_685_686.port_b.Q_flow + (TC_673_686.port_b.Q_flow + (CABI0CabiA011012008.port.Q_flow + (TC_686_687.port_a.Q_flow + (TC_686_699.port_a.Q_flow + (TC_686_907.port_a.Q_flow + TC_686_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011012008.port.T = TC_673_686.port_b.T; CABI0CabiA011012008.port.T = TC_685_686.port_b.T; CABI0CabiA011012008.port.T = TC_686_0.port_a.T; CABI0CabiA011012008.port.T = TC_686_687.port_a.T; CABI0CabiA011012008.port.T = TC_686_699.port_a.T; CABI0CabiA011012008.port.T = TC_686_907.port_a.T; CABI0CabiA011012008.port.T = TsCABI0CabiA011012008.port.T; TsCABI0CabiA010012008.port.Q_flow + (TC_684_685.port_b.Q_flow + (TC_672_685.port_b.Q_flow + (CABI0CabiA010012008.port.Q_flow + (TC_685_686.port_a.Q_flow + (TC_685_698.port_a.Q_flow + (TC_685_906.port_a.Q_flow + TC_685_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010012008.port.T = TC_672_685.port_b.T; CABI0CabiA010012008.port.T = TC_684_685.port_b.T; CABI0CabiA010012008.port.T = TC_685_0.port_a.T; CABI0CabiA010012008.port.T = TC_685_686.port_a.T; CABI0CabiA010012008.port.T = TC_685_698.port_a.T; CABI0CabiA010012008.port.T = TC_685_906.port_a.T; CABI0CabiA010012008.port.T = TsCABI0CabiA010012008.port.T; TsCABI0CabiA009012008.port.Q_flow + (TC_683_684.port_b.Q_flow + (TC_671_684.port_b.Q_flow + (CABI0CabiA009012008.port.Q_flow + (TC_684_685.port_a.Q_flow + (TC_684_697.port_a.Q_flow + (TC_684_905.port_a.Q_flow + TC_684_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009012008.port.T = TC_671_684.port_b.T; CABI0CabiA009012008.port.T = TC_683_684.port_b.T; CABI0CabiA009012008.port.T = TC_684_0.port_a.T; CABI0CabiA009012008.port.T = TC_684_685.port_a.T; CABI0CabiA009012008.port.T = TC_684_697.port_a.T; CABI0CabiA009012008.port.T = TC_684_905.port_a.T; CABI0CabiA009012008.port.T = TsCABI0CabiA009012008.port.T; TsCABI0CabiA008012008.port.Q_flow + (TC_682_683.port_b.Q_flow + (TC_670_683.port_b.Q_flow + (CABI0CabiA008012008.port.Q_flow + (TC_683_684.port_a.Q_flow + (TC_683_696.port_a.Q_flow + (TC_683_904.port_a.Q_flow + TC_683_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008012008.port.T = TC_670_683.port_b.T; CABI0CabiA008012008.port.T = TC_682_683.port_b.T; CABI0CabiA008012008.port.T = TC_683_0.port_a.T; CABI0CabiA008012008.port.T = TC_683_684.port_a.T; CABI0CabiA008012008.port.T = TC_683_696.port_a.T; CABI0CabiA008012008.port.T = TC_683_904.port_a.T; CABI0CabiA008012008.port.T = TsCABI0CabiA008012008.port.T; TsCABI0CabiA007012008.port.Q_flow + (TC_681_682.port_b.Q_flow + (TC_669_682.port_b.Q_flow + (CABI0CabiA007012008.port.Q_flow + (TC_682_683.port_a.Q_flow + (TC_682_695.port_a.Q_flow + (TC_682_903.port_a.Q_flow + TC_682_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007012008.port.T = TC_669_682.port_b.T; CABI0CabiA007012008.port.T = TC_681_682.port_b.T; CABI0CabiA007012008.port.T = TC_682_0.port_a.T; CABI0CabiA007012008.port.T = TC_682_683.port_a.T; CABI0CabiA007012008.port.T = TC_682_695.port_a.T; CABI0CabiA007012008.port.T = TC_682_903.port_a.T; CABI0CabiA007012008.port.T = TsCABI0CabiA007012008.port.T; TsCABI0CabiA006012008.port.Q_flow + (TC_680_681.port_b.Q_flow + (TC_668_681.port_b.Q_flow + (CABI0CabiA006012008.port.Q_flow + (TC_681_682.port_a.Q_flow + (TC_681_694.port_a.Q_flow + (TC_681_902.port_a.Q_flow + TC_681_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006012008.port.T = TC_668_681.port_b.T; CABI0CabiA006012008.port.T = TC_680_681.port_b.T; CABI0CabiA006012008.port.T = TC_681_0.port_a.T; CABI0CabiA006012008.port.T = TC_681_682.port_a.T; CABI0CabiA006012008.port.T = TC_681_694.port_a.T; CABI0CabiA006012008.port.T = TC_681_902.port_a.T; CABI0CabiA006012008.port.T = TsCABI0CabiA006012008.port.T; TsCABI0CabiA005012008.port.Q_flow + (TC_679_680.port_b.Q_flow + (TC_667_680.port_b.Q_flow + (CABI0CabiA005012008.port.Q_flow + (TC_680_681.port_a.Q_flow + (TC_680_693.port_a.Q_flow + (TC_680_901.port_a.Q_flow + TC_680_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005012008.port.T = TC_667_680.port_b.T; CABI0CabiA005012008.port.T = TC_679_680.port_b.T; CABI0CabiA005012008.port.T = TC_680_0.port_a.T; CABI0CabiA005012008.port.T = TC_680_681.port_a.T; CABI0CabiA005012008.port.T = TC_680_693.port_a.T; CABI0CabiA005012008.port.T = TC_680_901.port_a.T; CABI0CabiA005012008.port.T = TsCABI0CabiA005012008.port.T; TsCABI0CabiA004012008.port.Q_flow + (TC_678_679.port_b.Q_flow + (TC_666_679.port_b.Q_flow + (CABI0CabiA004012008.port.Q_flow + (TC_679_680.port_a.Q_flow + (TC_679_692.port_a.Q_flow + (TC_679_900.port_a.Q_flow + TC_679_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004012008.port.T = TC_666_679.port_b.T; CABI0CabiA004012008.port.T = TC_678_679.port_b.T; CABI0CabiA004012008.port.T = TC_679_0.port_a.T; CABI0CabiA004012008.port.T = TC_679_680.port_a.T; CABI0CabiA004012008.port.T = TC_679_692.port_a.T; CABI0CabiA004012008.port.T = TC_679_900.port_a.T; CABI0CabiA004012008.port.T = TsCABI0CabiA004012008.port.T; TsCABI0CabiA003012008.port.Q_flow + (TC_677_678.port_b.Q_flow + (TC_665_678.port_b.Q_flow + (CABI0CabiA003012008.port.Q_flow + (TC_678_679.port_a.Q_flow + (TC_678_691.port_a.Q_flow + (TC_678_899.port_a.Q_flow + TC_678_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003012008.port.T = TC_665_678.port_b.T; CABI0CabiA003012008.port.T = TC_677_678.port_b.T; CABI0CabiA003012008.port.T = TC_678_0.port_a.T; CABI0CabiA003012008.port.T = TC_678_679.port_a.T; CABI0CabiA003012008.port.T = TC_678_691.port_a.T; CABI0CabiA003012008.port.T = TC_678_899.port_a.T; CABI0CabiA003012008.port.T = TsCABI0CabiA003012008.port.T; TsCABI0CabiA002012008.port.Q_flow + (TC_676_677.port_b.Q_flow + (TC_664_677.port_b.Q_flow + (CABI0CabiA002012008.port.Q_flow + (TC_677_678.port_a.Q_flow + (TC_677_690.port_a.Q_flow + (TC_677_898.port_a.Q_flow + TC_677_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002012008.port.T = TC_664_677.port_b.T; CABI0CabiA002012008.port.T = TC_676_677.port_b.T; CABI0CabiA002012008.port.T = TC_677_0.port_a.T; CABI0CabiA002012008.port.T = TC_677_678.port_a.T; CABI0CabiA002012008.port.T = TC_677_690.port_a.T; CABI0CabiA002012008.port.T = TC_677_898.port_a.T; CABI0CabiA002012008.port.T = TsCABI0CabiA002012008.port.T; TsCABI0CabiA001012008.port.Q_flow + (TC_663_676.port_b.Q_flow + (TC_512_676.port_b.Q_flow + (CABI0CabiA001012008.port.Q_flow + (TC_676_677.port_a.Q_flow + (TC_676_689.port_a.Q_flow + TC_676_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001012008.port.T = TC_512_676.port_b.T; CABI0CabiA001012008.port.T = TC_663_676.port_b.T; CABI0CabiA001012008.port.T = TC_676_0.port_a.T; CABI0CabiA001012008.port.T = TC_676_677.port_a.T; CABI0CabiA001012008.port.T = TC_676_689.port_a.T; CABI0CabiA001012008.port.T = TsCABI0CabiA001012008.port.T; TsCABI0CabiA013011008.port.Q_flow + (TC_674_675.port_b.Q_flow + (TC_662_675.port_b.Q_flow + (TC_511_675.port_b.Q_flow + (CABI0CabiA013011008.port.Q_flow + (TC_675_688.port_a.Q_flow + TC_675_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013011008.port.T = TC_511_675.port_b.T; CABI0CabiA013011008.port.T = TC_662_675.port_b.T; CABI0CabiA013011008.port.T = TC_674_675.port_b.T; CABI0CabiA013011008.port.T = TC_675_0.port_a.T; CABI0CabiA013011008.port.T = TC_675_688.port_a.T; CABI0CabiA013011008.port.T = TsCABI0CabiA013011008.port.T; TsCABI0CabiA012011008.port.Q_flow + (TC_673_674.port_b.Q_flow + (TC_661_674.port_b.Q_flow + (CABI0CabiA012011008.port.Q_flow + (TC_674_675.port_a.Q_flow + (TC_674_687.port_a.Q_flow + (TC_674_897.port_a.Q_flow + TC_674_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012011008.port.T = TC_661_674.port_b.T; CABI0CabiA012011008.port.T = TC_673_674.port_b.T; CABI0CabiA012011008.port.T = TC_674_0.port_a.T; CABI0CabiA012011008.port.T = TC_674_675.port_a.T; CABI0CabiA012011008.port.T = TC_674_687.port_a.T; CABI0CabiA012011008.port.T = TC_674_897.port_a.T; CABI0CabiA012011008.port.T = TsCABI0CabiA012011008.port.T; TsCABI0CabiA011011008.port.Q_flow + (TC_672_673.port_b.Q_flow + (TC_660_673.port_b.Q_flow + (CABI0CabiA011011008.port.Q_flow + (TC_673_674.port_a.Q_flow + (TC_673_686.port_a.Q_flow + (TC_673_896.port_a.Q_flow + TC_673_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011011008.port.T = TC_660_673.port_b.T; CABI0CabiA011011008.port.T = TC_672_673.port_b.T; CABI0CabiA011011008.port.T = TC_673_0.port_a.T; CABI0CabiA011011008.port.T = TC_673_674.port_a.T; CABI0CabiA011011008.port.T = TC_673_686.port_a.T; CABI0CabiA011011008.port.T = TC_673_896.port_a.T; CABI0CabiA011011008.port.T = TsCABI0CabiA011011008.port.T; TsCABI0CabiA010011008.port.Q_flow + (TC_671_672.port_b.Q_flow + (TC_659_672.port_b.Q_flow + (CABI0CabiA010011008.port.Q_flow + (TC_672_673.port_a.Q_flow + (TC_672_685.port_a.Q_flow + (TC_672_895.port_a.Q_flow + TC_672_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010011008.port.T = TC_659_672.port_b.T; CABI0CabiA010011008.port.T = TC_671_672.port_b.T; CABI0CabiA010011008.port.T = TC_672_0.port_a.T; CABI0CabiA010011008.port.T = TC_672_673.port_a.T; CABI0CabiA010011008.port.T = TC_672_685.port_a.T; CABI0CabiA010011008.port.T = TC_672_895.port_a.T; CABI0CabiA010011008.port.T = TsCABI0CabiA010011008.port.T; TsCABI0CabiA009011008.port.Q_flow + (TC_670_671.port_b.Q_flow + (TC_658_671.port_b.Q_flow + (CABI0CabiA009011008.port.Q_flow + (TC_671_672.port_a.Q_flow + (TC_671_684.port_a.Q_flow + (TC_671_894.port_a.Q_flow + TC_671_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009011008.port.T = TC_658_671.port_b.T; CABI0CabiA009011008.port.T = TC_670_671.port_b.T; CABI0CabiA009011008.port.T = TC_671_0.port_a.T; CABI0CabiA009011008.port.T = TC_671_672.port_a.T; CABI0CabiA009011008.port.T = TC_671_684.port_a.T; CABI0CabiA009011008.port.T = TC_671_894.port_a.T; CABI0CabiA009011008.port.T = TsCABI0CabiA009011008.port.T; TsCABI0CabiA008011008.port.Q_flow + (TC_669_670.port_b.Q_flow + (TC_657_670.port_b.Q_flow + (CABI0CabiA008011008.port.Q_flow + (TC_670_671.port_a.Q_flow + (TC_670_683.port_a.Q_flow + (TC_670_893.port_a.Q_flow + TC_670_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008011008.port.T = TC_657_670.port_b.T; CABI0CabiA008011008.port.T = TC_669_670.port_b.T; CABI0CabiA008011008.port.T = TC_670_0.port_a.T; CABI0CabiA008011008.port.T = TC_670_671.port_a.T; CABI0CabiA008011008.port.T = TC_670_683.port_a.T; CABI0CabiA008011008.port.T = TC_670_893.port_a.T; CABI0CabiA008011008.port.T = TsCABI0CabiA008011008.port.T; TsCABI0CabiA007011008.port.Q_flow + (TC_668_669.port_b.Q_flow + (TC_656_669.port_b.Q_flow + (CABI0CabiA007011008.port.Q_flow + (TC_669_670.port_a.Q_flow + (TC_669_682.port_a.Q_flow + (TC_669_892.port_a.Q_flow + TC_669_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007011008.port.T = TC_656_669.port_b.T; CABI0CabiA007011008.port.T = TC_668_669.port_b.T; CABI0CabiA007011008.port.T = TC_669_0.port_a.T; CABI0CabiA007011008.port.T = TC_669_670.port_a.T; CABI0CabiA007011008.port.T = TC_669_682.port_a.T; CABI0CabiA007011008.port.T = TC_669_892.port_a.T; CABI0CabiA007011008.port.T = TsCABI0CabiA007011008.port.T; TsCABI0CabiA006011008.port.Q_flow + (TC_667_668.port_b.Q_flow + (TC_655_668.port_b.Q_flow + (CABI0CabiA006011008.port.Q_flow + (TC_668_669.port_a.Q_flow + (TC_668_681.port_a.Q_flow + (TC_668_891.port_a.Q_flow + TC_668_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006011008.port.T = TC_655_668.port_b.T; CABI0CabiA006011008.port.T = TC_667_668.port_b.T; CABI0CabiA006011008.port.T = TC_668_0.port_a.T; CABI0CabiA006011008.port.T = TC_668_669.port_a.T; CABI0CabiA006011008.port.T = TC_668_681.port_a.T; CABI0CabiA006011008.port.T = TC_668_891.port_a.T; CABI0CabiA006011008.port.T = TsCABI0CabiA006011008.port.T; TsCABI0CabiA005011008.port.Q_flow + (TC_666_667.port_b.Q_flow + (TC_654_667.port_b.Q_flow + (CABI0CabiA005011008.port.Q_flow + (TC_667_668.port_a.Q_flow + (TC_667_680.port_a.Q_flow + (TC_667_890.port_a.Q_flow + TC_667_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005011008.port.T = TC_654_667.port_b.T; CABI0CabiA005011008.port.T = TC_666_667.port_b.T; CABI0CabiA005011008.port.T = TC_667_0.port_a.T; CABI0CabiA005011008.port.T = TC_667_668.port_a.T; CABI0CabiA005011008.port.T = TC_667_680.port_a.T; CABI0CabiA005011008.port.T = TC_667_890.port_a.T; CABI0CabiA005011008.port.T = TsCABI0CabiA005011008.port.T; TsCABI0CabiA004011008.port.Q_flow + (TC_665_666.port_b.Q_flow + (TC_653_666.port_b.Q_flow + (CABI0CabiA004011008.port.Q_flow + (TC_666_667.port_a.Q_flow + (TC_666_679.port_a.Q_flow + (TC_666_889.port_a.Q_flow + TC_666_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004011008.port.T = TC_653_666.port_b.T; CABI0CabiA004011008.port.T = TC_665_666.port_b.T; CABI0CabiA004011008.port.T = TC_666_0.port_a.T; CABI0CabiA004011008.port.T = TC_666_667.port_a.T; CABI0CabiA004011008.port.T = TC_666_679.port_a.T; CABI0CabiA004011008.port.T = TC_666_889.port_a.T; CABI0CabiA004011008.port.T = TsCABI0CabiA004011008.port.T; TsCABI0CabiA003011008.port.Q_flow + (TC_664_665.port_b.Q_flow + (TC_652_665.port_b.Q_flow + (CABI0CabiA003011008.port.Q_flow + (TC_665_666.port_a.Q_flow + (TC_665_678.port_a.Q_flow + (TC_665_888.port_a.Q_flow + TC_665_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003011008.port.T = TC_652_665.port_b.T; CABI0CabiA003011008.port.T = TC_664_665.port_b.T; CABI0CabiA003011008.port.T = TC_665_0.port_a.T; CABI0CabiA003011008.port.T = TC_665_666.port_a.T; CABI0CabiA003011008.port.T = TC_665_678.port_a.T; CABI0CabiA003011008.port.T = TC_665_888.port_a.T; CABI0CabiA003011008.port.T = TsCABI0CabiA003011008.port.T; TsCABI0CabiA002011008.port.Q_flow + (TC_663_664.port_b.Q_flow + (TC_651_664.port_b.Q_flow + (CABI0CabiA002011008.port.Q_flow + (TC_664_665.port_a.Q_flow + (TC_664_677.port_a.Q_flow + (TC_664_887.port_a.Q_flow + TC_664_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002011008.port.T = TC_651_664.port_b.T; CABI0CabiA002011008.port.T = TC_663_664.port_b.T; CABI0CabiA002011008.port.T = TC_664_0.port_a.T; CABI0CabiA002011008.port.T = TC_664_665.port_a.T; CABI0CabiA002011008.port.T = TC_664_677.port_a.T; CABI0CabiA002011008.port.T = TC_664_887.port_a.T; CABI0CabiA002011008.port.T = TsCABI0CabiA002011008.port.T; TsCABI0CabiA001011008.port.Q_flow + (TC_650_663.port_b.Q_flow + (TC_510_663.port_b.Q_flow + (CABI0CabiA001011008.port.Q_flow + (TC_663_664.port_a.Q_flow + (TC_663_676.port_a.Q_flow + TC_663_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001011008.port.T = TC_510_663.port_b.T; CABI0CabiA001011008.port.T = TC_650_663.port_b.T; CABI0CabiA001011008.port.T = TC_663_0.port_a.T; CABI0CabiA001011008.port.T = TC_663_664.port_a.T; CABI0CabiA001011008.port.T = TC_663_676.port_a.T; CABI0CabiA001011008.port.T = TsCABI0CabiA001011008.port.T; TsCABI0CabiA013010008.port.Q_flow + (TC_661_662.port_b.Q_flow + (TC_649_662.port_b.Q_flow + (TC_509_662.port_b.Q_flow + (CABI0CabiA013010008.port.Q_flow + (TC_662_675.port_a.Q_flow + TC_662_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013010008.port.T = TC_509_662.port_b.T; CABI0CabiA013010008.port.T = TC_649_662.port_b.T; CABI0CabiA013010008.port.T = TC_661_662.port_b.T; CABI0CabiA013010008.port.T = TC_662_0.port_a.T; CABI0CabiA013010008.port.T = TC_662_675.port_a.T; CABI0CabiA013010008.port.T = TsCABI0CabiA013010008.port.T; TsCABI0CabiA012010008.port.Q_flow + (TC_660_661.port_b.Q_flow + (TC_648_661.port_b.Q_flow + (CABI0CabiA012010008.port.Q_flow + (TC_661_662.port_a.Q_flow + (TC_661_674.port_a.Q_flow + (TC_661_886.port_a.Q_flow + TC_661_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012010008.port.T = TC_648_661.port_b.T; CABI0CabiA012010008.port.T = TC_660_661.port_b.T; CABI0CabiA012010008.port.T = TC_661_0.port_a.T; CABI0CabiA012010008.port.T = TC_661_662.port_a.T; CABI0CabiA012010008.port.T = TC_661_674.port_a.T; CABI0CabiA012010008.port.T = TC_661_886.port_a.T; CABI0CabiA012010008.port.T = TsCABI0CabiA012010008.port.T; TsCABI0CabiA011010008.port.Q_flow + (TC_659_660.port_b.Q_flow + (TC_647_660.port_b.Q_flow + (CABI0CabiA011010008.port.Q_flow + (TC_660_661.port_a.Q_flow + (TC_660_673.port_a.Q_flow + (TC_660_885.port_a.Q_flow + TC_660_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011010008.port.T = TC_647_660.port_b.T; CABI0CabiA011010008.port.T = TC_659_660.port_b.T; CABI0CabiA011010008.port.T = TC_660_0.port_a.T; CABI0CabiA011010008.port.T = TC_660_661.port_a.T; CABI0CabiA011010008.port.T = TC_660_673.port_a.T; CABI0CabiA011010008.port.T = TC_660_885.port_a.T; CABI0CabiA011010008.port.T = TsCABI0CabiA011010008.port.T; TsCABI0CabiA010010008.port.Q_flow + (TC_658_659.port_b.Q_flow + (TC_646_659.port_b.Q_flow + (CABI0CabiA010010008.port.Q_flow + (TC_659_660.port_a.Q_flow + (TC_659_672.port_a.Q_flow + (TC_659_884.port_a.Q_flow + TC_659_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010010008.port.T = TC_646_659.port_b.T; CABI0CabiA010010008.port.T = TC_658_659.port_b.T; CABI0CabiA010010008.port.T = TC_659_0.port_a.T; CABI0CabiA010010008.port.T = TC_659_660.port_a.T; CABI0CabiA010010008.port.T = TC_659_672.port_a.T; CABI0CabiA010010008.port.T = TC_659_884.port_a.T; CABI0CabiA010010008.port.T = TsCABI0CabiA010010008.port.T; TsCABI0CabiA009010008.port.Q_flow + (TC_657_658.port_b.Q_flow + (TC_645_658.port_b.Q_flow + (CABI0CabiA009010008.port.Q_flow + (TC_658_659.port_a.Q_flow + (TC_658_671.port_a.Q_flow + (TC_658_883.port_a.Q_flow + TC_658_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009010008.port.T = TC_645_658.port_b.T; CABI0CabiA009010008.port.T = TC_657_658.port_b.T; CABI0CabiA009010008.port.T = TC_658_0.port_a.T; CABI0CabiA009010008.port.T = TC_658_659.port_a.T; CABI0CabiA009010008.port.T = TC_658_671.port_a.T; CABI0CabiA009010008.port.T = TC_658_883.port_a.T; CABI0CabiA009010008.port.T = TsCABI0CabiA009010008.port.T; TsCABI0CabiA008010008.port.Q_flow + (TC_656_657.port_b.Q_flow + (TC_644_657.port_b.Q_flow + (CABI0CabiA008010008.port.Q_flow + (TC_657_658.port_a.Q_flow + (TC_657_670.port_a.Q_flow + (TC_657_882.port_a.Q_flow + TC_657_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008010008.port.T = TC_644_657.port_b.T; CABI0CabiA008010008.port.T = TC_656_657.port_b.T; CABI0CabiA008010008.port.T = TC_657_0.port_a.T; CABI0CabiA008010008.port.T = TC_657_658.port_a.T; CABI0CabiA008010008.port.T = TC_657_670.port_a.T; CABI0CabiA008010008.port.T = TC_657_882.port_a.T; CABI0CabiA008010008.port.T = TsCABI0CabiA008010008.port.T; TsCABI0CabiA007010008.port.Q_flow + (TC_655_656.port_b.Q_flow + (TC_643_656.port_b.Q_flow + (CABI0CabiA007010008.port.Q_flow + (TC_656_657.port_a.Q_flow + (TC_656_669.port_a.Q_flow + (TC_656_881.port_a.Q_flow + TC_656_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007010008.port.T = TC_643_656.port_b.T; CABI0CabiA007010008.port.T = TC_655_656.port_b.T; CABI0CabiA007010008.port.T = TC_656_0.port_a.T; CABI0CabiA007010008.port.T = TC_656_657.port_a.T; CABI0CabiA007010008.port.T = TC_656_669.port_a.T; CABI0CabiA007010008.port.T = TC_656_881.port_a.T; CABI0CabiA007010008.port.T = TsCABI0CabiA007010008.port.T; TsCABI0CabiA006010008.port.Q_flow + (TC_654_655.port_b.Q_flow + (TC_642_655.port_b.Q_flow + (CABI0CabiA006010008.port.Q_flow + (TC_655_656.port_a.Q_flow + (TC_655_668.port_a.Q_flow + (TC_655_880.port_a.Q_flow + TC_655_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006010008.port.T = TC_642_655.port_b.T; CABI0CabiA006010008.port.T = TC_654_655.port_b.T; CABI0CabiA006010008.port.T = TC_655_0.port_a.T; CABI0CabiA006010008.port.T = TC_655_656.port_a.T; CABI0CabiA006010008.port.T = TC_655_668.port_a.T; CABI0CabiA006010008.port.T = TC_655_880.port_a.T; CABI0CabiA006010008.port.T = TsCABI0CabiA006010008.port.T; TsCABI0CabiA005010008.port.Q_flow + (TC_653_654.port_b.Q_flow + (TC_641_654.port_b.Q_flow + (CABI0CabiA005010008.port.Q_flow + (TC_654_655.port_a.Q_flow + (TC_654_667.port_a.Q_flow + (TC_654_879.port_a.Q_flow + TC_654_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005010008.port.T = TC_641_654.port_b.T; CABI0CabiA005010008.port.T = TC_653_654.port_b.T; CABI0CabiA005010008.port.T = TC_654_0.port_a.T; CABI0CabiA005010008.port.T = TC_654_655.port_a.T; CABI0CabiA005010008.port.T = TC_654_667.port_a.T; CABI0CabiA005010008.port.T = TC_654_879.port_a.T; CABI0CabiA005010008.port.T = TsCABI0CabiA005010008.port.T; TsCABI0CabiA004010008.port.Q_flow + (TC_652_653.port_b.Q_flow + (TC_640_653.port_b.Q_flow + (CABI0CabiA004010008.port.Q_flow + (TC_653_654.port_a.Q_flow + (TC_653_666.port_a.Q_flow + (TC_653_878.port_a.Q_flow + TC_653_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004010008.port.T = TC_640_653.port_b.T; CABI0CabiA004010008.port.T = TC_652_653.port_b.T; CABI0CabiA004010008.port.T = TC_653_0.port_a.T; CABI0CabiA004010008.port.T = TC_653_654.port_a.T; CABI0CabiA004010008.port.T = TC_653_666.port_a.T; CABI0CabiA004010008.port.T = TC_653_878.port_a.T; CABI0CabiA004010008.port.T = TsCABI0CabiA004010008.port.T; TsCABI0CabiA003010008.port.Q_flow + (TC_651_652.port_b.Q_flow + (TC_639_652.port_b.Q_flow + (CABI0CabiA003010008.port.Q_flow + (TC_652_653.port_a.Q_flow + (TC_652_665.port_a.Q_flow + (TC_652_877.port_a.Q_flow + TC_652_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003010008.port.T = TC_639_652.port_b.T; CABI0CabiA003010008.port.T = TC_651_652.port_b.T; CABI0CabiA003010008.port.T = TC_652_0.port_a.T; CABI0CabiA003010008.port.T = TC_652_653.port_a.T; CABI0CabiA003010008.port.T = TC_652_665.port_a.T; CABI0CabiA003010008.port.T = TC_652_877.port_a.T; CABI0CabiA003010008.port.T = TsCABI0CabiA003010008.port.T; TsCABI0CabiA002010008.port.Q_flow + (TC_650_651.port_b.Q_flow + (TC_638_651.port_b.Q_flow + (CABI0CabiA002010008.port.Q_flow + (TC_651_652.port_a.Q_flow + (TC_651_664.port_a.Q_flow + (TC_651_876.port_a.Q_flow + TC_651_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002010008.port.T = TC_638_651.port_b.T; CABI0CabiA002010008.port.T = TC_650_651.port_b.T; CABI0CabiA002010008.port.T = TC_651_0.port_a.T; CABI0CabiA002010008.port.T = TC_651_652.port_a.T; CABI0CabiA002010008.port.T = TC_651_664.port_a.T; CABI0CabiA002010008.port.T = TC_651_876.port_a.T; CABI0CabiA002010008.port.T = TsCABI0CabiA002010008.port.T; TsCABI0CabiA001010008.port.Q_flow + (TC_637_650.port_b.Q_flow + (TC_508_650.port_b.Q_flow + (CABI0CabiA001010008.port.Q_flow + (TC_650_651.port_a.Q_flow + (TC_650_663.port_a.Q_flow + TC_650_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001010008.port.T = TC_508_650.port_b.T; CABI0CabiA001010008.port.T = TC_637_650.port_b.T; CABI0CabiA001010008.port.T = TC_650_0.port_a.T; CABI0CabiA001010008.port.T = TC_650_651.port_a.T; CABI0CabiA001010008.port.T = TC_650_663.port_a.T; CABI0CabiA001010008.port.T = TsCABI0CabiA001010008.port.T; TsCABI0CabiA013009008.port.Q_flow + (TC_648_649.port_b.Q_flow + (TC_636_649.port_b.Q_flow + (TC_507_649.port_b.Q_flow + (CABI0CabiA013009008.port.Q_flow + (TC_649_662.port_a.Q_flow + TC_649_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013009008.port.T = TC_507_649.port_b.T; CABI0CabiA013009008.port.T = TC_636_649.port_b.T; CABI0CabiA013009008.port.T = TC_648_649.port_b.T; CABI0CabiA013009008.port.T = TC_649_0.port_a.T; CABI0CabiA013009008.port.T = TC_649_662.port_a.T; CABI0CabiA013009008.port.T = TsCABI0CabiA013009008.port.T; TsCABI0CabiA012009008.port.Q_flow + (TC_647_648.port_b.Q_flow + (TC_635_648.port_b.Q_flow + (CABI0CabiA012009008.port.Q_flow + (TC_648_649.port_a.Q_flow + (TC_648_661.port_a.Q_flow + (TC_648_875.port_a.Q_flow + TC_648_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012009008.port.T = TC_635_648.port_b.T; CABI0CabiA012009008.port.T = TC_647_648.port_b.T; CABI0CabiA012009008.port.T = TC_648_0.port_a.T; CABI0CabiA012009008.port.T = TC_648_649.port_a.T; CABI0CabiA012009008.port.T = TC_648_661.port_a.T; CABI0CabiA012009008.port.T = TC_648_875.port_a.T; CABI0CabiA012009008.port.T = TsCABI0CabiA012009008.port.T; TsCABI0CabiA011009008.port.Q_flow + (TC_646_647.port_b.Q_flow + (TC_634_647.port_b.Q_flow + (CABI0CabiA011009008.port.Q_flow + (TC_647_648.port_a.Q_flow + (TC_647_660.port_a.Q_flow + (TC_647_874.port_a.Q_flow + TC_647_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011009008.port.T = TC_634_647.port_b.T; CABI0CabiA011009008.port.T = TC_646_647.port_b.T; CABI0CabiA011009008.port.T = TC_647_0.port_a.T; CABI0CabiA011009008.port.T = TC_647_648.port_a.T; CABI0CabiA011009008.port.T = TC_647_660.port_a.T; CABI0CabiA011009008.port.T = TC_647_874.port_a.T; CABI0CabiA011009008.port.T = TsCABI0CabiA011009008.port.T; TsCABI0CabiA010009008.port.Q_flow + (TC_645_646.port_b.Q_flow + (TC_633_646.port_b.Q_flow + (CABI0CabiA010009008.port.Q_flow + (TC_646_647.port_a.Q_flow + (TC_646_659.port_a.Q_flow + (TC_646_873.port_a.Q_flow + TC_646_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010009008.port.T = TC_633_646.port_b.T; CABI0CabiA010009008.port.T = TC_645_646.port_b.T; CABI0CabiA010009008.port.T = TC_646_0.port_a.T; CABI0CabiA010009008.port.T = TC_646_647.port_a.T; CABI0CabiA010009008.port.T = TC_646_659.port_a.T; CABI0CabiA010009008.port.T = TC_646_873.port_a.T; CABI0CabiA010009008.port.T = TsCABI0CabiA010009008.port.T; TsCABI0CabiA009009008.port.Q_flow + (TC_644_645.port_b.Q_flow + (TC_632_645.port_b.Q_flow + (CABI0CabiA009009008.port.Q_flow + (TC_645_646.port_a.Q_flow + (TC_645_658.port_a.Q_flow + (TC_645_872.port_a.Q_flow + TC_645_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009009008.port.T = TC_632_645.port_b.T; CABI0CabiA009009008.port.T = TC_644_645.port_b.T; CABI0CabiA009009008.port.T = TC_645_0.port_a.T; CABI0CabiA009009008.port.T = TC_645_646.port_a.T; CABI0CabiA009009008.port.T = TC_645_658.port_a.T; CABI0CabiA009009008.port.T = TC_645_872.port_a.T; CABI0CabiA009009008.port.T = TsCABI0CabiA009009008.port.T; TsCABI0CabiA008009008.port.Q_flow + (TC_643_644.port_b.Q_flow + (TC_631_644.port_b.Q_flow + (CABI0CabiA008009008.port.Q_flow + (TC_644_645.port_a.Q_flow + (TC_644_657.port_a.Q_flow + (TC_644_871.port_a.Q_flow + TC_644_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008009008.port.T = TC_631_644.port_b.T; CABI0CabiA008009008.port.T = TC_643_644.port_b.T; CABI0CabiA008009008.port.T = TC_644_0.port_a.T; CABI0CabiA008009008.port.T = TC_644_645.port_a.T; CABI0CabiA008009008.port.T = TC_644_657.port_a.T; CABI0CabiA008009008.port.T = TC_644_871.port_a.T; CABI0CabiA008009008.port.T = TsCABI0CabiA008009008.port.T; TsCABI0CabiA007009008.port.Q_flow + (TC_642_643.port_b.Q_flow + (TC_630_643.port_b.Q_flow + (CABI0CabiA007009008.port.Q_flow + (TC_643_644.port_a.Q_flow + (TC_643_656.port_a.Q_flow + (TC_643_870.port_a.Q_flow + TC_643_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007009008.port.T = TC_630_643.port_b.T; CABI0CabiA007009008.port.T = TC_642_643.port_b.T; CABI0CabiA007009008.port.T = TC_643_0.port_a.T; CABI0CabiA007009008.port.T = TC_643_644.port_a.T; CABI0CabiA007009008.port.T = TC_643_656.port_a.T; CABI0CabiA007009008.port.T = TC_643_870.port_a.T; CABI0CabiA007009008.port.T = TsCABI0CabiA007009008.port.T; TsCABI0CabiA006009008.port.Q_flow + (TC_641_642.port_b.Q_flow + (TC_629_642.port_b.Q_flow + (CABI0CabiA006009008.port.Q_flow + (TC_642_643.port_a.Q_flow + (TC_642_655.port_a.Q_flow + (TC_642_869.port_a.Q_flow + TC_642_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006009008.port.T = TC_629_642.port_b.T; CABI0CabiA006009008.port.T = TC_641_642.port_b.T; CABI0CabiA006009008.port.T = TC_642_0.port_a.T; CABI0CabiA006009008.port.T = TC_642_643.port_a.T; CABI0CabiA006009008.port.T = TC_642_655.port_a.T; CABI0CabiA006009008.port.T = TC_642_869.port_a.T; CABI0CabiA006009008.port.T = TsCABI0CabiA006009008.port.T; TsCABI0CabiA005009008.port.Q_flow + (TC_640_641.port_b.Q_flow + (TC_628_641.port_b.Q_flow + (CABI0CabiA005009008.port.Q_flow + (TC_641_642.port_a.Q_flow + (TC_641_654.port_a.Q_flow + (TC_641_868.port_a.Q_flow + TC_641_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005009008.port.T = TC_628_641.port_b.T; CABI0CabiA005009008.port.T = TC_640_641.port_b.T; CABI0CabiA005009008.port.T = TC_641_0.port_a.T; CABI0CabiA005009008.port.T = TC_641_642.port_a.T; CABI0CabiA005009008.port.T = TC_641_654.port_a.T; CABI0CabiA005009008.port.T = TC_641_868.port_a.T; CABI0CabiA005009008.port.T = TsCABI0CabiA005009008.port.T; TsCABI0CabiA004009008.port.Q_flow + (TC_639_640.port_b.Q_flow + (TC_627_640.port_b.Q_flow + (CABI0CabiA004009008.port.Q_flow + (TC_640_641.port_a.Q_flow + (TC_640_653.port_a.Q_flow + (TC_640_867.port_a.Q_flow + TC_640_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004009008.port.T = TC_627_640.port_b.T; CABI0CabiA004009008.port.T = TC_639_640.port_b.T; CABI0CabiA004009008.port.T = TC_640_0.port_a.T; CABI0CabiA004009008.port.T = TC_640_641.port_a.T; CABI0CabiA004009008.port.T = TC_640_653.port_a.T; CABI0CabiA004009008.port.T = TC_640_867.port_a.T; CABI0CabiA004009008.port.T = TsCABI0CabiA004009008.port.T; TsCABI0CabiA003009008.port.Q_flow + (TC_638_639.port_b.Q_flow + (TC_626_639.port_b.Q_flow + (CABI0CabiA003009008.port.Q_flow + (TC_639_640.port_a.Q_flow + (TC_639_652.port_a.Q_flow + (TC_639_866.port_a.Q_flow + TC_639_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003009008.port.T = TC_626_639.port_b.T; CABI0CabiA003009008.port.T = TC_638_639.port_b.T; CABI0CabiA003009008.port.T = TC_639_0.port_a.T; CABI0CabiA003009008.port.T = TC_639_640.port_a.T; CABI0CabiA003009008.port.T = TC_639_652.port_a.T; CABI0CabiA003009008.port.T = TC_639_866.port_a.T; CABI0CabiA003009008.port.T = TsCABI0CabiA003009008.port.T; TsCABI0CabiA002009008.port.Q_flow + (TC_637_638.port_b.Q_flow + (TC_625_638.port_b.Q_flow + (CABI0CabiA002009008.port.Q_flow + (TC_638_639.port_a.Q_flow + (TC_638_651.port_a.Q_flow + (TC_638_865.port_a.Q_flow + TC_638_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002009008.port.T = TC_625_638.port_b.T; CABI0CabiA002009008.port.T = TC_637_638.port_b.T; CABI0CabiA002009008.port.T = TC_638_0.port_a.T; CABI0CabiA002009008.port.T = TC_638_639.port_a.T; CABI0CabiA002009008.port.T = TC_638_651.port_a.T; CABI0CabiA002009008.port.T = TC_638_865.port_a.T; CABI0CabiA002009008.port.T = TsCABI0CabiA002009008.port.T; TsCABI0CabiA001009008.port.Q_flow + (TC_624_637.port_b.Q_flow + (TC_506_637.port_b.Q_flow + (CABI0CabiA001009008.port.Q_flow + (TC_637_638.port_a.Q_flow + (TC_637_650.port_a.Q_flow + TC_637_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001009008.port.T = TC_506_637.port_b.T; CABI0CabiA001009008.port.T = TC_624_637.port_b.T; CABI0CabiA001009008.port.T = TC_637_0.port_a.T; CABI0CabiA001009008.port.T = TC_637_638.port_a.T; CABI0CabiA001009008.port.T = TC_637_650.port_a.T; CABI0CabiA001009008.port.T = TsCABI0CabiA001009008.port.T; TsCABI0CabiA013008008.port.Q_flow + (TC_635_636.port_b.Q_flow + (TC_623_636.port_b.Q_flow + (TC_505_636.port_b.Q_flow + (CABI0CabiA013008008.port.Q_flow + (TC_636_649.port_a.Q_flow + TC_636_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013008008.port.T = TC_505_636.port_b.T; CABI0CabiA013008008.port.T = TC_623_636.port_b.T; CABI0CabiA013008008.port.T = TC_635_636.port_b.T; CABI0CabiA013008008.port.T = TC_636_0.port_a.T; CABI0CabiA013008008.port.T = TC_636_649.port_a.T; CABI0CabiA013008008.port.T = TsCABI0CabiA013008008.port.T; TsCABI0CabiA012008008.port.Q_flow + (TC_634_635.port_b.Q_flow + (TC_622_635.port_b.Q_flow + (CABI0CabiA012008008.port.Q_flow + (TC_635_636.port_a.Q_flow + (TC_635_648.port_a.Q_flow + (TC_635_864.port_a.Q_flow + TC_635_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012008008.port.T = TC_622_635.port_b.T; CABI0CabiA012008008.port.T = TC_634_635.port_b.T; CABI0CabiA012008008.port.T = TC_635_0.port_a.T; CABI0CabiA012008008.port.T = TC_635_636.port_a.T; CABI0CabiA012008008.port.T = TC_635_648.port_a.T; CABI0CabiA012008008.port.T = TC_635_864.port_a.T; CABI0CabiA012008008.port.T = TsCABI0CabiA012008008.port.T; TsCABI0CabiA011008008.port.Q_flow + (TC_633_634.port_b.Q_flow + (TC_621_634.port_b.Q_flow + (CABI0CabiA011008008.port.Q_flow + (TC_634_635.port_a.Q_flow + (TC_634_647.port_a.Q_flow + (TC_634_863.port_a.Q_flow + TC_634_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011008008.port.T = TC_621_634.port_b.T; CABI0CabiA011008008.port.T = TC_633_634.port_b.T; CABI0CabiA011008008.port.T = TC_634_0.port_a.T; CABI0CabiA011008008.port.T = TC_634_635.port_a.T; CABI0CabiA011008008.port.T = TC_634_647.port_a.T; CABI0CabiA011008008.port.T = TC_634_863.port_a.T; CABI0CabiA011008008.port.T = TsCABI0CabiA011008008.port.T; TsCABI0CabiA010008008.port.Q_flow + (TC_632_633.port_b.Q_flow + (TC_620_633.port_b.Q_flow + (CABI0CabiA010008008.port.Q_flow + (TC_633_634.port_a.Q_flow + (TC_633_646.port_a.Q_flow + (TC_633_862.port_a.Q_flow + TC_633_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010008008.port.T = TC_620_633.port_b.T; CABI0CabiA010008008.port.T = TC_632_633.port_b.T; CABI0CabiA010008008.port.T = TC_633_0.port_a.T; CABI0CabiA010008008.port.T = TC_633_634.port_a.T; CABI0CabiA010008008.port.T = TC_633_646.port_a.T; CABI0CabiA010008008.port.T = TC_633_862.port_a.T; CABI0CabiA010008008.port.T = TsCABI0CabiA010008008.port.T; TsCABI0CabiA009008008.port.Q_flow + (TC_631_632.port_b.Q_flow + (TC_619_632.port_b.Q_flow + (CABI0CabiA009008008.port.Q_flow + (TC_632_633.port_a.Q_flow + (TC_632_645.port_a.Q_flow + (TC_632_861.port_a.Q_flow + TC_632_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009008008.port.T = TC_619_632.port_b.T; CABI0CabiA009008008.port.T = TC_631_632.port_b.T; CABI0CabiA009008008.port.T = TC_632_0.port_a.T; CABI0CabiA009008008.port.T = TC_632_633.port_a.T; CABI0CabiA009008008.port.T = TC_632_645.port_a.T; CABI0CabiA009008008.port.T = TC_632_861.port_a.T; CABI0CabiA009008008.port.T = TsCABI0CabiA009008008.port.T; TsCABI0CabiA008008008.port.Q_flow + (TC_630_631.port_b.Q_flow + (TC_618_631.port_b.Q_flow + (CABI0CabiA008008008.port.Q_flow + (TC_631_632.port_a.Q_flow + (TC_631_644.port_a.Q_flow + (TC_631_860.port_a.Q_flow + TC_631_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008008008.port.T = TC_618_631.port_b.T; CABI0CabiA008008008.port.T = TC_630_631.port_b.T; CABI0CabiA008008008.port.T = TC_631_0.port_a.T; CABI0CabiA008008008.port.T = TC_631_632.port_a.T; CABI0CabiA008008008.port.T = TC_631_644.port_a.T; CABI0CabiA008008008.port.T = TC_631_860.port_a.T; CABI0CabiA008008008.port.T = TsCABI0CabiA008008008.port.T; TsCABI0CabiA007008008.port.Q_flow + (TC_629_630.port_b.Q_flow + (TC_617_630.port_b.Q_flow + (CABI0CabiA007008008.port.Q_flow + (TC_630_631.port_a.Q_flow + (TC_630_643.port_a.Q_flow + (TC_630_859.port_a.Q_flow + TC_630_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007008008.port.T = TC_617_630.port_b.T; CABI0CabiA007008008.port.T = TC_629_630.port_b.T; CABI0CabiA007008008.port.T = TC_630_0.port_a.T; CABI0CabiA007008008.port.T = TC_630_631.port_a.T; CABI0CabiA007008008.port.T = TC_630_643.port_a.T; CABI0CabiA007008008.port.T = TC_630_859.port_a.T; CABI0CabiA007008008.port.T = TsCABI0CabiA007008008.port.T; TsCABI0CabiA006008008.port.Q_flow + (TC_628_629.port_b.Q_flow + (TC_616_629.port_b.Q_flow + (CABI0CabiA006008008.port.Q_flow + (TC_629_630.port_a.Q_flow + (TC_629_642.port_a.Q_flow + (TC_629_858.port_a.Q_flow + TC_629_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006008008.port.T = TC_616_629.port_b.T; CABI0CabiA006008008.port.T = TC_628_629.port_b.T; CABI0CabiA006008008.port.T = TC_629_0.port_a.T; CABI0CabiA006008008.port.T = TC_629_630.port_a.T; CABI0CabiA006008008.port.T = TC_629_642.port_a.T; CABI0CabiA006008008.port.T = TC_629_858.port_a.T; CABI0CabiA006008008.port.T = TsCABI0CabiA006008008.port.T; TsCABI0CabiA005008008.port.Q_flow + (TC_627_628.port_b.Q_flow + (TC_615_628.port_b.Q_flow + (CABI0CabiA005008008.port.Q_flow + (TC_628_629.port_a.Q_flow + (TC_628_641.port_a.Q_flow + (TC_628_857.port_a.Q_flow + TC_628_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005008008.port.T = TC_615_628.port_b.T; CABI0CabiA005008008.port.T = TC_627_628.port_b.T; CABI0CabiA005008008.port.T = TC_628_0.port_a.T; CABI0CabiA005008008.port.T = TC_628_629.port_a.T; CABI0CabiA005008008.port.T = TC_628_641.port_a.T; CABI0CabiA005008008.port.T = TC_628_857.port_a.T; CABI0CabiA005008008.port.T = TsCABI0CabiA005008008.port.T; TsCABI0CabiA004008008.port.Q_flow + (TC_626_627.port_b.Q_flow + (TC_614_627.port_b.Q_flow + (CABI0CabiA004008008.port.Q_flow + (TC_627_628.port_a.Q_flow + (TC_627_640.port_a.Q_flow + (TC_627_856.port_a.Q_flow + TC_627_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004008008.port.T = TC_614_627.port_b.T; CABI0CabiA004008008.port.T = TC_626_627.port_b.T; CABI0CabiA004008008.port.T = TC_627_0.port_a.T; CABI0CabiA004008008.port.T = TC_627_628.port_a.T; CABI0CabiA004008008.port.T = TC_627_640.port_a.T; CABI0CabiA004008008.port.T = TC_627_856.port_a.T; CABI0CabiA004008008.port.T = TsCABI0CabiA004008008.port.T; TsCABI0CabiA003008008.port.Q_flow + (TC_625_626.port_b.Q_flow + (TC_613_626.port_b.Q_flow + (CABI0CabiA003008008.port.Q_flow + (TC_626_627.port_a.Q_flow + (TC_626_639.port_a.Q_flow + (TC_626_855.port_a.Q_flow + TC_626_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003008008.port.T = TC_613_626.port_b.T; CABI0CabiA003008008.port.T = TC_625_626.port_b.T; CABI0CabiA003008008.port.T = TC_626_0.port_a.T; CABI0CabiA003008008.port.T = TC_626_627.port_a.T; CABI0CabiA003008008.port.T = TC_626_639.port_a.T; CABI0CabiA003008008.port.T = TC_626_855.port_a.T; CABI0CabiA003008008.port.T = TsCABI0CabiA003008008.port.T; TsCABI0CabiA002008008.port.Q_flow + (TC_624_625.port_b.Q_flow + (TC_612_625.port_b.Q_flow + (CABI0CabiA002008008.port.Q_flow + (TC_625_626.port_a.Q_flow + (TC_625_638.port_a.Q_flow + (TC_625_854.port_a.Q_flow + TC_625_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002008008.port.T = TC_612_625.port_b.T; CABI0CabiA002008008.port.T = TC_624_625.port_b.T; CABI0CabiA002008008.port.T = TC_625_0.port_a.T; CABI0CabiA002008008.port.T = TC_625_626.port_a.T; CABI0CabiA002008008.port.T = TC_625_638.port_a.T; CABI0CabiA002008008.port.T = TC_625_854.port_a.T; CABI0CabiA002008008.port.T = TsCABI0CabiA002008008.port.T; TsCABI0CabiA001008008.port.Q_flow + (TC_611_624.port_b.Q_flow + (TC_504_624.port_b.Q_flow + (CABI0CabiA001008008.port.Q_flow + (TC_624_625.port_a.Q_flow + (TC_624_637.port_a.Q_flow + TC_624_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001008008.port.T = TC_504_624.port_b.T; CABI0CabiA001008008.port.T = TC_611_624.port_b.T; CABI0CabiA001008008.port.T = TC_624_0.port_a.T; CABI0CabiA001008008.port.T = TC_624_625.port_a.T; CABI0CabiA001008008.port.T = TC_624_637.port_a.T; CABI0CabiA001008008.port.T = TsCABI0CabiA001008008.port.T; TsCABI0CabiA013007008.port.Q_flow + (TC_622_623.port_b.Q_flow + (TC_610_623.port_b.Q_flow + (TC_503_623.port_b.Q_flow + (CABI0CabiA013007008.port.Q_flow + (TC_623_636.port_a.Q_flow + TC_623_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013007008.port.T = TC_503_623.port_b.T; CABI0CabiA013007008.port.T = TC_610_623.port_b.T; CABI0CabiA013007008.port.T = TC_622_623.port_b.T; CABI0CabiA013007008.port.T = TC_623_0.port_a.T; CABI0CabiA013007008.port.T = TC_623_636.port_a.T; CABI0CabiA013007008.port.T = TsCABI0CabiA013007008.port.T; TsCABI0CabiA012007008.port.Q_flow + (TC_621_622.port_b.Q_flow + (TC_609_622.port_b.Q_flow + (CABI0CabiA012007008.port.Q_flow + (TC_622_623.port_a.Q_flow + (TC_622_635.port_a.Q_flow + (TC_622_853.port_a.Q_flow + TC_622_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012007008.port.T = TC_609_622.port_b.T; CABI0CabiA012007008.port.T = TC_621_622.port_b.T; CABI0CabiA012007008.port.T = TC_622_0.port_a.T; CABI0CabiA012007008.port.T = TC_622_623.port_a.T; CABI0CabiA012007008.port.T = TC_622_635.port_a.T; CABI0CabiA012007008.port.T = TC_622_853.port_a.T; CABI0CabiA012007008.port.T = TsCABI0CabiA012007008.port.T; TsCABI0CabiA011007008.port.Q_flow + (TC_620_621.port_b.Q_flow + (TC_608_621.port_b.Q_flow + (CABI0CabiA011007008.port.Q_flow + (TC_621_622.port_a.Q_flow + (TC_621_634.port_a.Q_flow + (TC_621_852.port_a.Q_flow + TC_621_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011007008.port.T = TC_608_621.port_b.T; CABI0CabiA011007008.port.T = TC_620_621.port_b.T; CABI0CabiA011007008.port.T = TC_621_0.port_a.T; CABI0CabiA011007008.port.T = TC_621_622.port_a.T; CABI0CabiA011007008.port.T = TC_621_634.port_a.T; CABI0CabiA011007008.port.T = TC_621_852.port_a.T; CABI0CabiA011007008.port.T = TsCABI0CabiA011007008.port.T; TsCABI0CabiA010007008.port.Q_flow + (TC_619_620.port_b.Q_flow + (TC_607_620.port_b.Q_flow + (CABI0CabiA010007008.port.Q_flow + (TC_620_621.port_a.Q_flow + (TC_620_633.port_a.Q_flow + (TC_620_851.port_a.Q_flow + TC_620_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010007008.port.T = TC_607_620.port_b.T; CABI0CabiA010007008.port.T = TC_619_620.port_b.T; CABI0CabiA010007008.port.T = TC_620_0.port_a.T; CABI0CabiA010007008.port.T = TC_620_621.port_a.T; CABI0CabiA010007008.port.T = TC_620_633.port_a.T; CABI0CabiA010007008.port.T = TC_620_851.port_a.T; CABI0CabiA010007008.port.T = TsCABI0CabiA010007008.port.T; TsCABI0CabiA009007008.port.Q_flow + (TC_618_619.port_b.Q_flow + (TC_606_619.port_b.Q_flow + (CABI0CabiA009007008.port.Q_flow + (TC_619_620.port_a.Q_flow + (TC_619_632.port_a.Q_flow + (TC_619_850.port_a.Q_flow + TC_619_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009007008.port.T = TC_606_619.port_b.T; CABI0CabiA009007008.port.T = TC_618_619.port_b.T; CABI0CabiA009007008.port.T = TC_619_0.port_a.T; CABI0CabiA009007008.port.T = TC_619_620.port_a.T; CABI0CabiA009007008.port.T = TC_619_632.port_a.T; CABI0CabiA009007008.port.T = TC_619_850.port_a.T; CABI0CabiA009007008.port.T = TsCABI0CabiA009007008.port.T; TsCABI0CabiA008007008.port.Q_flow + (TC_617_618.port_b.Q_flow + (TC_605_618.port_b.Q_flow + (CABI0CabiA008007008.port.Q_flow + (TC_618_619.port_a.Q_flow + (TC_618_631.port_a.Q_flow + (TC_618_849.port_a.Q_flow + TC_618_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008007008.port.T = TC_605_618.port_b.T; CABI0CabiA008007008.port.T = TC_617_618.port_b.T; CABI0CabiA008007008.port.T = TC_618_0.port_a.T; CABI0CabiA008007008.port.T = TC_618_619.port_a.T; CABI0CabiA008007008.port.T = TC_618_631.port_a.T; CABI0CabiA008007008.port.T = TC_618_849.port_a.T; CABI0CabiA008007008.port.T = TsCABI0CabiA008007008.port.T; TsCABI0CabiA007007008.port.Q_flow + (TC_616_617.port_b.Q_flow + (TC_604_617.port_b.Q_flow + (CABI0CabiA007007008.port.Q_flow + (TC_617_618.port_a.Q_flow + (TC_617_630.port_a.Q_flow + (TC_617_848.port_a.Q_flow + TC_617_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007007008.port.T = TC_604_617.port_b.T; CABI0CabiA007007008.port.T = TC_616_617.port_b.T; CABI0CabiA007007008.port.T = TC_617_0.port_a.T; CABI0CabiA007007008.port.T = TC_617_618.port_a.T; CABI0CabiA007007008.port.T = TC_617_630.port_a.T; CABI0CabiA007007008.port.T = TC_617_848.port_a.T; CABI0CabiA007007008.port.T = TsCABI0CabiA007007008.port.T; TsCABI0CabiA006007008.port.Q_flow + (TC_615_616.port_b.Q_flow + (TC_603_616.port_b.Q_flow + (CABI0CabiA006007008.port.Q_flow + (TC_616_617.port_a.Q_flow + (TC_616_629.port_a.Q_flow + (TC_616_847.port_a.Q_flow + TC_616_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006007008.port.T = TC_603_616.port_b.T; CABI0CabiA006007008.port.T = TC_615_616.port_b.T; CABI0CabiA006007008.port.T = TC_616_0.port_a.T; CABI0CabiA006007008.port.T = TC_616_617.port_a.T; CABI0CabiA006007008.port.T = TC_616_629.port_a.T; CABI0CabiA006007008.port.T = TC_616_847.port_a.T; CABI0CabiA006007008.port.T = TsCABI0CabiA006007008.port.T; TsCABI0CabiA005007008.port.Q_flow + (TC_614_615.port_b.Q_flow + (TC_602_615.port_b.Q_flow + (CABI0CabiA005007008.port.Q_flow + (TC_615_616.port_a.Q_flow + (TC_615_628.port_a.Q_flow + (TC_615_846.port_a.Q_flow + TC_615_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005007008.port.T = TC_602_615.port_b.T; CABI0CabiA005007008.port.T = TC_614_615.port_b.T; CABI0CabiA005007008.port.T = TC_615_0.port_a.T; CABI0CabiA005007008.port.T = TC_615_616.port_a.T; CABI0CabiA005007008.port.T = TC_615_628.port_a.T; CABI0CabiA005007008.port.T = TC_615_846.port_a.T; CABI0CabiA005007008.port.T = TsCABI0CabiA005007008.port.T; TsCABI0CabiA004007008.port.Q_flow + (TC_613_614.port_b.Q_flow + (TC_601_614.port_b.Q_flow + (CABI0CabiA004007008.port.Q_flow + (TC_614_615.port_a.Q_flow + (TC_614_627.port_a.Q_flow + (TC_614_845.port_a.Q_flow + TC_614_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004007008.port.T = TC_601_614.port_b.T; CABI0CabiA004007008.port.T = TC_613_614.port_b.T; CABI0CabiA004007008.port.T = TC_614_0.port_a.T; CABI0CabiA004007008.port.T = TC_614_615.port_a.T; CABI0CabiA004007008.port.T = TC_614_627.port_a.T; CABI0CabiA004007008.port.T = TC_614_845.port_a.T; CABI0CabiA004007008.port.T = TsCABI0CabiA004007008.port.T; TsCABI0CabiA003007008.port.Q_flow + (TC_612_613.port_b.Q_flow + (TC_600_613.port_b.Q_flow + (CABI0CabiA003007008.port.Q_flow + (TC_613_614.port_a.Q_flow + (TC_613_626.port_a.Q_flow + (TC_613_844.port_a.Q_flow + TC_613_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003007008.port.T = TC_600_613.port_b.T; CABI0CabiA003007008.port.T = TC_612_613.port_b.T; CABI0CabiA003007008.port.T = TC_613_0.port_a.T; CABI0CabiA003007008.port.T = TC_613_614.port_a.T; CABI0CabiA003007008.port.T = TC_613_626.port_a.T; CABI0CabiA003007008.port.T = TC_613_844.port_a.T; CABI0CabiA003007008.port.T = TsCABI0CabiA003007008.port.T; TsCABI0CabiA002007008.port.Q_flow + (TC_611_612.port_b.Q_flow + (TC_599_612.port_b.Q_flow + (CABI0CabiA002007008.port.Q_flow + (TC_612_613.port_a.Q_flow + (TC_612_625.port_a.Q_flow + (TC_612_843.port_a.Q_flow + TC_612_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002007008.port.T = TC_599_612.port_b.T; CABI0CabiA002007008.port.T = TC_611_612.port_b.T; CABI0CabiA002007008.port.T = TC_612_0.port_a.T; CABI0CabiA002007008.port.T = TC_612_613.port_a.T; CABI0CabiA002007008.port.T = TC_612_625.port_a.T; CABI0CabiA002007008.port.T = TC_612_843.port_a.T; CABI0CabiA002007008.port.T = TsCABI0CabiA002007008.port.T; TsCABI0CabiA001007008.port.Q_flow + (TC_598_611.port_b.Q_flow + (TC_502_611.port_b.Q_flow + (CABI0CabiA001007008.port.Q_flow + (TC_611_612.port_a.Q_flow + (TC_611_624.port_a.Q_flow + TC_611_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001007008.port.T = TC_502_611.port_b.T; CABI0CabiA001007008.port.T = TC_598_611.port_b.T; CABI0CabiA001007008.port.T = TC_611_0.port_a.T; CABI0CabiA001007008.port.T = TC_611_612.port_a.T; CABI0CabiA001007008.port.T = TC_611_624.port_a.T; CABI0CabiA001007008.port.T = TsCABI0CabiA001007008.port.T; TsCABI0CabiA013006008.port.Q_flow + (TC_609_610.port_b.Q_flow + (TC_597_610.port_b.Q_flow + (TC_501_610.port_b.Q_flow + (CABI0CabiA013006008.port.Q_flow + (TC_610_623.port_a.Q_flow + TC_610_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013006008.port.T = TC_501_610.port_b.T; CABI0CabiA013006008.port.T = TC_597_610.port_b.T; CABI0CabiA013006008.port.T = TC_609_610.port_b.T; CABI0CabiA013006008.port.T = TC_610_0.port_a.T; CABI0CabiA013006008.port.T = TC_610_623.port_a.T; CABI0CabiA013006008.port.T = TsCABI0CabiA013006008.port.T; TsCABI0CabiA012006008.port.Q_flow + (TC_608_609.port_b.Q_flow + (TC_596_609.port_b.Q_flow + (CABI0CabiA012006008.port.Q_flow + (TC_609_610.port_a.Q_flow + (TC_609_622.port_a.Q_flow + (TC_609_974.port_a.Q_flow + TC_609_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012006008.port.T = TC_596_609.port_b.T; CABI0CabiA012006008.port.T = TC_608_609.port_b.T; CABI0CabiA012006008.port.T = TC_609_0.port_a.T; CABI0CabiA012006008.port.T = TC_609_610.port_a.T; CABI0CabiA012006008.port.T = TC_609_622.port_a.T; CABI0CabiA012006008.port.T = TC_609_974.port_a.T; CABI0CabiA012006008.port.T = TsCABI0CabiA012006008.port.T; TsCABI0CabiA011006008.port.Q_flow + (TC_607_608.port_b.Q_flow + (TC_595_608.port_b.Q_flow + (CABI0CabiA011006008.port.Q_flow + (TC_608_609.port_a.Q_flow + (TC_608_621.port_a.Q_flow + (TC_608_973.port_a.Q_flow + TC_608_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011006008.port.T = TC_595_608.port_b.T; CABI0CabiA011006008.port.T = TC_607_608.port_b.T; CABI0CabiA011006008.port.T = TC_608_0.port_a.T; CABI0CabiA011006008.port.T = TC_608_609.port_a.T; CABI0CabiA011006008.port.T = TC_608_621.port_a.T; CABI0CabiA011006008.port.T = TC_608_973.port_a.T; CABI0CabiA011006008.port.T = TsCABI0CabiA011006008.port.T; TsCABI0CabiA010006008.port.Q_flow + (TC_606_607.port_b.Q_flow + (TC_594_607.port_b.Q_flow + (CABI0CabiA010006008.port.Q_flow + (TC_607_608.port_a.Q_flow + (TC_607_620.port_a.Q_flow + (TC_607_972.port_a.Q_flow + TC_607_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010006008.port.T = TC_594_607.port_b.T; CABI0CabiA010006008.port.T = TC_606_607.port_b.T; CABI0CabiA010006008.port.T = TC_607_0.port_a.T; CABI0CabiA010006008.port.T = TC_607_608.port_a.T; CABI0CabiA010006008.port.T = TC_607_620.port_a.T; CABI0CabiA010006008.port.T = TC_607_972.port_a.T; CABI0CabiA010006008.port.T = TsCABI0CabiA010006008.port.T; TsCABI0CabiA009006008.port.Q_flow + (TC_605_606.port_b.Q_flow + (TC_593_606.port_b.Q_flow + (CABI0CabiA009006008.port.Q_flow + (TC_606_607.port_a.Q_flow + (TC_606_619.port_a.Q_flow + (TC_606_971.port_a.Q_flow + TC_606_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009006008.port.T = TC_593_606.port_b.T; CABI0CabiA009006008.port.T = TC_605_606.port_b.T; CABI0CabiA009006008.port.T = TC_606_0.port_a.T; CABI0CabiA009006008.port.T = TC_606_607.port_a.T; CABI0CabiA009006008.port.T = TC_606_619.port_a.T; CABI0CabiA009006008.port.T = TC_606_971.port_a.T; CABI0CabiA009006008.port.T = TsCABI0CabiA009006008.port.T; TsCABI0CabiA008006008.port.Q_flow + (TC_604_605.port_b.Q_flow + (TC_592_605.port_b.Q_flow + (CABI0CabiA008006008.port.Q_flow + (TC_605_606.port_a.Q_flow + (TC_605_618.port_a.Q_flow + (TC_605_970.port_a.Q_flow + TC_605_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008006008.port.T = TC_592_605.port_b.T; CABI0CabiA008006008.port.T = TC_604_605.port_b.T; CABI0CabiA008006008.port.T = TC_605_0.port_a.T; CABI0CabiA008006008.port.T = TC_605_606.port_a.T; CABI0CabiA008006008.port.T = TC_605_618.port_a.T; CABI0CabiA008006008.port.T = TC_605_970.port_a.T; CABI0CabiA008006008.port.T = TsCABI0CabiA008006008.port.T; TsCABI0CabiA007006008.port.Q_flow + (TC_603_604.port_b.Q_flow + (TC_591_604.port_b.Q_flow + (CABI0CabiA007006008.port.Q_flow + (TC_604_605.port_a.Q_flow + (TC_604_617.port_a.Q_flow + (TC_604_969.port_a.Q_flow + TC_604_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007006008.port.T = TC_591_604.port_b.T; CABI0CabiA007006008.port.T = TC_603_604.port_b.T; CABI0CabiA007006008.port.T = TC_604_0.port_a.T; CABI0CabiA007006008.port.T = TC_604_605.port_a.T; CABI0CabiA007006008.port.T = TC_604_617.port_a.T; CABI0CabiA007006008.port.T = TC_604_969.port_a.T; CABI0CabiA007006008.port.T = TsCABI0CabiA007006008.port.T; TsCABI0CabiA006006008.port.Q_flow + (TC_602_603.port_b.Q_flow + (TC_590_603.port_b.Q_flow + (CABI0CabiA006006008.port.Q_flow + (TC_603_604.port_a.Q_flow + (TC_603_616.port_a.Q_flow + (TC_603_968.port_a.Q_flow + TC_603_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006006008.port.T = TC_590_603.port_b.T; CABI0CabiA006006008.port.T = TC_602_603.port_b.T; CABI0CabiA006006008.port.T = TC_603_0.port_a.T; CABI0CabiA006006008.port.T = TC_603_604.port_a.T; CABI0CabiA006006008.port.T = TC_603_616.port_a.T; CABI0CabiA006006008.port.T = TC_603_968.port_a.T; CABI0CabiA006006008.port.T = TsCABI0CabiA006006008.port.T; TsCABI0CabiA005006008.port.Q_flow + (TC_601_602.port_b.Q_flow + (TC_589_602.port_b.Q_flow + (CABI0CabiA005006008.port.Q_flow + (TC_602_603.port_a.Q_flow + (TC_602_615.port_a.Q_flow + (TC_602_967.port_a.Q_flow + TC_602_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005006008.port.T = TC_589_602.port_b.T; CABI0CabiA005006008.port.T = TC_601_602.port_b.T; CABI0CabiA005006008.port.T = TC_602_0.port_a.T; CABI0CabiA005006008.port.T = TC_602_603.port_a.T; CABI0CabiA005006008.port.T = TC_602_615.port_a.T; CABI0CabiA005006008.port.T = TC_602_967.port_a.T; CABI0CabiA005006008.port.T = TsCABI0CabiA005006008.port.T; TsCABI0CabiA004006008.port.Q_flow + (TC_600_601.port_b.Q_flow + (TC_588_601.port_b.Q_flow + (CABI0CabiA004006008.port.Q_flow + (TC_601_602.port_a.Q_flow + (TC_601_614.port_a.Q_flow + (TC_601_966.port_a.Q_flow + TC_601_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004006008.port.T = TC_588_601.port_b.T; CABI0CabiA004006008.port.T = TC_600_601.port_b.T; CABI0CabiA004006008.port.T = TC_601_0.port_a.T; CABI0CabiA004006008.port.T = TC_601_602.port_a.T; CABI0CabiA004006008.port.T = TC_601_614.port_a.T; CABI0CabiA004006008.port.T = TC_601_966.port_a.T; CABI0CabiA004006008.port.T = TsCABI0CabiA004006008.port.T; TsCABI0CabiA003006008.port.Q_flow + (TC_599_600.port_b.Q_flow + (TC_587_600.port_b.Q_flow + (CABI0CabiA003006008.port.Q_flow + (TC_600_601.port_a.Q_flow + (TC_600_613.port_a.Q_flow + (TC_600_965.port_a.Q_flow + TC_600_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003006008.port.T = TC_587_600.port_b.T; CABI0CabiA003006008.port.T = TC_599_600.port_b.T; CABI0CabiA003006008.port.T = TC_600_0.port_a.T; CABI0CabiA003006008.port.T = TC_600_601.port_a.T; CABI0CabiA003006008.port.T = TC_600_613.port_a.T; CABI0CabiA003006008.port.T = TC_600_965.port_a.T; CABI0CabiA003006008.port.T = TsCABI0CabiA003006008.port.T; TsCABI0CabiA002006008.port.Q_flow + (TC_598_599.port_b.Q_flow + (TC_586_599.port_b.Q_flow + (CABI0CabiA002006008.port.Q_flow + (TC_599_600.port_a.Q_flow + (TC_599_612.port_a.Q_flow + (TC_599_964.port_a.Q_flow + TC_599_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002006008.port.T = TC_586_599.port_b.T; CABI0CabiA002006008.port.T = TC_598_599.port_b.T; CABI0CabiA002006008.port.T = TC_599_0.port_a.T; CABI0CabiA002006008.port.T = TC_599_600.port_a.T; CABI0CabiA002006008.port.T = TC_599_612.port_a.T; CABI0CabiA002006008.port.T = TC_599_964.port_a.T; CABI0CabiA002006008.port.T = TsCABI0CabiA002006008.port.T; TsCABI0CabiA001006008.port.Q_flow + (TC_585_598.port_b.Q_flow + (TC_500_598.port_b.Q_flow + (CABI0CabiA001006008.port.Q_flow + (TC_598_599.port_a.Q_flow + (TC_598_611.port_a.Q_flow + TC_598_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001006008.port.T = TC_500_598.port_b.T; CABI0CabiA001006008.port.T = TC_585_598.port_b.T; CABI0CabiA001006008.port.T = TC_598_0.port_a.T; CABI0CabiA001006008.port.T = TC_598_599.port_a.T; CABI0CabiA001006008.port.T = TC_598_611.port_a.T; CABI0CabiA001006008.port.T = TsCABI0CabiA001006008.port.T; TsCABI0CabiA013005008.port.Q_flow + (TC_596_597.port_b.Q_flow + (TC_584_597.port_b.Q_flow + (TC_499_597.port_b.Q_flow + (CABI0CabiA013005008.port.Q_flow + (TC_597_610.port_a.Q_flow + TC_597_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013005008.port.T = TC_499_597.port_b.T; CABI0CabiA013005008.port.T = TC_584_597.port_b.T; CABI0CabiA013005008.port.T = TC_596_597.port_b.T; CABI0CabiA013005008.port.T = TC_597_0.port_a.T; CABI0CabiA013005008.port.T = TC_597_610.port_a.T; CABI0CabiA013005008.port.T = TsCABI0CabiA013005008.port.T; TsCABI0CabiA012005008.port.Q_flow + (TC_595_596.port_b.Q_flow + (TC_583_596.port_b.Q_flow + (CABI0CabiA012005008.port.Q_flow + (TC_596_597.port_a.Q_flow + (TC_596_609.port_a.Q_flow + (TC_596_963.port_a.Q_flow + TC_596_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012005008.port.T = TC_583_596.port_b.T; CABI0CabiA012005008.port.T = TC_595_596.port_b.T; CABI0CabiA012005008.port.T = TC_596_0.port_a.T; CABI0CabiA012005008.port.T = TC_596_597.port_a.T; CABI0CabiA012005008.port.T = TC_596_609.port_a.T; CABI0CabiA012005008.port.T = TC_596_963.port_a.T; CABI0CabiA012005008.port.T = TsCABI0CabiA012005008.port.T; TsCABI0CabiA011005008.port.Q_flow + (TC_594_595.port_b.Q_flow + (TC_582_595.port_b.Q_flow + (CABI0CabiA011005008.port.Q_flow + (TC_595_596.port_a.Q_flow + (TC_595_608.port_a.Q_flow + (TC_595_962.port_a.Q_flow + TC_595_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011005008.port.T = TC_582_595.port_b.T; CABI0CabiA011005008.port.T = TC_594_595.port_b.T; CABI0CabiA011005008.port.T = TC_595_0.port_a.T; CABI0CabiA011005008.port.T = TC_595_596.port_a.T; CABI0CabiA011005008.port.T = TC_595_608.port_a.T; CABI0CabiA011005008.port.T = TC_595_962.port_a.T; CABI0CabiA011005008.port.T = TsCABI0CabiA011005008.port.T; TsCABI0CabiA010005008.port.Q_flow + (TC_593_594.port_b.Q_flow + (TC_581_594.port_b.Q_flow + (CABI0CabiA010005008.port.Q_flow + (TC_594_595.port_a.Q_flow + (TC_594_607.port_a.Q_flow + (TC_594_961.port_a.Q_flow + TC_594_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010005008.port.T = TC_581_594.port_b.T; CABI0CabiA010005008.port.T = TC_593_594.port_b.T; CABI0CabiA010005008.port.T = TC_594_0.port_a.T; CABI0CabiA010005008.port.T = TC_594_595.port_a.T; CABI0CabiA010005008.port.T = TC_594_607.port_a.T; CABI0CabiA010005008.port.T = TC_594_961.port_a.T; CABI0CabiA010005008.port.T = TsCABI0CabiA010005008.port.T; TsCABI0CabiA009005008.port.Q_flow + (TC_592_593.port_b.Q_flow + (TC_580_593.port_b.Q_flow + (CABI0CabiA009005008.port.Q_flow + (TC_593_594.port_a.Q_flow + (TC_593_606.port_a.Q_flow + (TC_593_960.port_a.Q_flow + TC_593_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009005008.port.T = TC_580_593.port_b.T; CABI0CabiA009005008.port.T = TC_592_593.port_b.T; CABI0CabiA009005008.port.T = TC_593_0.port_a.T; CABI0CabiA009005008.port.T = TC_593_594.port_a.T; CABI0CabiA009005008.port.T = TC_593_606.port_a.T; CABI0CabiA009005008.port.T = TC_593_960.port_a.T; CABI0CabiA009005008.port.T = TsCABI0CabiA009005008.port.T; TsCABI0CabiA008005008.port.Q_flow + (TC_591_592.port_b.Q_flow + (TC_579_592.port_b.Q_flow + (CABI0CabiA008005008.port.Q_flow + (TC_592_593.port_a.Q_flow + (TC_592_605.port_a.Q_flow + (TC_592_959.port_a.Q_flow + TC_592_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008005008.port.T = TC_579_592.port_b.T; CABI0CabiA008005008.port.T = TC_591_592.port_b.T; CABI0CabiA008005008.port.T = TC_592_0.port_a.T; CABI0CabiA008005008.port.T = TC_592_593.port_a.T; CABI0CabiA008005008.port.T = TC_592_605.port_a.T; CABI0CabiA008005008.port.T = TC_592_959.port_a.T; CABI0CabiA008005008.port.T = TsCABI0CabiA008005008.port.T; TsCABI0CabiA007005008.port.Q_flow + (TC_590_591.port_b.Q_flow + (TC_578_591.port_b.Q_flow + (CABI0CabiA007005008.port.Q_flow + (TC_591_592.port_a.Q_flow + (TC_591_604.port_a.Q_flow + (TC_591_958.port_a.Q_flow + TC_591_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007005008.port.T = TC_578_591.port_b.T; CABI0CabiA007005008.port.T = TC_590_591.port_b.T; CABI0CabiA007005008.port.T = TC_591_0.port_a.T; CABI0CabiA007005008.port.T = TC_591_592.port_a.T; CABI0CabiA007005008.port.T = TC_591_604.port_a.T; CABI0CabiA007005008.port.T = TC_591_958.port_a.T; CABI0CabiA007005008.port.T = TsCABI0CabiA007005008.port.T; TsCABI0CabiA006005008.port.Q_flow + (TC_589_590.port_b.Q_flow + (TC_577_590.port_b.Q_flow + (CABI0CabiA006005008.port.Q_flow + (TC_590_591.port_a.Q_flow + (TC_590_603.port_a.Q_flow + (TC_590_957.port_a.Q_flow + TC_590_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006005008.port.T = TC_577_590.port_b.T; CABI0CabiA006005008.port.T = TC_589_590.port_b.T; CABI0CabiA006005008.port.T = TC_590_0.port_a.T; CABI0CabiA006005008.port.T = TC_590_591.port_a.T; CABI0CabiA006005008.port.T = TC_590_603.port_a.T; CABI0CabiA006005008.port.T = TC_590_957.port_a.T; CABI0CabiA006005008.port.T = TsCABI0CabiA006005008.port.T; TsCABI0CabiA005005008.port.Q_flow + (TC_588_589.port_b.Q_flow + (TC_576_589.port_b.Q_flow + (CABI0CabiA005005008.port.Q_flow + (TC_589_590.port_a.Q_flow + (TC_589_602.port_a.Q_flow + (TC_589_956.port_a.Q_flow + TC_589_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005005008.port.T = TC_576_589.port_b.T; CABI0CabiA005005008.port.T = TC_588_589.port_b.T; CABI0CabiA005005008.port.T = TC_589_0.port_a.T; CABI0CabiA005005008.port.T = TC_589_590.port_a.T; CABI0CabiA005005008.port.T = TC_589_602.port_a.T; CABI0CabiA005005008.port.T = TC_589_956.port_a.T; CABI0CabiA005005008.port.T = TsCABI0CabiA005005008.port.T; TsCABI0CabiA004005008.port.Q_flow + (TC_587_588.port_b.Q_flow + (TC_575_588.port_b.Q_flow + (CABI0CabiA004005008.port.Q_flow + (TC_588_589.port_a.Q_flow + (TC_588_601.port_a.Q_flow + (TC_588_955.port_a.Q_flow + TC_588_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004005008.port.T = TC_575_588.port_b.T; CABI0CabiA004005008.port.T = TC_587_588.port_b.T; CABI0CabiA004005008.port.T = TC_588_0.port_a.T; CABI0CabiA004005008.port.T = TC_588_589.port_a.T; CABI0CabiA004005008.port.T = TC_588_601.port_a.T; CABI0CabiA004005008.port.T = TC_588_955.port_a.T; CABI0CabiA004005008.port.T = TsCABI0CabiA004005008.port.T; TsCABI0CabiA003005008.port.Q_flow + (TC_586_587.port_b.Q_flow + (TC_574_587.port_b.Q_flow + (CABI0CabiA003005008.port.Q_flow + (TC_587_588.port_a.Q_flow + (TC_587_600.port_a.Q_flow + (TC_587_954.port_a.Q_flow + TC_587_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003005008.port.T = TC_574_587.port_b.T; CABI0CabiA003005008.port.T = TC_586_587.port_b.T; CABI0CabiA003005008.port.T = TC_587_0.port_a.T; CABI0CabiA003005008.port.T = TC_587_588.port_a.T; CABI0CabiA003005008.port.T = TC_587_600.port_a.T; CABI0CabiA003005008.port.T = TC_587_954.port_a.T; CABI0CabiA003005008.port.T = TsCABI0CabiA003005008.port.T; TsCABI0CabiA002005008.port.Q_flow + (TC_585_586.port_b.Q_flow + (TC_573_586.port_b.Q_flow + (CABI0CabiA002005008.port.Q_flow + (TC_586_587.port_a.Q_flow + (TC_586_599.port_a.Q_flow + (TC_586_953.port_a.Q_flow + TC_586_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002005008.port.T = TC_573_586.port_b.T; CABI0CabiA002005008.port.T = TC_585_586.port_b.T; CABI0CabiA002005008.port.T = TC_586_0.port_a.T; CABI0CabiA002005008.port.T = TC_586_587.port_a.T; CABI0CabiA002005008.port.T = TC_586_599.port_a.T; CABI0CabiA002005008.port.T = TC_586_953.port_a.T; CABI0CabiA002005008.port.T = TsCABI0CabiA002005008.port.T; TsCABI0CabiA001005008.port.Q_flow + (TC_572_585.port_b.Q_flow + (TC_498_585.port_b.Q_flow + (CABI0CabiA001005008.port.Q_flow + (TC_585_586.port_a.Q_flow + (TC_585_598.port_a.Q_flow + TC_585_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001005008.port.T = TC_498_585.port_b.T; CABI0CabiA001005008.port.T = TC_572_585.port_b.T; CABI0CabiA001005008.port.T = TC_585_0.port_a.T; CABI0CabiA001005008.port.T = TC_585_586.port_a.T; CABI0CabiA001005008.port.T = TC_585_598.port_a.T; CABI0CabiA001005008.port.T = TsCABI0CabiA001005008.port.T; TsCABI0CabiA013004008.port.Q_flow + (TC_583_584.port_b.Q_flow + (TC_571_584.port_b.Q_flow + (TC_497_584.port_b.Q_flow + (CABI0CabiA013004008.port.Q_flow + (TC_584_597.port_a.Q_flow + TC_584_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013004008.port.T = TC_497_584.port_b.T; CABI0CabiA013004008.port.T = TC_571_584.port_b.T; CABI0CabiA013004008.port.T = TC_583_584.port_b.T; CABI0CabiA013004008.port.T = TC_584_0.port_a.T; CABI0CabiA013004008.port.T = TC_584_597.port_a.T; CABI0CabiA013004008.port.T = TsCABI0CabiA013004008.port.T; TsCABI0CabiA012004008.port.Q_flow + (TC_582_583.port_b.Q_flow + (TC_570_583.port_b.Q_flow + (CABI0CabiA012004008.port.Q_flow + (TC_583_584.port_a.Q_flow + (TC_583_596.port_a.Q_flow + (TC_583_952.port_a.Q_flow + TC_583_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012004008.port.T = TC_570_583.port_b.T; CABI0CabiA012004008.port.T = TC_582_583.port_b.T; CABI0CabiA012004008.port.T = TC_583_0.port_a.T; CABI0CabiA012004008.port.T = TC_583_584.port_a.T; CABI0CabiA012004008.port.T = TC_583_596.port_a.T; CABI0CabiA012004008.port.T = TC_583_952.port_a.T; CABI0CabiA012004008.port.T = TsCABI0CabiA012004008.port.T; TsCABI0CabiA011004008.port.Q_flow + (TC_581_582.port_b.Q_flow + (TC_569_582.port_b.Q_flow + (CABI0CabiA011004008.port.Q_flow + (TC_582_583.port_a.Q_flow + (TC_582_595.port_a.Q_flow + (TC_582_951.port_a.Q_flow + TC_582_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011004008.port.T = TC_569_582.port_b.T; CABI0CabiA011004008.port.T = TC_581_582.port_b.T; CABI0CabiA011004008.port.T = TC_582_0.port_a.T; CABI0CabiA011004008.port.T = TC_582_583.port_a.T; CABI0CabiA011004008.port.T = TC_582_595.port_a.T; CABI0CabiA011004008.port.T = TC_582_951.port_a.T; CABI0CabiA011004008.port.T = TsCABI0CabiA011004008.port.T; TsCABI0CabiA010004008.port.Q_flow + (TC_580_581.port_b.Q_flow + (TC_568_581.port_b.Q_flow + (CABI0CabiA010004008.port.Q_flow + (TC_581_582.port_a.Q_flow + (TC_581_594.port_a.Q_flow + (TC_581_950.port_a.Q_flow + TC_581_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010004008.port.T = TC_568_581.port_b.T; CABI0CabiA010004008.port.T = TC_580_581.port_b.T; CABI0CabiA010004008.port.T = TC_581_0.port_a.T; CABI0CabiA010004008.port.T = TC_581_582.port_a.T; CABI0CabiA010004008.port.T = TC_581_594.port_a.T; CABI0CabiA010004008.port.T = TC_581_950.port_a.T; CABI0CabiA010004008.port.T = TsCABI0CabiA010004008.port.T; TsCABI0CabiA009004008.port.Q_flow + (TC_579_580.port_b.Q_flow + (TC_567_580.port_b.Q_flow + (CABI0CabiA009004008.port.Q_flow + (TC_580_581.port_a.Q_flow + (TC_580_593.port_a.Q_flow + (TC_580_949.port_a.Q_flow + TC_580_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009004008.port.T = TC_567_580.port_b.T; CABI0CabiA009004008.port.T = TC_579_580.port_b.T; CABI0CabiA009004008.port.T = TC_580_0.port_a.T; CABI0CabiA009004008.port.T = TC_580_581.port_a.T; CABI0CabiA009004008.port.T = TC_580_593.port_a.T; CABI0CabiA009004008.port.T = TC_580_949.port_a.T; CABI0CabiA009004008.port.T = TsCABI0CabiA009004008.port.T; TsCABI0CabiA008004008.port.Q_flow + (TC_578_579.port_b.Q_flow + (TC_566_579.port_b.Q_flow + (CABI0CabiA008004008.port.Q_flow + (TC_579_580.port_a.Q_flow + (TC_579_592.port_a.Q_flow + (TC_579_948.port_a.Q_flow + TC_579_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008004008.port.T = TC_566_579.port_b.T; CABI0CabiA008004008.port.T = TC_578_579.port_b.T; CABI0CabiA008004008.port.T = TC_579_0.port_a.T; CABI0CabiA008004008.port.T = TC_579_580.port_a.T; CABI0CabiA008004008.port.T = TC_579_592.port_a.T; CABI0CabiA008004008.port.T = TC_579_948.port_a.T; CABI0CabiA008004008.port.T = TsCABI0CabiA008004008.port.T; TsCABI0CabiA007004008.port.Q_flow + (TC_577_578.port_b.Q_flow + (TC_565_578.port_b.Q_flow + (CABI0CabiA007004008.port.Q_flow + (TC_578_579.port_a.Q_flow + (TC_578_591.port_a.Q_flow + (TC_578_947.port_a.Q_flow + TC_578_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007004008.port.T = TC_565_578.port_b.T; CABI0CabiA007004008.port.T = TC_577_578.port_b.T; CABI0CabiA007004008.port.T = TC_578_0.port_a.T; CABI0CabiA007004008.port.T = TC_578_579.port_a.T; CABI0CabiA007004008.port.T = TC_578_591.port_a.T; CABI0CabiA007004008.port.T = TC_578_947.port_a.T; CABI0CabiA007004008.port.T = TsCABI0CabiA007004008.port.T; TsCABI0CabiA006004008.port.Q_flow + (TC_576_577.port_b.Q_flow + (TC_564_577.port_b.Q_flow + (CABI0CabiA006004008.port.Q_flow + (TC_577_578.port_a.Q_flow + (TC_577_590.port_a.Q_flow + (TC_577_946.port_a.Q_flow + TC_577_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006004008.port.T = TC_564_577.port_b.T; CABI0CabiA006004008.port.T = TC_576_577.port_b.T; CABI0CabiA006004008.port.T = TC_577_0.port_a.T; CABI0CabiA006004008.port.T = TC_577_578.port_a.T; CABI0CabiA006004008.port.T = TC_577_590.port_a.T; CABI0CabiA006004008.port.T = TC_577_946.port_a.T; CABI0CabiA006004008.port.T = TsCABI0CabiA006004008.port.T; TsCABI0CabiA005004008.port.Q_flow + (TC_575_576.port_b.Q_flow + (TC_563_576.port_b.Q_flow + (CABI0CabiA005004008.port.Q_flow + (TC_576_577.port_a.Q_flow + (TC_576_589.port_a.Q_flow + (TC_576_945.port_a.Q_flow + TC_576_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005004008.port.T = TC_563_576.port_b.T; CABI0CabiA005004008.port.T = TC_575_576.port_b.T; CABI0CabiA005004008.port.T = TC_576_0.port_a.T; CABI0CabiA005004008.port.T = TC_576_577.port_a.T; CABI0CabiA005004008.port.T = TC_576_589.port_a.T; CABI0CabiA005004008.port.T = TC_576_945.port_a.T; CABI0CabiA005004008.port.T = TsCABI0CabiA005004008.port.T; TsCABI0CabiA004004008.port.Q_flow + (TC_574_575.port_b.Q_flow + (TC_562_575.port_b.Q_flow + (CABI0CabiA004004008.port.Q_flow + (TC_575_576.port_a.Q_flow + (TC_575_588.port_a.Q_flow + (TC_575_944.port_a.Q_flow + TC_575_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004004008.port.T = TC_562_575.port_b.T; CABI0CabiA004004008.port.T = TC_574_575.port_b.T; CABI0CabiA004004008.port.T = TC_575_0.port_a.T; CABI0CabiA004004008.port.T = TC_575_576.port_a.T; CABI0CabiA004004008.port.T = TC_575_588.port_a.T; CABI0CabiA004004008.port.T = TC_575_944.port_a.T; CABI0CabiA004004008.port.T = TsCABI0CabiA004004008.port.T; TsCABI0CabiA003004008.port.Q_flow + (TC_573_574.port_b.Q_flow + (TC_561_574.port_b.Q_flow + (CABI0CabiA003004008.port.Q_flow + (TC_574_575.port_a.Q_flow + (TC_574_587.port_a.Q_flow + (TC_574_943.port_a.Q_flow + TC_574_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003004008.port.T = TC_561_574.port_b.T; CABI0CabiA003004008.port.T = TC_573_574.port_b.T; CABI0CabiA003004008.port.T = TC_574_0.port_a.T; CABI0CabiA003004008.port.T = TC_574_575.port_a.T; CABI0CabiA003004008.port.T = TC_574_587.port_a.T; CABI0CabiA003004008.port.T = TC_574_943.port_a.T; CABI0CabiA003004008.port.T = TsCABI0CabiA003004008.port.T; TsCABI0CabiA002004008.port.Q_flow + (TC_572_573.port_b.Q_flow + (TC_560_573.port_b.Q_flow + (CABI0CabiA002004008.port.Q_flow + (TC_573_574.port_a.Q_flow + (TC_573_586.port_a.Q_flow + (TC_573_942.port_a.Q_flow + TC_573_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002004008.port.T = TC_560_573.port_b.T; CABI0CabiA002004008.port.T = TC_572_573.port_b.T; CABI0CabiA002004008.port.T = TC_573_0.port_a.T; CABI0CabiA002004008.port.T = TC_573_574.port_a.T; CABI0CabiA002004008.port.T = TC_573_586.port_a.T; CABI0CabiA002004008.port.T = TC_573_942.port_a.T; CABI0CabiA002004008.port.T = TsCABI0CabiA002004008.port.T; TsCABI0CabiA001004008.port.Q_flow + (TC_559_572.port_b.Q_flow + (TC_496_572.port_b.Q_flow + (CABI0CabiA001004008.port.Q_flow + (TC_572_573.port_a.Q_flow + (TC_572_585.port_a.Q_flow + TC_572_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001004008.port.T = TC_496_572.port_b.T; CABI0CabiA001004008.port.T = TC_559_572.port_b.T; CABI0CabiA001004008.port.T = TC_572_0.port_a.T; CABI0CabiA001004008.port.T = TC_572_573.port_a.T; CABI0CabiA001004008.port.T = TC_572_585.port_a.T; CABI0CabiA001004008.port.T = TsCABI0CabiA001004008.port.T; TsCABI0CabiA013003008.port.Q_flow + (TC_570_571.port_b.Q_flow + (TC_558_571.port_b.Q_flow + (TC_495_571.port_b.Q_flow + (CABI0CabiA013003008.port.Q_flow + (TC_571_584.port_a.Q_flow + TC_571_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013003008.port.T = TC_495_571.port_b.T; CABI0CabiA013003008.port.T = TC_558_571.port_b.T; CABI0CabiA013003008.port.T = TC_570_571.port_b.T; CABI0CabiA013003008.port.T = TC_571_0.port_a.T; CABI0CabiA013003008.port.T = TC_571_584.port_a.T; CABI0CabiA013003008.port.T = TsCABI0CabiA013003008.port.T; TsCABI0CabiA012003008.port.Q_flow + (TC_569_570.port_b.Q_flow + (TC_557_570.port_b.Q_flow + (CABI0CabiA012003008.port.Q_flow + (TC_570_571.port_a.Q_flow + (TC_570_583.port_a.Q_flow + (TC_570_941.port_a.Q_flow + TC_570_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012003008.port.T = TC_557_570.port_b.T; CABI0CabiA012003008.port.T = TC_569_570.port_b.T; CABI0CabiA012003008.port.T = TC_570_0.port_a.T; CABI0CabiA012003008.port.T = TC_570_571.port_a.T; CABI0CabiA012003008.port.T = TC_570_583.port_a.T; CABI0CabiA012003008.port.T = TC_570_941.port_a.T; CABI0CabiA012003008.port.T = TsCABI0CabiA012003008.port.T; TsCABI0CabiA011003008.port.Q_flow + (TC_568_569.port_b.Q_flow + (TC_556_569.port_b.Q_flow + (CABI0CabiA011003008.port.Q_flow + (TC_569_570.port_a.Q_flow + (TC_569_582.port_a.Q_flow + (TC_569_940.port_a.Q_flow + TC_569_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011003008.port.T = TC_556_569.port_b.T; CABI0CabiA011003008.port.T = TC_568_569.port_b.T; CABI0CabiA011003008.port.T = TC_569_0.port_a.T; CABI0CabiA011003008.port.T = TC_569_570.port_a.T; CABI0CabiA011003008.port.T = TC_569_582.port_a.T; CABI0CabiA011003008.port.T = TC_569_940.port_a.T; CABI0CabiA011003008.port.T = TsCABI0CabiA011003008.port.T; TsCABI0CabiA010003008.port.Q_flow + (TC_567_568.port_b.Q_flow + (TC_555_568.port_b.Q_flow + (CABI0CabiA010003008.port.Q_flow + (TC_568_569.port_a.Q_flow + (TC_568_581.port_a.Q_flow + (TC_568_939.port_a.Q_flow + TC_568_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010003008.port.T = TC_555_568.port_b.T; CABI0CabiA010003008.port.T = TC_567_568.port_b.T; CABI0CabiA010003008.port.T = TC_568_0.port_a.T; CABI0CabiA010003008.port.T = TC_568_569.port_a.T; CABI0CabiA010003008.port.T = TC_568_581.port_a.T; CABI0CabiA010003008.port.T = TC_568_939.port_a.T; CABI0CabiA010003008.port.T = TsCABI0CabiA010003008.port.T; TsCABI0CabiA009003008.port.Q_flow + (TC_566_567.port_b.Q_flow + (TC_554_567.port_b.Q_flow + (CABI0CabiA009003008.port.Q_flow + (TC_567_568.port_a.Q_flow + (TC_567_580.port_a.Q_flow + (TC_567_938.port_a.Q_flow + TC_567_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009003008.port.T = TC_554_567.port_b.T; CABI0CabiA009003008.port.T = TC_566_567.port_b.T; CABI0CabiA009003008.port.T = TC_567_0.port_a.T; CABI0CabiA009003008.port.T = TC_567_568.port_a.T; CABI0CabiA009003008.port.T = TC_567_580.port_a.T; CABI0CabiA009003008.port.T = TC_567_938.port_a.T; CABI0CabiA009003008.port.T = TsCABI0CabiA009003008.port.T; TsCABI0CabiA008003008.port.Q_flow + (TC_565_566.port_b.Q_flow + (TC_553_566.port_b.Q_flow + (CABI0CabiA008003008.port.Q_flow + (TC_566_567.port_a.Q_flow + (TC_566_579.port_a.Q_flow + (TC_566_937.port_a.Q_flow + TC_566_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008003008.port.T = TC_553_566.port_b.T; CABI0CabiA008003008.port.T = TC_565_566.port_b.T; CABI0CabiA008003008.port.T = TC_566_0.port_a.T; CABI0CabiA008003008.port.T = TC_566_567.port_a.T; CABI0CabiA008003008.port.T = TC_566_579.port_a.T; CABI0CabiA008003008.port.T = TC_566_937.port_a.T; CABI0CabiA008003008.port.T = TsCABI0CabiA008003008.port.T; TsCABI0CabiA007003008.port.Q_flow + (TC_564_565.port_b.Q_flow + (TC_552_565.port_b.Q_flow + (CABI0CabiA007003008.port.Q_flow + (TC_565_566.port_a.Q_flow + (TC_565_578.port_a.Q_flow + (TC_565_936.port_a.Q_flow + TC_565_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007003008.port.T = TC_552_565.port_b.T; CABI0CabiA007003008.port.T = TC_564_565.port_b.T; CABI0CabiA007003008.port.T = TC_565_0.port_a.T; CABI0CabiA007003008.port.T = TC_565_566.port_a.T; CABI0CabiA007003008.port.T = TC_565_578.port_a.T; CABI0CabiA007003008.port.T = TC_565_936.port_a.T; CABI0CabiA007003008.port.T = TsCABI0CabiA007003008.port.T; TsCABI0CabiA006003008.port.Q_flow + (TC_563_564.port_b.Q_flow + (TC_551_564.port_b.Q_flow + (CABI0CabiA006003008.port.Q_flow + (TC_564_565.port_a.Q_flow + (TC_564_577.port_a.Q_flow + (TC_564_935.port_a.Q_flow + TC_564_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006003008.port.T = TC_551_564.port_b.T; CABI0CabiA006003008.port.T = TC_563_564.port_b.T; CABI0CabiA006003008.port.T = TC_564_0.port_a.T; CABI0CabiA006003008.port.T = TC_564_565.port_a.T; CABI0CabiA006003008.port.T = TC_564_577.port_a.T; CABI0CabiA006003008.port.T = TC_564_935.port_a.T; CABI0CabiA006003008.port.T = TsCABI0CabiA006003008.port.T; TsCABI0CabiA005003008.port.Q_flow + (TC_562_563.port_b.Q_flow + (TC_550_563.port_b.Q_flow + (CABI0CabiA005003008.port.Q_flow + (TC_563_564.port_a.Q_flow + (TC_563_576.port_a.Q_flow + (TC_563_934.port_a.Q_flow + TC_563_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005003008.port.T = TC_550_563.port_b.T; CABI0CabiA005003008.port.T = TC_562_563.port_b.T; CABI0CabiA005003008.port.T = TC_563_0.port_a.T; CABI0CabiA005003008.port.T = TC_563_564.port_a.T; CABI0CabiA005003008.port.T = TC_563_576.port_a.T; CABI0CabiA005003008.port.T = TC_563_934.port_a.T; CABI0CabiA005003008.port.T = TsCABI0CabiA005003008.port.T; TsCABI0CabiA004003008.port.Q_flow + (TC_561_562.port_b.Q_flow + (TC_549_562.port_b.Q_flow + (CABI0CabiA004003008.port.Q_flow + (TC_562_563.port_a.Q_flow + (TC_562_575.port_a.Q_flow + (TC_562_933.port_a.Q_flow + TC_562_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004003008.port.T = TC_549_562.port_b.T; CABI0CabiA004003008.port.T = TC_561_562.port_b.T; CABI0CabiA004003008.port.T = TC_562_0.port_a.T; CABI0CabiA004003008.port.T = TC_562_563.port_a.T; CABI0CabiA004003008.port.T = TC_562_575.port_a.T; CABI0CabiA004003008.port.T = TC_562_933.port_a.T; CABI0CabiA004003008.port.T = TsCABI0CabiA004003008.port.T; TsCABI0CabiA003003008.port.Q_flow + (TC_560_561.port_b.Q_flow + (TC_548_561.port_b.Q_flow + (CABI0CabiA003003008.port.Q_flow + (TC_561_562.port_a.Q_flow + (TC_561_574.port_a.Q_flow + (TC_561_932.port_a.Q_flow + TC_561_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003003008.port.T = TC_548_561.port_b.T; CABI0CabiA003003008.port.T = TC_560_561.port_b.T; CABI0CabiA003003008.port.T = TC_561_0.port_a.T; CABI0CabiA003003008.port.T = TC_561_562.port_a.T; CABI0CabiA003003008.port.T = TC_561_574.port_a.T; CABI0CabiA003003008.port.T = TC_561_932.port_a.T; CABI0CabiA003003008.port.T = TsCABI0CabiA003003008.port.T; TsCABI0CabiA002003008.port.Q_flow + (TC_559_560.port_b.Q_flow + (TC_547_560.port_b.Q_flow + (CABI0CabiA002003008.port.Q_flow + (TC_560_561.port_a.Q_flow + (TC_560_573.port_a.Q_flow + (TC_560_931.port_a.Q_flow + TC_560_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002003008.port.T = TC_547_560.port_b.T; CABI0CabiA002003008.port.T = TC_559_560.port_b.T; CABI0CabiA002003008.port.T = TC_560_0.port_a.T; CABI0CabiA002003008.port.T = TC_560_561.port_a.T; CABI0CabiA002003008.port.T = TC_560_573.port_a.T; CABI0CabiA002003008.port.T = TC_560_931.port_a.T; CABI0CabiA002003008.port.T = TsCABI0CabiA002003008.port.T; TsCABI0CabiA001003008.port.Q_flow + (TC_546_559.port_b.Q_flow + (TC_494_559.port_b.Q_flow + (CABI0CabiA001003008.port.Q_flow + (TC_559_560.port_a.Q_flow + (TC_559_572.port_a.Q_flow + TC_559_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001003008.port.T = TC_494_559.port_b.T; CABI0CabiA001003008.port.T = TC_546_559.port_b.T; CABI0CabiA001003008.port.T = TC_559_0.port_a.T; CABI0CabiA001003008.port.T = TC_559_560.port_a.T; CABI0CabiA001003008.port.T = TC_559_572.port_a.T; CABI0CabiA001003008.port.T = TsCABI0CabiA001003008.port.T; TsCABI0CabiA013002008.port.Q_flow + (TC_557_558.port_b.Q_flow + (TC_545_558.port_b.Q_flow + (TC_493_558.port_b.Q_flow + (CABI0CabiA013002008.port.Q_flow + (TC_558_571.port_a.Q_flow + TC_558_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013002008.port.T = TC_493_558.port_b.T; CABI0CabiA013002008.port.T = TC_545_558.port_b.T; CABI0CabiA013002008.port.T = TC_557_558.port_b.T; CABI0CabiA013002008.port.T = TC_558_0.port_a.T; CABI0CabiA013002008.port.T = TC_558_571.port_a.T; CABI0CabiA013002008.port.T = TsCABI0CabiA013002008.port.T; TsCABI0CabiA012002008.port.Q_flow + (TC_556_557.port_b.Q_flow + (TC_544_557.port_b.Q_flow + (CABI0CabiA012002008.port.Q_flow + (TC_557_558.port_a.Q_flow + (TC_557_570.port_a.Q_flow + (TC_557_930.port_a.Q_flow + TC_557_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012002008.port.T = TC_544_557.port_b.T; CABI0CabiA012002008.port.T = TC_556_557.port_b.T; CABI0CabiA012002008.port.T = TC_557_0.port_a.T; CABI0CabiA012002008.port.T = TC_557_558.port_a.T; CABI0CabiA012002008.port.T = TC_557_570.port_a.T; CABI0CabiA012002008.port.T = TC_557_930.port_a.T; CABI0CabiA012002008.port.T = TsCABI0CabiA012002008.port.T; TsCABI0CabiA011002008.port.Q_flow + (TC_555_556.port_b.Q_flow + (TC_543_556.port_b.Q_flow + (CABI0CabiA011002008.port.Q_flow + (TC_556_557.port_a.Q_flow + (TC_556_569.port_a.Q_flow + (TC_556_929.port_a.Q_flow + TC_556_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011002008.port.T = TC_543_556.port_b.T; CABI0CabiA011002008.port.T = TC_555_556.port_b.T; CABI0CabiA011002008.port.T = TC_556_0.port_a.T; CABI0CabiA011002008.port.T = TC_556_557.port_a.T; CABI0CabiA011002008.port.T = TC_556_569.port_a.T; CABI0CabiA011002008.port.T = TC_556_929.port_a.T; CABI0CabiA011002008.port.T = TsCABI0CabiA011002008.port.T; TsCABI0CabiA010002008.port.Q_flow + (TC_554_555.port_b.Q_flow + (TC_542_555.port_b.Q_flow + (CABI0CabiA010002008.port.Q_flow + (TC_555_556.port_a.Q_flow + (TC_555_568.port_a.Q_flow + (TC_555_928.port_a.Q_flow + TC_555_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010002008.port.T = TC_542_555.port_b.T; CABI0CabiA010002008.port.T = TC_554_555.port_b.T; CABI0CabiA010002008.port.T = TC_555_0.port_a.T; CABI0CabiA010002008.port.T = TC_555_556.port_a.T; CABI0CabiA010002008.port.T = TC_555_568.port_a.T; CABI0CabiA010002008.port.T = TC_555_928.port_a.T; CABI0CabiA010002008.port.T = TsCABI0CabiA010002008.port.T; TsCABI0CabiA009002008.port.Q_flow + (TC_553_554.port_b.Q_flow + (TC_541_554.port_b.Q_flow + (CABI0CabiA009002008.port.Q_flow + (TC_554_555.port_a.Q_flow + (TC_554_567.port_a.Q_flow + (TC_554_927.port_a.Q_flow + TC_554_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009002008.port.T = TC_541_554.port_b.T; CABI0CabiA009002008.port.T = TC_553_554.port_b.T; CABI0CabiA009002008.port.T = TC_554_0.port_a.T; CABI0CabiA009002008.port.T = TC_554_555.port_a.T; CABI0CabiA009002008.port.T = TC_554_567.port_a.T; CABI0CabiA009002008.port.T = TC_554_927.port_a.T; CABI0CabiA009002008.port.T = TsCABI0CabiA009002008.port.T; TsCABI0CabiA008002008.port.Q_flow + (TC_552_553.port_b.Q_flow + (TC_540_553.port_b.Q_flow + (CABI0CabiA008002008.port.Q_flow + (TC_553_554.port_a.Q_flow + (TC_553_566.port_a.Q_flow + (TC_553_926.port_a.Q_flow + TC_553_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008002008.port.T = TC_540_553.port_b.T; CABI0CabiA008002008.port.T = TC_552_553.port_b.T; CABI0CabiA008002008.port.T = TC_553_0.port_a.T; CABI0CabiA008002008.port.T = TC_553_554.port_a.T; CABI0CabiA008002008.port.T = TC_553_566.port_a.T; CABI0CabiA008002008.port.T = TC_553_926.port_a.T; CABI0CabiA008002008.port.T = TsCABI0CabiA008002008.port.T; TsCABI0CabiA007002008.port.Q_flow + (TC_551_552.port_b.Q_flow + (TC_539_552.port_b.Q_flow + (CABI0CabiA007002008.port.Q_flow + (TC_552_553.port_a.Q_flow + (TC_552_565.port_a.Q_flow + (TC_552_925.port_a.Q_flow + TC_552_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007002008.port.T = TC_539_552.port_b.T; CABI0CabiA007002008.port.T = TC_551_552.port_b.T; CABI0CabiA007002008.port.T = TC_552_0.port_a.T; CABI0CabiA007002008.port.T = TC_552_553.port_a.T; CABI0CabiA007002008.port.T = TC_552_565.port_a.T; CABI0CabiA007002008.port.T = TC_552_925.port_a.T; CABI0CabiA007002008.port.T = TsCABI0CabiA007002008.port.T; TsCABI0CabiA006002008.port.Q_flow + (TC_550_551.port_b.Q_flow + (TC_538_551.port_b.Q_flow + (CABI0CabiA006002008.port.Q_flow + (TC_551_552.port_a.Q_flow + (TC_551_564.port_a.Q_flow + (TC_551_924.port_a.Q_flow + TC_551_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006002008.port.T = TC_538_551.port_b.T; CABI0CabiA006002008.port.T = TC_550_551.port_b.T; CABI0CabiA006002008.port.T = TC_551_0.port_a.T; CABI0CabiA006002008.port.T = TC_551_552.port_a.T; CABI0CabiA006002008.port.T = TC_551_564.port_a.T; CABI0CabiA006002008.port.T = TC_551_924.port_a.T; CABI0CabiA006002008.port.T = TsCABI0CabiA006002008.port.T; TsCABI0CabiA005002008.port.Q_flow + (TC_549_550.port_b.Q_flow + (TC_537_550.port_b.Q_flow + (CABI0CabiA005002008.port.Q_flow + (TC_550_551.port_a.Q_flow + (TC_550_563.port_a.Q_flow + (TC_550_923.port_a.Q_flow + TC_550_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005002008.port.T = TC_537_550.port_b.T; CABI0CabiA005002008.port.T = TC_549_550.port_b.T; CABI0CabiA005002008.port.T = TC_550_0.port_a.T; CABI0CabiA005002008.port.T = TC_550_551.port_a.T; CABI0CabiA005002008.port.T = TC_550_563.port_a.T; CABI0CabiA005002008.port.T = TC_550_923.port_a.T; CABI0CabiA005002008.port.T = TsCABI0CabiA005002008.port.T; TsCABI0CabiA004002008.port.Q_flow + (TC_548_549.port_b.Q_flow + (TC_536_549.port_b.Q_flow + (CABI0CabiA004002008.port.Q_flow + (TC_549_550.port_a.Q_flow + (TC_549_562.port_a.Q_flow + (TC_549_922.port_a.Q_flow + TC_549_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004002008.port.T = TC_536_549.port_b.T; CABI0CabiA004002008.port.T = TC_548_549.port_b.T; CABI0CabiA004002008.port.T = TC_549_0.port_a.T; CABI0CabiA004002008.port.T = TC_549_550.port_a.T; CABI0CabiA004002008.port.T = TC_549_562.port_a.T; CABI0CabiA004002008.port.T = TC_549_922.port_a.T; CABI0CabiA004002008.port.T = TsCABI0CabiA004002008.port.T; TsCABI0CabiA003002008.port.Q_flow + (TC_547_548.port_b.Q_flow + (TC_535_548.port_b.Q_flow + (CABI0CabiA003002008.port.Q_flow + (TC_548_549.port_a.Q_flow + (TC_548_561.port_a.Q_flow + (TC_548_921.port_a.Q_flow + TC_548_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003002008.port.T = TC_535_548.port_b.T; CABI0CabiA003002008.port.T = TC_547_548.port_b.T; CABI0CabiA003002008.port.T = TC_548_0.port_a.T; CABI0CabiA003002008.port.T = TC_548_549.port_a.T; CABI0CabiA003002008.port.T = TC_548_561.port_a.T; CABI0CabiA003002008.port.T = TC_548_921.port_a.T; CABI0CabiA003002008.port.T = TsCABI0CabiA003002008.port.T; TsCABI0CabiA002002008.port.Q_flow + (TC_546_547.port_b.Q_flow + (TC_534_547.port_b.Q_flow + (CABI0CabiA002002008.port.Q_flow + (TC_547_548.port_a.Q_flow + (TC_547_560.port_a.Q_flow + (TC_547_920.port_a.Q_flow + TC_547_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002002008.port.T = TC_534_547.port_b.T; CABI0CabiA002002008.port.T = TC_546_547.port_b.T; CABI0CabiA002002008.port.T = TC_547_0.port_a.T; CABI0CabiA002002008.port.T = TC_547_548.port_a.T; CABI0CabiA002002008.port.T = TC_547_560.port_a.T; CABI0CabiA002002008.port.T = TC_547_920.port_a.T; CABI0CabiA002002008.port.T = TsCABI0CabiA002002008.port.T; TsCABI0CabiA001002008.port.Q_flow + (TC_533_546.port_b.Q_flow + (TC_492_546.port_b.Q_flow + (CABI0CabiA001002008.port.Q_flow + (TC_546_547.port_a.Q_flow + (TC_546_559.port_a.Q_flow + TC_546_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001002008.port.T = TC_492_546.port_b.T; CABI0CabiA001002008.port.T = TC_533_546.port_b.T; CABI0CabiA001002008.port.T = TC_546_0.port_a.T; CABI0CabiA001002008.port.T = TC_546_547.port_a.T; CABI0CabiA001002008.port.T = TC_546_559.port_a.T; CABI0CabiA001002008.port.T = TsCABI0CabiA001002008.port.T; TsCABI0CabiA013001008.port.Q_flow + (TC_544_545.port_b.Q_flow + (TC_491_545.port_b.Q_flow + (CABI0CabiA013001008.port.Q_flow + (TC_545_558.port_a.Q_flow + TC_545_0.port_a.Q_flow)))) = 0.0; CABI0CabiA013001008.port.T = TC_491_545.port_b.T; CABI0CabiA013001008.port.T = TC_544_545.port_b.T; CABI0CabiA013001008.port.T = TC_545_0.port_a.T; CABI0CabiA013001008.port.T = TC_545_558.port_a.T; CABI0CabiA013001008.port.T = TsCABI0CabiA013001008.port.T; TsCABI0CabiA012001008.port.Q_flow + (TC_543_544.port_b.Q_flow + (TC_490_544.port_b.Q_flow + (CABI0CabiA012001008.port.Q_flow + (TC_544_545.port_a.Q_flow + (TC_544_557.port_a.Q_flow + TC_544_0.port_a.Q_flow))))) = 0.0; CABI0CabiA012001008.port.T = TC_490_544.port_b.T; CABI0CabiA012001008.port.T = TC_543_544.port_b.T; CABI0CabiA012001008.port.T = TC_544_0.port_a.T; CABI0CabiA012001008.port.T = TC_544_545.port_a.T; CABI0CabiA012001008.port.T = TC_544_557.port_a.T; CABI0CabiA012001008.port.T = TsCABI0CabiA012001008.port.T; TsCABI0CabiA011001008.port.Q_flow + (TC_542_543.port_b.Q_flow + (TC_489_543.port_b.Q_flow + (CABI0CabiA011001008.port.Q_flow + (TC_543_544.port_a.Q_flow + (TC_543_556.port_a.Q_flow + TC_543_0.port_a.Q_flow))))) = 0.0; CABI0CabiA011001008.port.T = TC_489_543.port_b.T; CABI0CabiA011001008.port.T = TC_542_543.port_b.T; CABI0CabiA011001008.port.T = TC_543_0.port_a.T; CABI0CabiA011001008.port.T = TC_543_544.port_a.T; CABI0CabiA011001008.port.T = TC_543_556.port_a.T; CABI0CabiA011001008.port.T = TsCABI0CabiA011001008.port.T; TsCABI0CabiA010001008.port.Q_flow + (TC_541_542.port_b.Q_flow + (TC_488_542.port_b.Q_flow + (CABI0CabiA010001008.port.Q_flow + (TC_542_543.port_a.Q_flow + (TC_542_555.port_a.Q_flow + TC_542_0.port_a.Q_flow))))) = 0.0; CABI0CabiA010001008.port.T = TC_488_542.port_b.T; CABI0CabiA010001008.port.T = TC_541_542.port_b.T; CABI0CabiA010001008.port.T = TC_542_0.port_a.T; CABI0CabiA010001008.port.T = TC_542_543.port_a.T; CABI0CabiA010001008.port.T = TC_542_555.port_a.T; CABI0CabiA010001008.port.T = TsCABI0CabiA010001008.port.T; TsCABI0CabiA009001008.port.Q_flow + (TC_540_541.port_b.Q_flow + (TC_487_541.port_b.Q_flow + (CABI0CabiA009001008.port.Q_flow + (TC_541_542.port_a.Q_flow + (TC_541_554.port_a.Q_flow + TC_541_0.port_a.Q_flow))))) = 0.0; CABI0CabiA009001008.port.T = TC_487_541.port_b.T; CABI0CabiA009001008.port.T = TC_540_541.port_b.T; CABI0CabiA009001008.port.T = TC_541_0.port_a.T; CABI0CabiA009001008.port.T = TC_541_542.port_a.T; CABI0CabiA009001008.port.T = TC_541_554.port_a.T; CABI0CabiA009001008.port.T = TsCABI0CabiA009001008.port.T; TsCABI0CabiA008001008.port.Q_flow + (TC_539_540.port_b.Q_flow + (TC_486_540.port_b.Q_flow + (CABI0CabiA008001008.port.Q_flow + (TC_540_541.port_a.Q_flow + (TC_540_553.port_a.Q_flow + TC_540_0.port_a.Q_flow))))) = 0.0; CABI0CabiA008001008.port.T = TC_486_540.port_b.T; CABI0CabiA008001008.port.T = TC_539_540.port_b.T; CABI0CabiA008001008.port.T = TC_540_0.port_a.T; CABI0CabiA008001008.port.T = TC_540_541.port_a.T; CABI0CabiA008001008.port.T = TC_540_553.port_a.T; CABI0CabiA008001008.port.T = TsCABI0CabiA008001008.port.T; TsCABI0CabiA007001008.port.Q_flow + (TC_538_539.port_b.Q_flow + (TC_485_539.port_b.Q_flow + (CABI0CabiA007001008.port.Q_flow + (TC_539_540.port_a.Q_flow + (TC_539_552.port_a.Q_flow + TC_539_0.port_a.Q_flow))))) = 0.0; CABI0CabiA007001008.port.T = TC_485_539.port_b.T; CABI0CabiA007001008.port.T = TC_538_539.port_b.T; CABI0CabiA007001008.port.T = TC_539_0.port_a.T; CABI0CabiA007001008.port.T = TC_539_540.port_a.T; CABI0CabiA007001008.port.T = TC_539_552.port_a.T; CABI0CabiA007001008.port.T = TsCABI0CabiA007001008.port.T; TsCABI0CabiA006001008.port.Q_flow + (TC_537_538.port_b.Q_flow + (TC_484_538.port_b.Q_flow + (CABI0CabiA006001008.port.Q_flow + (TC_538_539.port_a.Q_flow + (TC_538_551.port_a.Q_flow + TC_538_0.port_a.Q_flow))))) = 0.0; CABI0CabiA006001008.port.T = TC_484_538.port_b.T; CABI0CabiA006001008.port.T = TC_537_538.port_b.T; CABI0CabiA006001008.port.T = TC_538_0.port_a.T; CABI0CabiA006001008.port.T = TC_538_539.port_a.T; CABI0CabiA006001008.port.T = TC_538_551.port_a.T; CABI0CabiA006001008.port.T = TsCABI0CabiA006001008.port.T; TsCABI0CabiA005001008.port.Q_flow + (TC_536_537.port_b.Q_flow + (TC_483_537.port_b.Q_flow + (CABI0CabiA005001008.port.Q_flow + (TC_537_538.port_a.Q_flow + (TC_537_550.port_a.Q_flow + TC_537_0.port_a.Q_flow))))) = 0.0; CABI0CabiA005001008.port.T = TC_483_537.port_b.T; CABI0CabiA005001008.port.T = TC_536_537.port_b.T; CABI0CabiA005001008.port.T = TC_537_0.port_a.T; CABI0CabiA005001008.port.T = TC_537_538.port_a.T; CABI0CabiA005001008.port.T = TC_537_550.port_a.T; CABI0CabiA005001008.port.T = TsCABI0CabiA005001008.port.T; TsCABI0CabiA004001008.port.Q_flow + (TC_535_536.port_b.Q_flow + (TC_482_536.port_b.Q_flow + (CABI0CabiA004001008.port.Q_flow + (TC_536_537.port_a.Q_flow + (TC_536_549.port_a.Q_flow + TC_536_0.port_a.Q_flow))))) = 0.0; CABI0CabiA004001008.port.T = TC_482_536.port_b.T; CABI0CabiA004001008.port.T = TC_535_536.port_b.T; CABI0CabiA004001008.port.T = TC_536_0.port_a.T; CABI0CabiA004001008.port.T = TC_536_537.port_a.T; CABI0CabiA004001008.port.T = TC_536_549.port_a.T; CABI0CabiA004001008.port.T = TsCABI0CabiA004001008.port.T; TsCABI0CabiA003001008.port.Q_flow + (TC_534_535.port_b.Q_flow + (TC_481_535.port_b.Q_flow + (CABI0CabiA003001008.port.Q_flow + (TC_535_536.port_a.Q_flow + (TC_535_548.port_a.Q_flow + TC_535_0.port_a.Q_flow))))) = 0.0; CABI0CabiA003001008.port.T = TC_481_535.port_b.T; CABI0CabiA003001008.port.T = TC_534_535.port_b.T; CABI0CabiA003001008.port.T = TC_535_0.port_a.T; CABI0CabiA003001008.port.T = TC_535_536.port_a.T; CABI0CabiA003001008.port.T = TC_535_548.port_a.T; CABI0CabiA003001008.port.T = TsCABI0CabiA003001008.port.T; TsCABI0CabiA002001008.port.Q_flow + (TC_533_534.port_b.Q_flow + (TC_480_534.port_b.Q_flow + (CABI0CabiA002001008.port.Q_flow + (TC_534_535.port_a.Q_flow + (TC_534_547.port_a.Q_flow + TC_534_0.port_a.Q_flow))))) = 0.0; CABI0CabiA002001008.port.T = TC_480_534.port_b.T; CABI0CabiA002001008.port.T = TC_533_534.port_b.T; CABI0CabiA002001008.port.T = TC_534_0.port_a.T; CABI0CabiA002001008.port.T = TC_534_535.port_a.T; CABI0CabiA002001008.port.T = TC_534_547.port_a.T; CABI0CabiA002001008.port.T = TsCABI0CabiA002001008.port.T; TsCABI0CabiA001001008.port.Q_flow + (TC_479_533.port_b.Q_flow + (CABI0CabiA001001008.port.Q_flow + (TC_533_534.port_a.Q_flow + (TC_533_546.port_a.Q_flow + TC_533_0.port_a.Q_flow)))) = 0.0; CABI0CabiA001001008.port.T = TC_479_533.port_b.T; CABI0CabiA001001008.port.T = TC_533_0.port_a.T; CABI0CabiA001001008.port.T = TC_533_534.port_a.T; CABI0CabiA001001008.port.T = TC_533_546.port_a.T; CABI0CabiA001001008.port.T = TsCABI0CabiA001001008.port.T; TsCABI0CabiA013016007.port.Q_flow + (TC_531_532.port_b.Q_flow + (TC_519_532.port_b.Q_flow + (TC_478_532.port_b.Q_flow + (CABI0CabiA013016007.port.Q_flow + (TC_532_740.port_a.Q_flow + TC_532_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013016007.port.T = TC_478_532.port_b.T; CABI0CabiA013016007.port.T = TC_519_532.port_b.T; CABI0CabiA013016007.port.T = TC_531_532.port_b.T; CABI0CabiA013016007.port.T = TC_532_0.port_a.T; CABI0CabiA013016007.port.T = TC_532_740.port_a.T; CABI0CabiA013016007.port.T = TsCABI0CabiA013016007.port.T; TsCABI0CabiA012016007.port.Q_flow + (TC_530_531.port_b.Q_flow + (TC_477_531.port_b.Q_flow + (CABI0CabiA012016007.port.Q_flow + (TC_531_532.port_a.Q_flow + (TC_531_739.port_a.Q_flow + (TC_531_831.port_a.Q_flow + TC_531_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012016007.port.T = TC_477_531.port_b.T; CABI0CabiA012016007.port.T = TC_530_531.port_b.T; CABI0CabiA012016007.port.T = TC_531_0.port_a.T; CABI0CabiA012016007.port.T = TC_531_532.port_a.T; CABI0CabiA012016007.port.T = TC_531_739.port_a.T; CABI0CabiA012016007.port.T = TC_531_831.port_a.T; CABI0CabiA012016007.port.T = TsCABI0CabiA012016007.port.T; TsCABI0CabiA011016007.port.Q_flow + (TC_529_530.port_b.Q_flow + (TC_476_530.port_b.Q_flow + (CABI0CabiA011016007.port.Q_flow + (TC_530_531.port_a.Q_flow + (TC_530_738.port_a.Q_flow + (TC_530_830.port_a.Q_flow + TC_530_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011016007.port.T = TC_476_530.port_b.T; CABI0CabiA011016007.port.T = TC_529_530.port_b.T; CABI0CabiA011016007.port.T = TC_530_0.port_a.T; CABI0CabiA011016007.port.T = TC_530_531.port_a.T; CABI0CabiA011016007.port.T = TC_530_738.port_a.T; CABI0CabiA011016007.port.T = TC_530_830.port_a.T; CABI0CabiA011016007.port.T = TsCABI0CabiA011016007.port.T; TsCABI0CabiA010016007.port.Q_flow + (TC_528_529.port_b.Q_flow + (TC_475_529.port_b.Q_flow + (CABI0CabiA010016007.port.Q_flow + (TC_529_530.port_a.Q_flow + (TC_529_737.port_a.Q_flow + (TC_529_829.port_a.Q_flow + TC_529_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010016007.port.T = TC_475_529.port_b.T; CABI0CabiA010016007.port.T = TC_528_529.port_b.T; CABI0CabiA010016007.port.T = TC_529_0.port_a.T; CABI0CabiA010016007.port.T = TC_529_530.port_a.T; CABI0CabiA010016007.port.T = TC_529_737.port_a.T; CABI0CabiA010016007.port.T = TC_529_829.port_a.T; CABI0CabiA010016007.port.T = TsCABI0CabiA010016007.port.T; TsCABI0CabiA009016007.port.Q_flow + (TC_527_528.port_b.Q_flow + (TC_474_528.port_b.Q_flow + (CABI0CabiA009016007.port.Q_flow + (TC_528_529.port_a.Q_flow + (TC_528_736.port_a.Q_flow + (TC_528_828.port_a.Q_flow + TC_528_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009016007.port.T = TC_474_528.port_b.T; CABI0CabiA009016007.port.T = TC_527_528.port_b.T; CABI0CabiA009016007.port.T = TC_528_0.port_a.T; CABI0CabiA009016007.port.T = TC_528_529.port_a.T; CABI0CabiA009016007.port.T = TC_528_736.port_a.T; CABI0CabiA009016007.port.T = TC_528_828.port_a.T; CABI0CabiA009016007.port.T = TsCABI0CabiA009016007.port.T; TsCABI0CabiA008016007.port.Q_flow + (TC_526_527.port_b.Q_flow + (TC_473_527.port_b.Q_flow + (CABI0CabiA008016007.port.Q_flow + (TC_527_528.port_a.Q_flow + (TC_527_735.port_a.Q_flow + (TC_527_827.port_a.Q_flow + TC_527_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008016007.port.T = TC_473_527.port_b.T; CABI0CabiA008016007.port.T = TC_526_527.port_b.T; CABI0CabiA008016007.port.T = TC_527_0.port_a.T; CABI0CabiA008016007.port.T = TC_527_528.port_a.T; CABI0CabiA008016007.port.T = TC_527_735.port_a.T; CABI0CabiA008016007.port.T = TC_527_827.port_a.T; CABI0CabiA008016007.port.T = TsCABI0CabiA008016007.port.T; TsCABI0CabiA007016007.port.Q_flow + (TC_525_526.port_b.Q_flow + (TC_472_526.port_b.Q_flow + (CABI0CabiA007016007.port.Q_flow + (TC_526_527.port_a.Q_flow + (TC_526_734.port_a.Q_flow + (TC_526_826.port_a.Q_flow + TC_526_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007016007.port.T = TC_472_526.port_b.T; CABI0CabiA007016007.port.T = TC_525_526.port_b.T; CABI0CabiA007016007.port.T = TC_526_0.port_a.T; CABI0CabiA007016007.port.T = TC_526_527.port_a.T; CABI0CabiA007016007.port.T = TC_526_734.port_a.T; CABI0CabiA007016007.port.T = TC_526_826.port_a.T; CABI0CabiA007016007.port.T = TsCABI0CabiA007016007.port.T; TsCABI0CabiA006016007.port.Q_flow + (TC_524_525.port_b.Q_flow + (TC_471_525.port_b.Q_flow + (CABI0CabiA006016007.port.Q_flow + (TC_525_526.port_a.Q_flow + (TC_525_733.port_a.Q_flow + (TC_525_825.port_a.Q_flow + TC_525_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006016007.port.T = TC_471_525.port_b.T; CABI0CabiA006016007.port.T = TC_524_525.port_b.T; CABI0CabiA006016007.port.T = TC_525_0.port_a.T; CABI0CabiA006016007.port.T = TC_525_526.port_a.T; CABI0CabiA006016007.port.T = TC_525_733.port_a.T; CABI0CabiA006016007.port.T = TC_525_825.port_a.T; CABI0CabiA006016007.port.T = TsCABI0CabiA006016007.port.T; TsCABI0CabiA005016007.port.Q_flow + (TC_523_524.port_b.Q_flow + (TC_470_524.port_b.Q_flow + (CABI0CabiA005016007.port.Q_flow + (TC_524_525.port_a.Q_flow + (TC_524_732.port_a.Q_flow + (TC_524_824.port_a.Q_flow + TC_524_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005016007.port.T = TC_470_524.port_b.T; CABI0CabiA005016007.port.T = TC_523_524.port_b.T; CABI0CabiA005016007.port.T = TC_524_0.port_a.T; CABI0CabiA005016007.port.T = TC_524_525.port_a.T; CABI0CabiA005016007.port.T = TC_524_732.port_a.T; CABI0CabiA005016007.port.T = TC_524_824.port_a.T; CABI0CabiA005016007.port.T = TsCABI0CabiA005016007.port.T; TsCABI0CabiA004016007.port.Q_flow + (TC_522_523.port_b.Q_flow + (TC_469_523.port_b.Q_flow + (CABI0CabiA004016007.port.Q_flow + (TC_523_524.port_a.Q_flow + (TC_523_731.port_a.Q_flow + (TC_523_823.port_a.Q_flow + TC_523_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004016007.port.T = TC_469_523.port_b.T; CABI0CabiA004016007.port.T = TC_522_523.port_b.T; CABI0CabiA004016007.port.T = TC_523_0.port_a.T; CABI0CabiA004016007.port.T = TC_523_524.port_a.T; CABI0CabiA004016007.port.T = TC_523_731.port_a.T; CABI0CabiA004016007.port.T = TC_523_823.port_a.T; CABI0CabiA004016007.port.T = TsCABI0CabiA004016007.port.T; TsCABI0CabiA003016007.port.Q_flow + (TC_521_522.port_b.Q_flow + (TC_468_522.port_b.Q_flow + (CABI0CabiA003016007.port.Q_flow + (TC_522_523.port_a.Q_flow + (TC_522_730.port_a.Q_flow + (TC_522_822.port_a.Q_flow + TC_522_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003016007.port.T = TC_468_522.port_b.T; CABI0CabiA003016007.port.T = TC_521_522.port_b.T; CABI0CabiA003016007.port.T = TC_522_0.port_a.T; CABI0CabiA003016007.port.T = TC_522_523.port_a.T; CABI0CabiA003016007.port.T = TC_522_730.port_a.T; CABI0CabiA003016007.port.T = TC_522_822.port_a.T; CABI0CabiA003016007.port.T = TsCABI0CabiA003016007.port.T; TsCABI0CabiA002016007.port.Q_flow + (TC_520_521.port_b.Q_flow + (TC_467_521.port_b.Q_flow + (CABI0CabiA002016007.port.Q_flow + (TC_521_522.port_a.Q_flow + (TC_521_729.port_a.Q_flow + (TC_521_821.port_a.Q_flow + TC_521_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002016007.port.T = TC_467_521.port_b.T; CABI0CabiA002016007.port.T = TC_520_521.port_b.T; CABI0CabiA002016007.port.T = TC_521_0.port_a.T; CABI0CabiA002016007.port.T = TC_521_522.port_a.T; CABI0CabiA002016007.port.T = TC_521_729.port_a.T; CABI0CabiA002016007.port.T = TC_521_821.port_a.T; CABI0CabiA002016007.port.T = TsCABI0CabiA002016007.port.T; TsCABI0CabiA001016007.port.Q_flow + (TC_518_520.port_b.Q_flow + (TC_466_520.port_b.Q_flow + (CABI0CabiA001016007.port.Q_flow + (TC_520_521.port_a.Q_flow + (TC_520_728.port_a.Q_flow + TC_520_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001016007.port.T = TC_466_520.port_b.T; CABI0CabiA001016007.port.T = TC_518_520.port_b.T; CABI0CabiA001016007.port.T = TC_520_0.port_a.T; CABI0CabiA001016007.port.T = TC_520_521.port_a.T; CABI0CabiA001016007.port.T = TC_520_728.port_a.T; CABI0CabiA001016007.port.T = TsCABI0CabiA001016007.port.T; TsCABI0CabiA013015007.port.Q_flow + (TC_517_519.port_b.Q_flow + (TC_465_519.port_b.Q_flow + (CABI0CabiA013015007.port.Q_flow + (TC_519_532.port_a.Q_flow + (TC_519_727.port_a.Q_flow + (TC_519_831.port_a.Q_flow + TC_519_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013015007.port.T = TC_465_519.port_b.T; CABI0CabiA013015007.port.T = TC_517_519.port_b.T; CABI0CabiA013015007.port.T = TC_519_0.port_a.T; CABI0CabiA013015007.port.T = TC_519_532.port_a.T; CABI0CabiA013015007.port.T = TC_519_727.port_a.T; CABI0CabiA013015007.port.T = TC_519_831.port_a.T; CABI0CabiA013015007.port.T = TsCABI0CabiA013015007.port.T; TsCABI0CabiA001015007.port.Q_flow + (TC_516_518.port_b.Q_flow + (TC_464_518.port_b.Q_flow + (CABI0CabiA001015007.port.Q_flow + (TC_518_520.port_a.Q_flow + (TC_518_715.port_a.Q_flow + (TC_518_821.port_a.Q_flow + TC_518_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001015007.port.T = TC_464_518.port_b.T; CABI0CabiA001015007.port.T = TC_516_518.port_b.T; CABI0CabiA001015007.port.T = TC_518_0.port_a.T; CABI0CabiA001015007.port.T = TC_518_520.port_a.T; CABI0CabiA001015007.port.T = TC_518_715.port_a.T; CABI0CabiA001015007.port.T = TC_518_821.port_a.T; CABI0CabiA001015007.port.T = TsCABI0CabiA001015007.port.T; TsCABI0CabiA013014007.port.Q_flow + (TC_515_517.port_b.Q_flow + (TC_463_517.port_b.Q_flow + (CABI0CabiA013014007.port.Q_flow + (TC_517_519.port_a.Q_flow + (TC_517_714.port_a.Q_flow + (TC_517_842.port_a.Q_flow + TC_517_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013014007.port.T = TC_463_517.port_b.T; CABI0CabiA013014007.port.T = TC_515_517.port_b.T; CABI0CabiA013014007.port.T = TC_517_0.port_a.T; CABI0CabiA013014007.port.T = TC_517_519.port_a.T; CABI0CabiA013014007.port.T = TC_517_714.port_a.T; CABI0CabiA013014007.port.T = TC_517_842.port_a.T; CABI0CabiA013014007.port.T = TsCABI0CabiA013014007.port.T; TsCABI0CabiA001014007.port.Q_flow + (TC_514_516.port_b.Q_flow + (TC_462_516.port_b.Q_flow + (CABI0CabiA001014007.port.Q_flow + (TC_516_518.port_a.Q_flow + (TC_516_702.port_a.Q_flow + (TC_516_832.port_a.Q_flow + TC_516_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001014007.port.T = TC_462_516.port_b.T; CABI0CabiA001014007.port.T = TC_514_516.port_b.T; CABI0CabiA001014007.port.T = TC_516_0.port_a.T; CABI0CabiA001014007.port.T = TC_516_518.port_a.T; CABI0CabiA001014007.port.T = TC_516_702.port_a.T; CABI0CabiA001014007.port.T = TC_516_832.port_a.T; CABI0CabiA001014007.port.T = TsCABI0CabiA001014007.port.T; TsCABI0CabiA013013007.port.Q_flow + (TC_513_515.port_b.Q_flow + (TC_461_515.port_b.Q_flow + (CABI0CabiA013013007.port.Q_flow + (TC_515_517.port_a.Q_flow + (TC_515_701.port_a.Q_flow + (TC_515_919.port_a.Q_flow + TC_515_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013013007.port.T = TC_461_515.port_b.T; CABI0CabiA013013007.port.T = TC_513_515.port_b.T; CABI0CabiA013013007.port.T = TC_515_0.port_a.T; CABI0CabiA013013007.port.T = TC_515_517.port_a.T; CABI0CabiA013013007.port.T = TC_515_701.port_a.T; CABI0CabiA013013007.port.T = TC_515_919.port_a.T; CABI0CabiA013013007.port.T = TsCABI0CabiA013013007.port.T; TsCABI0CabiA001013007.port.Q_flow + (TC_512_514.port_b.Q_flow + (TC_460_514.port_b.Q_flow + (CABI0CabiA001013007.port.Q_flow + (TC_514_516.port_a.Q_flow + (TC_514_689.port_a.Q_flow + (TC_514_909.port_a.Q_flow + TC_514_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001013007.port.T = TC_460_514.port_b.T; CABI0CabiA001013007.port.T = TC_512_514.port_b.T; CABI0CabiA001013007.port.T = TC_514_0.port_a.T; CABI0CabiA001013007.port.T = TC_514_516.port_a.T; CABI0CabiA001013007.port.T = TC_514_689.port_a.T; CABI0CabiA001013007.port.T = TC_514_909.port_a.T; CABI0CabiA001013007.port.T = TsCABI0CabiA001013007.port.T; TsCABI0CabiA013012007.port.Q_flow + (TC_511_513.port_b.Q_flow + (TC_459_513.port_b.Q_flow + (CABI0CabiA013012007.port.Q_flow + (TC_513_515.port_a.Q_flow + (TC_513_688.port_a.Q_flow + (TC_513_908.port_a.Q_flow + TC_513_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013012007.port.T = TC_459_513.port_b.T; CABI0CabiA013012007.port.T = TC_511_513.port_b.T; CABI0CabiA013012007.port.T = TC_513_0.port_a.T; CABI0CabiA013012007.port.T = TC_513_515.port_a.T; CABI0CabiA013012007.port.T = TC_513_688.port_a.T; CABI0CabiA013012007.port.T = TC_513_908.port_a.T; CABI0CabiA013012007.port.T = TsCABI0CabiA013012007.port.T; TsCABI0CabiA001012007.port.Q_flow + (TC_510_512.port_b.Q_flow + (TC_458_512.port_b.Q_flow + (CABI0CabiA001012007.port.Q_flow + (TC_512_514.port_a.Q_flow + (TC_512_676.port_a.Q_flow + (TC_512_898.port_a.Q_flow + TC_512_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001012007.port.T = TC_458_512.port_b.T; CABI0CabiA001012007.port.T = TC_510_512.port_b.T; CABI0CabiA001012007.port.T = TC_512_0.port_a.T; CABI0CabiA001012007.port.T = TC_512_514.port_a.T; CABI0CabiA001012007.port.T = TC_512_676.port_a.T; CABI0CabiA001012007.port.T = TC_512_898.port_a.T; CABI0CabiA001012007.port.T = TsCABI0CabiA001012007.port.T; TsCABI0CabiA013011007.port.Q_flow + (TC_509_511.port_b.Q_flow + (TC_457_511.port_b.Q_flow + (CABI0CabiA013011007.port.Q_flow + (TC_511_513.port_a.Q_flow + (TC_511_675.port_a.Q_flow + (TC_511_897.port_a.Q_flow + TC_511_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013011007.port.T = TC_457_511.port_b.T; CABI0CabiA013011007.port.T = TC_509_511.port_b.T; CABI0CabiA013011007.port.T = TC_511_0.port_a.T; CABI0CabiA013011007.port.T = TC_511_513.port_a.T; CABI0CabiA013011007.port.T = TC_511_675.port_a.T; CABI0CabiA013011007.port.T = TC_511_897.port_a.T; CABI0CabiA013011007.port.T = TsCABI0CabiA013011007.port.T; TsCABI0CabiA001011007.port.Q_flow + (TC_508_510.port_b.Q_flow + (TC_456_510.port_b.Q_flow + (CABI0CabiA001011007.port.Q_flow + (TC_510_512.port_a.Q_flow + (TC_510_663.port_a.Q_flow + (TC_510_887.port_a.Q_flow + TC_510_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001011007.port.T = TC_456_510.port_b.T; CABI0CabiA001011007.port.T = TC_508_510.port_b.T; CABI0CabiA001011007.port.T = TC_510_0.port_a.T; CABI0CabiA001011007.port.T = TC_510_512.port_a.T; CABI0CabiA001011007.port.T = TC_510_663.port_a.T; CABI0CabiA001011007.port.T = TC_510_887.port_a.T; CABI0CabiA001011007.port.T = TsCABI0CabiA001011007.port.T; TsCABI0CabiA013010007.port.Q_flow + (TC_507_509.port_b.Q_flow + (TC_455_509.port_b.Q_flow + (CABI0CabiA013010007.port.Q_flow + (TC_509_511.port_a.Q_flow + (TC_509_662.port_a.Q_flow + (TC_509_886.port_a.Q_flow + TC_509_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013010007.port.T = TC_455_509.port_b.T; CABI0CabiA013010007.port.T = TC_507_509.port_b.T; CABI0CabiA013010007.port.T = TC_509_0.port_a.T; CABI0CabiA013010007.port.T = TC_509_511.port_a.T; CABI0CabiA013010007.port.T = TC_509_662.port_a.T; CABI0CabiA013010007.port.T = TC_509_886.port_a.T; CABI0CabiA013010007.port.T = TsCABI0CabiA013010007.port.T; TsCABI0CabiA001010007.port.Q_flow + (TC_506_508.port_b.Q_flow + (TC_454_508.port_b.Q_flow + (CABI0CabiA001010007.port.Q_flow + (TC_508_510.port_a.Q_flow + (TC_508_650.port_a.Q_flow + (TC_508_876.port_a.Q_flow + TC_508_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001010007.port.T = TC_454_508.port_b.T; CABI0CabiA001010007.port.T = TC_506_508.port_b.T; CABI0CabiA001010007.port.T = TC_508_0.port_a.T; CABI0CabiA001010007.port.T = TC_508_510.port_a.T; CABI0CabiA001010007.port.T = TC_508_650.port_a.T; CABI0CabiA001010007.port.T = TC_508_876.port_a.T; CABI0CabiA001010007.port.T = TsCABI0CabiA001010007.port.T; TsCABI0CabiA013009007.port.Q_flow + (TC_505_507.port_b.Q_flow + (TC_453_507.port_b.Q_flow + (CABI0CabiA013009007.port.Q_flow + (TC_507_509.port_a.Q_flow + (TC_507_649.port_a.Q_flow + (TC_507_875.port_a.Q_flow + TC_507_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013009007.port.T = TC_453_507.port_b.T; CABI0CabiA013009007.port.T = TC_505_507.port_b.T; CABI0CabiA013009007.port.T = TC_507_0.port_a.T; CABI0CabiA013009007.port.T = TC_507_509.port_a.T; CABI0CabiA013009007.port.T = TC_507_649.port_a.T; CABI0CabiA013009007.port.T = TC_507_875.port_a.T; CABI0CabiA013009007.port.T = TsCABI0CabiA013009007.port.T; TsCABI0CabiA001009007.port.Q_flow + (TC_504_506.port_b.Q_flow + (TC_452_506.port_b.Q_flow + (CABI0CabiA001009007.port.Q_flow + (TC_506_508.port_a.Q_flow + (TC_506_637.port_a.Q_flow + (TC_506_865.port_a.Q_flow + TC_506_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001009007.port.T = TC_452_506.port_b.T; CABI0CabiA001009007.port.T = TC_504_506.port_b.T; CABI0CabiA001009007.port.T = TC_506_0.port_a.T; CABI0CabiA001009007.port.T = TC_506_508.port_a.T; CABI0CabiA001009007.port.T = TC_506_637.port_a.T; CABI0CabiA001009007.port.T = TC_506_865.port_a.T; CABI0CabiA001009007.port.T = TsCABI0CabiA001009007.port.T; TsCABI0CabiA013008007.port.Q_flow + (TC_503_505.port_b.Q_flow + (TC_451_505.port_b.Q_flow + (CABI0CabiA013008007.port.Q_flow + (TC_505_507.port_a.Q_flow + (TC_505_636.port_a.Q_flow + (TC_505_864.port_a.Q_flow + TC_505_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013008007.port.T = TC_451_505.port_b.T; CABI0CabiA013008007.port.T = TC_503_505.port_b.T; CABI0CabiA013008007.port.T = TC_505_0.port_a.T; CABI0CabiA013008007.port.T = TC_505_507.port_a.T; CABI0CabiA013008007.port.T = TC_505_636.port_a.T; CABI0CabiA013008007.port.T = TC_505_864.port_a.T; CABI0CabiA013008007.port.T = TsCABI0CabiA013008007.port.T; TsCABI0CabiA001008007.port.Q_flow + (TC_502_504.port_b.Q_flow + (TC_450_504.port_b.Q_flow + (CABI0CabiA001008007.port.Q_flow + (TC_504_506.port_a.Q_flow + (TC_504_624.port_a.Q_flow + (TC_504_854.port_a.Q_flow + TC_504_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001008007.port.T = TC_450_504.port_b.T; CABI0CabiA001008007.port.T = TC_502_504.port_b.T; CABI0CabiA001008007.port.T = TC_504_0.port_a.T; CABI0CabiA001008007.port.T = TC_504_506.port_a.T; CABI0CabiA001008007.port.T = TC_504_624.port_a.T; CABI0CabiA001008007.port.T = TC_504_854.port_a.T; CABI0CabiA001008007.port.T = TsCABI0CabiA001008007.port.T; TsCABI0CabiA013007007.port.Q_flow + (TC_501_503.port_b.Q_flow + (TC_449_503.port_b.Q_flow + (CABI0CabiA013007007.port.Q_flow + (TC_503_505.port_a.Q_flow + (TC_503_623.port_a.Q_flow + (TC_503_853.port_a.Q_flow + TC_503_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013007007.port.T = TC_449_503.port_b.T; CABI0CabiA013007007.port.T = TC_501_503.port_b.T; CABI0CabiA013007007.port.T = TC_503_0.port_a.T; CABI0CabiA013007007.port.T = TC_503_505.port_a.T; CABI0CabiA013007007.port.T = TC_503_623.port_a.T; CABI0CabiA013007007.port.T = TC_503_853.port_a.T; CABI0CabiA013007007.port.T = TsCABI0CabiA013007007.port.T; TsCABI0CabiA001007007.port.Q_flow + (TC_500_502.port_b.Q_flow + (TC_448_502.port_b.Q_flow + (CABI0CabiA001007007.port.Q_flow + (TC_502_504.port_a.Q_flow + (TC_502_611.port_a.Q_flow + (TC_502_843.port_a.Q_flow + TC_502_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001007007.port.T = TC_448_502.port_b.T; CABI0CabiA001007007.port.T = TC_500_502.port_b.T; CABI0CabiA001007007.port.T = TC_502_0.port_a.T; CABI0CabiA001007007.port.T = TC_502_504.port_a.T; CABI0CabiA001007007.port.T = TC_502_611.port_a.T; CABI0CabiA001007007.port.T = TC_502_843.port_a.T; CABI0CabiA001007007.port.T = TsCABI0CabiA001007007.port.T; TsCABI0CabiA013006007.port.Q_flow + (TC_499_501.port_b.Q_flow + (TC_447_501.port_b.Q_flow + (CABI0CabiA013006007.port.Q_flow + (TC_501_503.port_a.Q_flow + (TC_501_610.port_a.Q_flow + (TC_501_974.port_a.Q_flow + TC_501_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013006007.port.T = TC_447_501.port_b.T; CABI0CabiA013006007.port.T = TC_499_501.port_b.T; CABI0CabiA013006007.port.T = TC_501_0.port_a.T; CABI0CabiA013006007.port.T = TC_501_503.port_a.T; CABI0CabiA013006007.port.T = TC_501_610.port_a.T; CABI0CabiA013006007.port.T = TC_501_974.port_a.T; CABI0CabiA013006007.port.T = TsCABI0CabiA013006007.port.T; TsCABI0CabiA001006007.port.Q_flow + (TC_498_500.port_b.Q_flow + (TC_446_500.port_b.Q_flow + (CABI0CabiA001006007.port.Q_flow + (TC_500_502.port_a.Q_flow + (TC_500_598.port_a.Q_flow + (TC_500_964.port_a.Q_flow + TC_500_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001006007.port.T = TC_446_500.port_b.T; CABI0CabiA001006007.port.T = TC_498_500.port_b.T; CABI0CabiA001006007.port.T = TC_500_0.port_a.T; CABI0CabiA001006007.port.T = TC_500_502.port_a.T; CABI0CabiA001006007.port.T = TC_500_598.port_a.T; CABI0CabiA001006007.port.T = TC_500_964.port_a.T; CABI0CabiA001006007.port.T = TsCABI0CabiA001006007.port.T; TsCABI0CabiA013005007.port.Q_flow + (TC_497_499.port_b.Q_flow + (TC_445_499.port_b.Q_flow + (CABI0CabiA013005007.port.Q_flow + (TC_499_501.port_a.Q_flow + (TC_499_597.port_a.Q_flow + (TC_499_963.port_a.Q_flow + TC_499_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013005007.port.T = TC_445_499.port_b.T; CABI0CabiA013005007.port.T = TC_497_499.port_b.T; CABI0CabiA013005007.port.T = TC_499_0.port_a.T; CABI0CabiA013005007.port.T = TC_499_501.port_a.T; CABI0CabiA013005007.port.T = TC_499_597.port_a.T; CABI0CabiA013005007.port.T = TC_499_963.port_a.T; CABI0CabiA013005007.port.T = TsCABI0CabiA013005007.port.T; TsCABI0CabiA001005007.port.Q_flow + (TC_496_498.port_b.Q_flow + (TC_444_498.port_b.Q_flow + (CABI0CabiA001005007.port.Q_flow + (TC_498_500.port_a.Q_flow + (TC_498_585.port_a.Q_flow + (TC_498_953.port_a.Q_flow + TC_498_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001005007.port.T = TC_444_498.port_b.T; CABI0CabiA001005007.port.T = TC_496_498.port_b.T; CABI0CabiA001005007.port.T = TC_498_0.port_a.T; CABI0CabiA001005007.port.T = TC_498_500.port_a.T; CABI0CabiA001005007.port.T = TC_498_585.port_a.T; CABI0CabiA001005007.port.T = TC_498_953.port_a.T; CABI0CabiA001005007.port.T = TsCABI0CabiA001005007.port.T; TsCABI0CabiA013004007.port.Q_flow + (TC_495_497.port_b.Q_flow + (TC_443_497.port_b.Q_flow + (CABI0CabiA013004007.port.Q_flow + (TC_497_499.port_a.Q_flow + (TC_497_584.port_a.Q_flow + (TC_497_952.port_a.Q_flow + TC_497_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013004007.port.T = TC_443_497.port_b.T; CABI0CabiA013004007.port.T = TC_495_497.port_b.T; CABI0CabiA013004007.port.T = TC_497_0.port_a.T; CABI0CabiA013004007.port.T = TC_497_499.port_a.T; CABI0CabiA013004007.port.T = TC_497_584.port_a.T; CABI0CabiA013004007.port.T = TC_497_952.port_a.T; CABI0CabiA013004007.port.T = TsCABI0CabiA013004007.port.T; TsCABI0CabiA001004007.port.Q_flow + (TC_494_496.port_b.Q_flow + (TC_442_496.port_b.Q_flow + (CABI0CabiA001004007.port.Q_flow + (TC_496_498.port_a.Q_flow + (TC_496_572.port_a.Q_flow + (TC_496_942.port_a.Q_flow + TC_496_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001004007.port.T = TC_442_496.port_b.T; CABI0CabiA001004007.port.T = TC_494_496.port_b.T; CABI0CabiA001004007.port.T = TC_496_0.port_a.T; CABI0CabiA001004007.port.T = TC_496_498.port_a.T; CABI0CabiA001004007.port.T = TC_496_572.port_a.T; CABI0CabiA001004007.port.T = TC_496_942.port_a.T; CABI0CabiA001004007.port.T = TsCABI0CabiA001004007.port.T; TsCABI0CabiA013003007.port.Q_flow + (TC_493_495.port_b.Q_flow + (TC_441_495.port_b.Q_flow + (CABI0CabiA013003007.port.Q_flow + (TC_495_497.port_a.Q_flow + (TC_495_571.port_a.Q_flow + (TC_495_941.port_a.Q_flow + TC_495_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013003007.port.T = TC_441_495.port_b.T; CABI0CabiA013003007.port.T = TC_493_495.port_b.T; CABI0CabiA013003007.port.T = TC_495_0.port_a.T; CABI0CabiA013003007.port.T = TC_495_497.port_a.T; CABI0CabiA013003007.port.T = TC_495_571.port_a.T; CABI0CabiA013003007.port.T = TC_495_941.port_a.T; CABI0CabiA013003007.port.T = TsCABI0CabiA013003007.port.T; TsCABI0CabiA001003007.port.Q_flow + (TC_492_494.port_b.Q_flow + (TC_440_494.port_b.Q_flow + (CABI0CabiA001003007.port.Q_flow + (TC_494_496.port_a.Q_flow + (TC_494_559.port_a.Q_flow + (TC_494_931.port_a.Q_flow + TC_494_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001003007.port.T = TC_440_494.port_b.T; CABI0CabiA001003007.port.T = TC_492_494.port_b.T; CABI0CabiA001003007.port.T = TC_494_0.port_a.T; CABI0CabiA001003007.port.T = TC_494_496.port_a.T; CABI0CabiA001003007.port.T = TC_494_559.port_a.T; CABI0CabiA001003007.port.T = TC_494_931.port_a.T; CABI0CabiA001003007.port.T = TsCABI0CabiA001003007.port.T; TsCABI0CabiA013002007.port.Q_flow + (TC_491_493.port_b.Q_flow + (TC_439_493.port_b.Q_flow + (CABI0CabiA013002007.port.Q_flow + (TC_493_495.port_a.Q_flow + (TC_493_558.port_a.Q_flow + (TC_493_930.port_a.Q_flow + TC_493_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013002007.port.T = TC_439_493.port_b.T; CABI0CabiA013002007.port.T = TC_491_493.port_b.T; CABI0CabiA013002007.port.T = TC_493_0.port_a.T; CABI0CabiA013002007.port.T = TC_493_495.port_a.T; CABI0CabiA013002007.port.T = TC_493_558.port_a.T; CABI0CabiA013002007.port.T = TC_493_930.port_a.T; CABI0CabiA013002007.port.T = TsCABI0CabiA013002007.port.T; TsCABI0CabiA001002007.port.Q_flow + (TC_479_492.port_b.Q_flow + (TC_438_492.port_b.Q_flow + (CABI0CabiA001002007.port.Q_flow + (TC_492_494.port_a.Q_flow + (TC_492_546.port_a.Q_flow + (TC_492_920.port_a.Q_flow + TC_492_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001002007.port.T = TC_438_492.port_b.T; CABI0CabiA001002007.port.T = TC_479_492.port_b.T; CABI0CabiA001002007.port.T = TC_492_0.port_a.T; CABI0CabiA001002007.port.T = TC_492_494.port_a.T; CABI0CabiA001002007.port.T = TC_492_546.port_a.T; CABI0CabiA001002007.port.T = TC_492_920.port_a.T; CABI0CabiA001002007.port.T = TsCABI0CabiA001002007.port.T; TsCABI0CabiA013001007.port.Q_flow + (TC_490_491.port_b.Q_flow + (TC_437_491.port_b.Q_flow + (CABI0CabiA013001007.port.Q_flow + (TC_491_493.port_a.Q_flow + (TC_491_545.port_a.Q_flow + TC_491_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013001007.port.T = TC_437_491.port_b.T; CABI0CabiA013001007.port.T = TC_490_491.port_b.T; CABI0CabiA013001007.port.T = TC_491_0.port_a.T; CABI0CabiA013001007.port.T = TC_491_493.port_a.T; CABI0CabiA013001007.port.T = TC_491_545.port_a.T; CABI0CabiA013001007.port.T = TsCABI0CabiA013001007.port.T; TsCABI0CabiA012001007.port.Q_flow + (TC_489_490.port_b.Q_flow + (TC_436_490.port_b.Q_flow + (CABI0CabiA012001007.port.Q_flow + (TC_490_491.port_a.Q_flow + (TC_490_544.port_a.Q_flow + (TC_490_930.port_a.Q_flow + TC_490_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012001007.port.T = TC_436_490.port_b.T; CABI0CabiA012001007.port.T = TC_489_490.port_b.T; CABI0CabiA012001007.port.T = TC_490_0.port_a.T; CABI0CabiA012001007.port.T = TC_490_491.port_a.T; CABI0CabiA012001007.port.T = TC_490_544.port_a.T; CABI0CabiA012001007.port.T = TC_490_930.port_a.T; CABI0CabiA012001007.port.T = TsCABI0CabiA012001007.port.T; TsCABI0CabiA011001007.port.Q_flow + (TC_488_489.port_b.Q_flow + (TC_435_489.port_b.Q_flow + (CABI0CabiA011001007.port.Q_flow + (TC_489_490.port_a.Q_flow + (TC_489_543.port_a.Q_flow + (TC_489_929.port_a.Q_flow + TC_489_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011001007.port.T = TC_435_489.port_b.T; CABI0CabiA011001007.port.T = TC_488_489.port_b.T; CABI0CabiA011001007.port.T = TC_489_0.port_a.T; CABI0CabiA011001007.port.T = TC_489_490.port_a.T; CABI0CabiA011001007.port.T = TC_489_543.port_a.T; CABI0CabiA011001007.port.T = TC_489_929.port_a.T; CABI0CabiA011001007.port.T = TsCABI0CabiA011001007.port.T; TsCABI0CabiA010001007.port.Q_flow + (TC_487_488.port_b.Q_flow + (TC_434_488.port_b.Q_flow + (CABI0CabiA010001007.port.Q_flow + (TC_488_489.port_a.Q_flow + (TC_488_542.port_a.Q_flow + (TC_488_928.port_a.Q_flow + TC_488_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010001007.port.T = TC_434_488.port_b.T; CABI0CabiA010001007.port.T = TC_487_488.port_b.T; CABI0CabiA010001007.port.T = TC_488_0.port_a.T; CABI0CabiA010001007.port.T = TC_488_489.port_a.T; CABI0CabiA010001007.port.T = TC_488_542.port_a.T; CABI0CabiA010001007.port.T = TC_488_928.port_a.T; CABI0CabiA010001007.port.T = TsCABI0CabiA010001007.port.T; TsCABI0CabiA009001007.port.Q_flow + (TC_486_487.port_b.Q_flow + (TC_433_487.port_b.Q_flow + (CABI0CabiA009001007.port.Q_flow + (TC_487_488.port_a.Q_flow + (TC_487_541.port_a.Q_flow + (TC_487_927.port_a.Q_flow + TC_487_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009001007.port.T = TC_433_487.port_b.T; CABI0CabiA009001007.port.T = TC_486_487.port_b.T; CABI0CabiA009001007.port.T = TC_487_0.port_a.T; CABI0CabiA009001007.port.T = TC_487_488.port_a.T; CABI0CabiA009001007.port.T = TC_487_541.port_a.T; CABI0CabiA009001007.port.T = TC_487_927.port_a.T; CABI0CabiA009001007.port.T = TsCABI0CabiA009001007.port.T; TsCABI0CabiA008001007.port.Q_flow + (TC_485_486.port_b.Q_flow + (TC_432_486.port_b.Q_flow + (CABI0CabiA008001007.port.Q_flow + (TC_486_487.port_a.Q_flow + (TC_486_540.port_a.Q_flow + (TC_486_926.port_a.Q_flow + TC_486_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008001007.port.T = TC_432_486.port_b.T; CABI0CabiA008001007.port.T = TC_485_486.port_b.T; CABI0CabiA008001007.port.T = TC_486_0.port_a.T; CABI0CabiA008001007.port.T = TC_486_487.port_a.T; CABI0CabiA008001007.port.T = TC_486_540.port_a.T; CABI0CabiA008001007.port.T = TC_486_926.port_a.T; CABI0CabiA008001007.port.T = TsCABI0CabiA008001007.port.T; TsCABI0CabiA007001007.port.Q_flow + (TC_484_485.port_b.Q_flow + (TC_431_485.port_b.Q_flow + (CABI0CabiA007001007.port.Q_flow + (TC_485_486.port_a.Q_flow + (TC_485_539.port_a.Q_flow + (TC_485_925.port_a.Q_flow + TC_485_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007001007.port.T = TC_431_485.port_b.T; CABI0CabiA007001007.port.T = TC_484_485.port_b.T; CABI0CabiA007001007.port.T = TC_485_0.port_a.T; CABI0CabiA007001007.port.T = TC_485_486.port_a.T; CABI0CabiA007001007.port.T = TC_485_539.port_a.T; CABI0CabiA007001007.port.T = TC_485_925.port_a.T; CABI0CabiA007001007.port.T = TsCABI0CabiA007001007.port.T; TsCABI0CabiA006001007.port.Q_flow + (TC_483_484.port_b.Q_flow + (TC_430_484.port_b.Q_flow + (CABI0CabiA006001007.port.Q_flow + (TC_484_485.port_a.Q_flow + (TC_484_538.port_a.Q_flow + (TC_484_924.port_a.Q_flow + TC_484_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006001007.port.T = TC_430_484.port_b.T; CABI0CabiA006001007.port.T = TC_483_484.port_b.T; CABI0CabiA006001007.port.T = TC_484_0.port_a.T; CABI0CabiA006001007.port.T = TC_484_485.port_a.T; CABI0CabiA006001007.port.T = TC_484_538.port_a.T; CABI0CabiA006001007.port.T = TC_484_924.port_a.T; CABI0CabiA006001007.port.T = TsCABI0CabiA006001007.port.T; TsCABI0CabiA005001007.port.Q_flow + (TC_482_483.port_b.Q_flow + (TC_429_483.port_b.Q_flow + (CABI0CabiA005001007.port.Q_flow + (TC_483_484.port_a.Q_flow + (TC_483_537.port_a.Q_flow + (TC_483_923.port_a.Q_flow + TC_483_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005001007.port.T = TC_429_483.port_b.T; CABI0CabiA005001007.port.T = TC_482_483.port_b.T; CABI0CabiA005001007.port.T = TC_483_0.port_a.T; CABI0CabiA005001007.port.T = TC_483_484.port_a.T; CABI0CabiA005001007.port.T = TC_483_537.port_a.T; CABI0CabiA005001007.port.T = TC_483_923.port_a.T; CABI0CabiA005001007.port.T = TsCABI0CabiA005001007.port.T; TsCABI0CabiA004001007.port.Q_flow + (TC_481_482.port_b.Q_flow + (TC_428_482.port_b.Q_flow + (CABI0CabiA004001007.port.Q_flow + (TC_482_483.port_a.Q_flow + (TC_482_536.port_a.Q_flow + (TC_482_922.port_a.Q_flow + TC_482_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004001007.port.T = TC_428_482.port_b.T; CABI0CabiA004001007.port.T = TC_481_482.port_b.T; CABI0CabiA004001007.port.T = TC_482_0.port_a.T; CABI0CabiA004001007.port.T = TC_482_483.port_a.T; CABI0CabiA004001007.port.T = TC_482_536.port_a.T; CABI0CabiA004001007.port.T = TC_482_922.port_a.T; CABI0CabiA004001007.port.T = TsCABI0CabiA004001007.port.T; TsCABI0CabiA003001007.port.Q_flow + (TC_480_481.port_b.Q_flow + (TC_427_481.port_b.Q_flow + (CABI0CabiA003001007.port.Q_flow + (TC_481_482.port_a.Q_flow + (TC_481_535.port_a.Q_flow + (TC_481_921.port_a.Q_flow + TC_481_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003001007.port.T = TC_427_481.port_b.T; CABI0CabiA003001007.port.T = TC_480_481.port_b.T; CABI0CabiA003001007.port.T = TC_481_0.port_a.T; CABI0CabiA003001007.port.T = TC_481_482.port_a.T; CABI0CabiA003001007.port.T = TC_481_535.port_a.T; CABI0CabiA003001007.port.T = TC_481_921.port_a.T; CABI0CabiA003001007.port.T = TsCABI0CabiA003001007.port.T; TsCABI0CabiA002001007.port.Q_flow + (TC_479_480.port_b.Q_flow + (TC_426_480.port_b.Q_flow + (CABI0CabiA002001007.port.Q_flow + (TC_480_481.port_a.Q_flow + (TC_480_534.port_a.Q_flow + (TC_480_920.port_a.Q_flow + TC_480_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002001007.port.T = TC_426_480.port_b.T; CABI0CabiA002001007.port.T = TC_479_480.port_b.T; CABI0CabiA002001007.port.T = TC_480_0.port_a.T; CABI0CabiA002001007.port.T = TC_480_481.port_a.T; CABI0CabiA002001007.port.T = TC_480_534.port_a.T; CABI0CabiA002001007.port.T = TC_480_920.port_a.T; CABI0CabiA002001007.port.T = TsCABI0CabiA002001007.port.T; TsCABI0CabiA001001007.port.Q_flow + (TC_425_479.port_b.Q_flow + (CABI0CabiA001001007.port.Q_flow + (TC_479_480.port_a.Q_flow + (TC_479_492.port_a.Q_flow + (TC_479_533.port_a.Q_flow + TC_479_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001001007.port.T = TC_425_479.port_b.T; CABI0CabiA001001007.port.T = TC_479_0.port_a.T; CABI0CabiA001001007.port.T = TC_479_480.port_a.T; CABI0CabiA001001007.port.T = TC_479_492.port_a.T; CABI0CabiA001001007.port.T = TC_479_533.port_a.T; CABI0CabiA001001007.port.T = TsCABI0CabiA001001007.port.T; TsCABI0CabiA013016006.port.Q_flow + (TC_477_478.port_b.Q_flow + (TC_465_478.port_b.Q_flow + (TC_315_478.port_b.Q_flow + (CABI0CabiA013016006.port.Q_flow + (TC_478_532.port_a.Q_flow + TC_478_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013016006.port.T = TC_315_478.port_b.T; CABI0CabiA013016006.port.T = TC_465_478.port_b.T; CABI0CabiA013016006.port.T = TC_477_478.port_b.T; CABI0CabiA013016006.port.T = TC_478_0.port_a.T; CABI0CabiA013016006.port.T = TC_478_532.port_a.T; CABI0CabiA013016006.port.T = TsCABI0CabiA013016006.port.T; TsCABI0CabiA012016006.port.Q_flow + (TC_476_477.port_b.Q_flow + (TC_314_477.port_b.Q_flow + (CABI0CabiA012016006.port.Q_flow + (TC_477_478.port_a.Q_flow + (TC_477_531.port_a.Q_flow + (TC_477_1027.port_a.Q_flow + TC_477_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012016006.port.T = TC_314_477.port_b.T; CABI0CabiA012016006.port.T = TC_476_477.port_b.T; CABI0CabiA012016006.port.T = TC_477_0.port_a.T; CABI0CabiA012016006.port.T = TC_477_1027.port_a.T; CABI0CabiA012016006.port.T = TC_477_478.port_a.T; CABI0CabiA012016006.port.T = TC_477_531.port_a.T; CABI0CabiA012016006.port.T = TsCABI0CabiA012016006.port.T; TsCABI0CabiA011016006.port.Q_flow + (TC_475_476.port_b.Q_flow + (TC_313_476.port_b.Q_flow + (CABI0CabiA011016006.port.Q_flow + (TC_476_477.port_a.Q_flow + (TC_476_530.port_a.Q_flow + (TC_476_1026.port_a.Q_flow + TC_476_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011016006.port.T = TC_313_476.port_b.T; CABI0CabiA011016006.port.T = TC_475_476.port_b.T; CABI0CabiA011016006.port.T = TC_476_0.port_a.T; CABI0CabiA011016006.port.T = TC_476_1026.port_a.T; CABI0CabiA011016006.port.T = TC_476_477.port_a.T; CABI0CabiA011016006.port.T = TC_476_530.port_a.T; CABI0CabiA011016006.port.T = TsCABI0CabiA011016006.port.T; TsCABI0CabiA010016006.port.Q_flow + (TC_474_475.port_b.Q_flow + (TC_312_475.port_b.Q_flow + (CABI0CabiA010016006.port.Q_flow + (TC_475_476.port_a.Q_flow + (TC_475_529.port_a.Q_flow + (TC_475_1025.port_a.Q_flow + TC_475_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010016006.port.T = TC_312_475.port_b.T; CABI0CabiA010016006.port.T = TC_474_475.port_b.T; CABI0CabiA010016006.port.T = TC_475_0.port_a.T; CABI0CabiA010016006.port.T = TC_475_1025.port_a.T; CABI0CabiA010016006.port.T = TC_475_476.port_a.T; CABI0CabiA010016006.port.T = TC_475_529.port_a.T; CABI0CabiA010016006.port.T = TsCABI0CabiA010016006.port.T; TsCABI0CabiA009016006.port.Q_flow + (TC_473_474.port_b.Q_flow + (TC_311_474.port_b.Q_flow + (CABI0CabiA009016006.port.Q_flow + (TC_474_475.port_a.Q_flow + (TC_474_528.port_a.Q_flow + (TC_474_1024.port_a.Q_flow + TC_474_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009016006.port.T = TC_311_474.port_b.T; CABI0CabiA009016006.port.T = TC_473_474.port_b.T; CABI0CabiA009016006.port.T = TC_474_0.port_a.T; CABI0CabiA009016006.port.T = TC_474_1024.port_a.T; CABI0CabiA009016006.port.T = TC_474_475.port_a.T; CABI0CabiA009016006.port.T = TC_474_528.port_a.T; CABI0CabiA009016006.port.T = TsCABI0CabiA009016006.port.T; TsCABI0CabiA008016006.port.Q_flow + (TC_472_473.port_b.Q_flow + (TC_310_473.port_b.Q_flow + (CABI0CabiA008016006.port.Q_flow + (TC_473_474.port_a.Q_flow + (TC_473_527.port_a.Q_flow + (TC_473_1023.port_a.Q_flow + TC_473_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008016006.port.T = TC_310_473.port_b.T; CABI0CabiA008016006.port.T = TC_472_473.port_b.T; CABI0CabiA008016006.port.T = TC_473_0.port_a.T; CABI0CabiA008016006.port.T = TC_473_1023.port_a.T; CABI0CabiA008016006.port.T = TC_473_474.port_a.T; CABI0CabiA008016006.port.T = TC_473_527.port_a.T; CABI0CabiA008016006.port.T = TsCABI0CabiA008016006.port.T; TsCABI0CabiA007016006.port.Q_flow + (TC_471_472.port_b.Q_flow + (TC_309_472.port_b.Q_flow + (CABI0CabiA007016006.port.Q_flow + (TC_472_473.port_a.Q_flow + (TC_472_526.port_a.Q_flow + (TC_472_1022.port_a.Q_flow + TC_472_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007016006.port.T = TC_309_472.port_b.T; CABI0CabiA007016006.port.T = TC_471_472.port_b.T; CABI0CabiA007016006.port.T = TC_472_0.port_a.T; CABI0CabiA007016006.port.T = TC_472_1022.port_a.T; CABI0CabiA007016006.port.T = TC_472_473.port_a.T; CABI0CabiA007016006.port.T = TC_472_526.port_a.T; CABI0CabiA007016006.port.T = TsCABI0CabiA007016006.port.T; TsCABI0CabiA006016006.port.Q_flow + (TC_470_471.port_b.Q_flow + (TC_308_471.port_b.Q_flow + (CABI0CabiA006016006.port.Q_flow + (TC_471_472.port_a.Q_flow + (TC_471_525.port_a.Q_flow + (TC_471_1021.port_a.Q_flow + TC_471_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006016006.port.T = TC_308_471.port_b.T; CABI0CabiA006016006.port.T = TC_470_471.port_b.T; CABI0CabiA006016006.port.T = TC_471_0.port_a.T; CABI0CabiA006016006.port.T = TC_471_1021.port_a.T; CABI0CabiA006016006.port.T = TC_471_472.port_a.T; CABI0CabiA006016006.port.T = TC_471_525.port_a.T; CABI0CabiA006016006.port.T = TsCABI0CabiA006016006.port.T; TsCABI0CabiA005016006.port.Q_flow + (TC_469_470.port_b.Q_flow + (TC_307_470.port_b.Q_flow + (CABI0CabiA005016006.port.Q_flow + (TC_470_471.port_a.Q_flow + (TC_470_524.port_a.Q_flow + (TC_470_1020.port_a.Q_flow + TC_470_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005016006.port.T = TC_307_470.port_b.T; CABI0CabiA005016006.port.T = TC_469_470.port_b.T; CABI0CabiA005016006.port.T = TC_470_0.port_a.T; CABI0CabiA005016006.port.T = TC_470_1020.port_a.T; CABI0CabiA005016006.port.T = TC_470_471.port_a.T; CABI0CabiA005016006.port.T = TC_470_524.port_a.T; CABI0CabiA005016006.port.T = TsCABI0CabiA005016006.port.T; TsCABI0CabiA004016006.port.Q_flow + (TC_468_469.port_b.Q_flow + (TC_306_469.port_b.Q_flow + (CABI0CabiA004016006.port.Q_flow + (TC_469_470.port_a.Q_flow + (TC_469_523.port_a.Q_flow + (TC_469_1019.port_a.Q_flow + TC_469_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004016006.port.T = TC_306_469.port_b.T; CABI0CabiA004016006.port.T = TC_468_469.port_b.T; CABI0CabiA004016006.port.T = TC_469_0.port_a.T; CABI0CabiA004016006.port.T = TC_469_1019.port_a.T; CABI0CabiA004016006.port.T = TC_469_470.port_a.T; CABI0CabiA004016006.port.T = TC_469_523.port_a.T; CABI0CabiA004016006.port.T = TsCABI0CabiA004016006.port.T; TsCABI0CabiA003016006.port.Q_flow + (TC_467_468.port_b.Q_flow + (TC_305_468.port_b.Q_flow + (CABI0CabiA003016006.port.Q_flow + (TC_468_469.port_a.Q_flow + (TC_468_522.port_a.Q_flow + (TC_468_1018.port_a.Q_flow + TC_468_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003016006.port.T = TC_305_468.port_b.T; CABI0CabiA003016006.port.T = TC_467_468.port_b.T; CABI0CabiA003016006.port.T = TC_468_0.port_a.T; CABI0CabiA003016006.port.T = TC_468_1018.port_a.T; CABI0CabiA003016006.port.T = TC_468_469.port_a.T; CABI0CabiA003016006.port.T = TC_468_522.port_a.T; CABI0CabiA003016006.port.T = TsCABI0CabiA003016006.port.T; TsCABI0CabiA002016006.port.Q_flow + (TC_466_467.port_b.Q_flow + (TC_304_467.port_b.Q_flow + (CABI0CabiA002016006.port.Q_flow + (TC_467_468.port_a.Q_flow + (TC_467_521.port_a.Q_flow + (TC_467_1017.port_a.Q_flow + TC_467_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002016006.port.T = TC_304_467.port_b.T; CABI0CabiA002016006.port.T = TC_466_467.port_b.T; CABI0CabiA002016006.port.T = TC_467_0.port_a.T; CABI0CabiA002016006.port.T = TC_467_1017.port_a.T; CABI0CabiA002016006.port.T = TC_467_468.port_a.T; CABI0CabiA002016006.port.T = TC_467_521.port_a.T; CABI0CabiA002016006.port.T = TsCABI0CabiA002016006.port.T; TsCABI0CabiA001016006.port.Q_flow + (TC_464_466.port_b.Q_flow + (TC_303_466.port_b.Q_flow + (CABI0CabiA001016006.port.Q_flow + (TC_466_467.port_a.Q_flow + (TC_466_520.port_a.Q_flow + TC_466_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001016006.port.T = TC_303_466.port_b.T; CABI0CabiA001016006.port.T = TC_464_466.port_b.T; CABI0CabiA001016006.port.T = TC_466_0.port_a.T; CABI0CabiA001016006.port.T = TC_466_467.port_a.T; CABI0CabiA001016006.port.T = TC_466_520.port_a.T; CABI0CabiA001016006.port.T = TsCABI0CabiA001016006.port.T; TsCABI0CabiA013015006.port.Q_flow + (TC_463_465.port_b.Q_flow + (TC_302_465.port_b.Q_flow + (CABI0CabiA013015006.port.Q_flow + (TC_465_478.port_a.Q_flow + (TC_465_519.port_a.Q_flow + (TC_465_1027.port_a.Q_flow + TC_465_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013015006.port.T = TC_302_465.port_b.T; CABI0CabiA013015006.port.T = TC_463_465.port_b.T; CABI0CabiA013015006.port.T = TC_465_0.port_a.T; CABI0CabiA013015006.port.T = TC_465_1027.port_a.T; CABI0CabiA013015006.port.T = TC_465_478.port_a.T; CABI0CabiA013015006.port.T = TC_465_519.port_a.T; CABI0CabiA013015006.port.T = TsCABI0CabiA013015006.port.T; TsCABI0CabiA001015006.port.Q_flow + (TC_462_464.port_b.Q_flow + (TC_301_464.port_b.Q_flow + (CABI0CabiA001015006.port.Q_flow + (TC_464_466.port_a.Q_flow + (TC_464_518.port_a.Q_flow + (TC_464_1017.port_a.Q_flow + TC_464_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001015006.port.T = TC_301_464.port_b.T; CABI0CabiA001015006.port.T = TC_462_464.port_b.T; CABI0CabiA001015006.port.T = TC_464_0.port_a.T; CABI0CabiA001015006.port.T = TC_464_1017.port_a.T; CABI0CabiA001015006.port.T = TC_464_466.port_a.T; CABI0CabiA001015006.port.T = TC_464_518.port_a.T; CABI0CabiA001015006.port.T = TsCABI0CabiA001015006.port.T; TsCABI0CabiA013014006.port.Q_flow + (TC_461_463.port_b.Q_flow + (TC_300_463.port_b.Q_flow + (CABI0CabiA013014006.port.Q_flow + (TC_463_465.port_a.Q_flow + (TC_463_517.port_a.Q_flow + (TC_463_1016.port_a.Q_flow + TC_463_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013014006.port.T = TC_300_463.port_b.T; CABI0CabiA013014006.port.T = TC_461_463.port_b.T; CABI0CabiA013014006.port.T = TC_463_0.port_a.T; CABI0CabiA013014006.port.T = TC_463_1016.port_a.T; CABI0CabiA013014006.port.T = TC_463_465.port_a.T; CABI0CabiA013014006.port.T = TC_463_517.port_a.T; CABI0CabiA013014006.port.T = TsCABI0CabiA013014006.port.T; TsCABI0CabiA001014006.port.Q_flow + (TC_460_462.port_b.Q_flow + (TC_299_462.port_b.Q_flow + (CABI0CabiA001014006.port.Q_flow + (TC_462_464.port_a.Q_flow + (TC_462_516.port_a.Q_flow + (TC_462_1006.port_a.Q_flow + TC_462_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001014006.port.T = TC_299_462.port_b.T; CABI0CabiA001014006.port.T = TC_460_462.port_b.T; CABI0CabiA001014006.port.T = TC_462_0.port_a.T; CABI0CabiA001014006.port.T = TC_462_1006.port_a.T; CABI0CabiA001014006.port.T = TC_462_464.port_a.T; CABI0CabiA001014006.port.T = TC_462_516.port_a.T; CABI0CabiA001014006.port.T = TsCABI0CabiA001014006.port.T; TsCABI0CabiA013013006.port.Q_flow + (TC_459_461.port_b.Q_flow + (TC_298_461.port_b.Q_flow + (CABI0CabiA013013006.port.Q_flow + (TC_461_463.port_a.Q_flow + (TC_461_515.port_a.Q_flow + (TC_461_1005.port_a.Q_flow + TC_461_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013013006.port.T = TC_298_461.port_b.T; CABI0CabiA013013006.port.T = TC_459_461.port_b.T; CABI0CabiA013013006.port.T = TC_461_0.port_a.T; CABI0CabiA013013006.port.T = TC_461_1005.port_a.T; CABI0CabiA013013006.port.T = TC_461_463.port_a.T; CABI0CabiA013013006.port.T = TC_461_515.port_a.T; CABI0CabiA013013006.port.T = TsCABI0CabiA013013006.port.T; TsCABI0CabiA001013006.port.Q_flow + (TC_458_460.port_b.Q_flow + (TC_297_460.port_b.Q_flow + (CABI0CabiA001013006.port.Q_flow + (TC_460_462.port_a.Q_flow + (TC_460_514.port_a.Q_flow + (TC_460_998.port_a.Q_flow + TC_460_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001013006.port.T = TC_297_460.port_b.T; CABI0CabiA001013006.port.T = TC_458_460.port_b.T; CABI0CabiA001013006.port.T = TC_460_0.port_a.T; CABI0CabiA001013006.port.T = TC_460_462.port_a.T; CABI0CabiA001013006.port.T = TC_460_514.port_a.T; CABI0CabiA001013006.port.T = TC_460_998.port_a.T; CABI0CabiA001013006.port.T = TsCABI0CabiA001013006.port.T; TsCABI0CabiA013012006.port.Q_flow + (TC_457_459.port_b.Q_flow + (TC_296_459.port_b.Q_flow + (CABI0CabiA013012006.port.Q_flow + (TC_459_461.port_a.Q_flow + (TC_459_513.port_a.Q_flow + (TC_459_997.port_a.Q_flow + TC_459_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013012006.port.T = TC_296_459.port_b.T; CABI0CabiA013012006.port.T = TC_457_459.port_b.T; CABI0CabiA013012006.port.T = TC_459_0.port_a.T; CABI0CabiA013012006.port.T = TC_459_461.port_a.T; CABI0CabiA013012006.port.T = TC_459_513.port_a.T; CABI0CabiA013012006.port.T = TC_459_997.port_a.T; CABI0CabiA013012006.port.T = TsCABI0CabiA013012006.port.T; TsCABI0CabiA001012006.port.Q_flow + (TC_456_458.port_b.Q_flow + (TC_295_458.port_b.Q_flow + (CABI0CabiA001012006.port.Q_flow + (TC_458_460.port_a.Q_flow + (TC_458_512.port_a.Q_flow + (TC_458_990.port_a.Q_flow + TC_458_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001012006.port.T = TC_295_458.port_b.T; CABI0CabiA001012006.port.T = TC_456_458.port_b.T; CABI0CabiA001012006.port.T = TC_458_0.port_a.T; CABI0CabiA001012006.port.T = TC_458_460.port_a.T; CABI0CabiA001012006.port.T = TC_458_512.port_a.T; CABI0CabiA001012006.port.T = TC_458_990.port_a.T; CABI0CabiA001012006.port.T = TsCABI0CabiA001012006.port.T; TsCABI0CabiA013011006.port.Q_flow + (TC_455_457.port_b.Q_flow + (TC_294_457.port_b.Q_flow + (CABI0CabiA013011006.port.Q_flow + (TC_457_459.port_a.Q_flow + (TC_457_511.port_a.Q_flow + (TC_457_989.port_a.Q_flow + TC_457_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013011006.port.T = TC_294_457.port_b.T; CABI0CabiA013011006.port.T = TC_455_457.port_b.T; CABI0CabiA013011006.port.T = TC_457_0.port_a.T; CABI0CabiA013011006.port.T = TC_457_459.port_a.T; CABI0CabiA013011006.port.T = TC_457_511.port_a.T; CABI0CabiA013011006.port.T = TC_457_989.port_a.T; CABI0CabiA013011006.port.T = TsCABI0CabiA013011006.port.T; TsCABI0CabiA001011006.port.Q_flow + (TC_454_456.port_b.Q_flow + (TC_293_456.port_b.Q_flow + (CABI0CabiA001011006.port.Q_flow + (TC_456_458.port_a.Q_flow + (TC_456_510.port_a.Q_flow + (TC_456_985.port_a.Q_flow + TC_456_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001011006.port.T = TC_293_456.port_b.T; CABI0CabiA001011006.port.T = TC_454_456.port_b.T; CABI0CabiA001011006.port.T = TC_456_0.port_a.T; CABI0CabiA001011006.port.T = TC_456_458.port_a.T; CABI0CabiA001011006.port.T = TC_456_510.port_a.T; CABI0CabiA001011006.port.T = TC_456_985.port_a.T; CABI0CabiA001011006.port.T = TsCABI0CabiA001011006.port.T; TsCABI0CabiA013010006.port.Q_flow + (TC_453_455.port_b.Q_flow + (TC_292_455.port_b.Q_flow + (CABI0CabiA013010006.port.Q_flow + (TC_455_457.port_a.Q_flow + (TC_455_509.port_a.Q_flow + (TC_455_984.port_a.Q_flow + TC_455_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013010006.port.T = TC_292_455.port_b.T; CABI0CabiA013010006.port.T = TC_453_455.port_b.T; CABI0CabiA013010006.port.T = TC_455_0.port_a.T; CABI0CabiA013010006.port.T = TC_455_457.port_a.T; CABI0CabiA013010006.port.T = TC_455_509.port_a.T; CABI0CabiA013010006.port.T = TC_455_984.port_a.T; CABI0CabiA013010006.port.T = TsCABI0CabiA013010006.port.T; TsCABI0CabiA001010006.port.Q_flow + (TC_452_454.port_b.Q_flow + (TC_291_454.port_b.Q_flow + (CABI0CabiA001010006.port.Q_flow + (TC_454_456.port_a.Q_flow + (TC_454_508.port_a.Q_flow + (TC_454_977.port_a.Q_flow + TC_454_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001010006.port.T = TC_291_454.port_b.T; CABI0CabiA001010006.port.T = TC_452_454.port_b.T; CABI0CabiA001010006.port.T = TC_454_0.port_a.T; CABI0CabiA001010006.port.T = TC_454_456.port_a.T; CABI0CabiA001010006.port.T = TC_454_508.port_a.T; CABI0CabiA001010006.port.T = TC_454_977.port_a.T; CABI0CabiA001010006.port.T = TsCABI0CabiA001010006.port.T; TsCABI0CabiA013009006.port.Q_flow + (TC_451_453.port_b.Q_flow + (TC_290_453.port_b.Q_flow + (CABI0CabiA013009006.port.Q_flow + (TC_453_455.port_a.Q_flow + (TC_453_507.port_a.Q_flow + (TC_453_976.port_a.Q_flow + TC_453_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013009006.port.T = TC_290_453.port_b.T; CABI0CabiA013009006.port.T = TC_451_453.port_b.T; CABI0CabiA013009006.port.T = TC_453_0.port_a.T; CABI0CabiA013009006.port.T = TC_453_455.port_a.T; CABI0CabiA013009006.port.T = TC_453_507.port_a.T; CABI0CabiA013009006.port.T = TC_453_976.port_a.T; CABI0CabiA013009006.port.T = TsCABI0CabiA013009006.port.T; TsCABI0CabiA001009006.port.Q_flow + (TC_450_452.port_b.Q_flow + (TC_289_452.port_b.Q_flow + (CABI0CabiA001009006.port.Q_flow + (TC_452_454.port_a.Q_flow + (TC_452_506.port_a.Q_flow + (TC_452_1060.port_a.Q_flow + TC_452_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001009006.port.T = TC_289_452.port_b.T; CABI0CabiA001009006.port.T = TC_450_452.port_b.T; CABI0CabiA001009006.port.T = TC_452_0.port_a.T; CABI0CabiA001009006.port.T = TC_452_1060.port_a.T; CABI0CabiA001009006.port.T = TC_452_454.port_a.T; CABI0CabiA001009006.port.T = TC_452_506.port_a.T; CABI0CabiA001009006.port.T = TsCABI0CabiA001009006.port.T; TsCABI0CabiA013008006.port.Q_flow + (TC_449_451.port_b.Q_flow + (TC_288_451.port_b.Q_flow + (CABI0CabiA013008006.port.Q_flow + (TC_451_453.port_a.Q_flow + (TC_451_505.port_a.Q_flow + (TC_451_1059.port_a.Q_flow + TC_451_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013008006.port.T = TC_288_451.port_b.T; CABI0CabiA013008006.port.T = TC_449_451.port_b.T; CABI0CabiA013008006.port.T = TC_451_0.port_a.T; CABI0CabiA013008006.port.T = TC_451_1059.port_a.T; CABI0CabiA013008006.port.T = TC_451_453.port_a.T; CABI0CabiA013008006.port.T = TC_451_505.port_a.T; CABI0CabiA013008006.port.T = TsCABI0CabiA013008006.port.T; TsCABI0CabiA001008006.port.Q_flow + (TC_448_450.port_b.Q_flow + (TC_287_450.port_b.Q_flow + (CABI0CabiA001008006.port.Q_flow + (TC_450_452.port_a.Q_flow + (TC_450_504.port_a.Q_flow + (TC_450_1049.port_a.Q_flow + TC_450_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001008006.port.T = TC_287_450.port_b.T; CABI0CabiA001008006.port.T = TC_448_450.port_b.T; CABI0CabiA001008006.port.T = TC_450_0.port_a.T; CABI0CabiA001008006.port.T = TC_450_1049.port_a.T; CABI0CabiA001008006.port.T = TC_450_452.port_a.T; CABI0CabiA001008006.port.T = TC_450_504.port_a.T; CABI0CabiA001008006.port.T = TsCABI0CabiA001008006.port.T; TsCABI0CabiA013007006.port.Q_flow + (TC_447_449.port_b.Q_flow + (TC_286_449.port_b.Q_flow + (CABI0CabiA013007006.port.Q_flow + (TC_449_451.port_a.Q_flow + (TC_449_503.port_a.Q_flow + (TC_449_1048.port_a.Q_flow + TC_449_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013007006.port.T = TC_286_449.port_b.T; CABI0CabiA013007006.port.T = TC_447_449.port_b.T; CABI0CabiA013007006.port.T = TC_449_0.port_a.T; CABI0CabiA013007006.port.T = TC_449_1048.port_a.T; CABI0CabiA013007006.port.T = TC_449_451.port_a.T; CABI0CabiA013007006.port.T = TC_449_503.port_a.T; CABI0CabiA013007006.port.T = TsCABI0CabiA013007006.port.T; TsCABI0CabiA001007006.port.Q_flow + (TC_446_448.port_b.Q_flow + (TC_285_448.port_b.Q_flow + (CABI0CabiA001007006.port.Q_flow + (TC_448_450.port_a.Q_flow + (TC_448_502.port_a.Q_flow + (TC_448_1038.port_a.Q_flow + TC_448_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001007006.port.T = TC_285_448.port_b.T; CABI0CabiA001007006.port.T = TC_446_448.port_b.T; CABI0CabiA001007006.port.T = TC_448_0.port_a.T; CABI0CabiA001007006.port.T = TC_448_1038.port_a.T; CABI0CabiA001007006.port.T = TC_448_450.port_a.T; CABI0CabiA001007006.port.T = TC_448_502.port_a.T; CABI0CabiA001007006.port.T = TsCABI0CabiA001007006.port.T; TsCABI0CabiA013006006.port.Q_flow + (TC_445_447.port_b.Q_flow + (TC_284_447.port_b.Q_flow + (CABI0CabiA013006006.port.Q_flow + (TC_447_449.port_a.Q_flow + (TC_447_501.port_a.Q_flow + (TC_447_1037.port_a.Q_flow + TC_447_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013006006.port.T = TC_284_447.port_b.T; CABI0CabiA013006006.port.T = TC_445_447.port_b.T; CABI0CabiA013006006.port.T = TC_447_0.port_a.T; CABI0CabiA013006006.port.T = TC_447_1037.port_a.T; CABI0CabiA013006006.port.T = TC_447_449.port_a.T; CABI0CabiA013006006.port.T = TC_447_501.port_a.T; CABI0CabiA013006006.port.T = TsCABI0CabiA013006006.port.T; TsCABI0CabiA001006006.port.Q_flow + (TC_444_446.port_b.Q_flow + (TC_283_446.port_b.Q_flow + (CABI0CabiA001006006.port.Q_flow + (TC_446_448.port_a.Q_flow + (TC_446_500.port_a.Q_flow + (TC_446_1031.port_a.Q_flow + TC_446_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001006006.port.T = TC_283_446.port_b.T; CABI0CabiA001006006.port.T = TC_444_446.port_b.T; CABI0CabiA001006006.port.T = TC_446_0.port_a.T; CABI0CabiA001006006.port.T = TC_446_1031.port_a.T; CABI0CabiA001006006.port.T = TC_446_448.port_a.T; CABI0CabiA001006006.port.T = TC_446_500.port_a.T; CABI0CabiA001006006.port.T = TsCABI0CabiA001006006.port.T; TsCABI0CabiA013005006.port.Q_flow + (TC_443_445.port_b.Q_flow + (TC_282_445.port_b.Q_flow + (CABI0CabiA013005006.port.Q_flow + (TC_445_447.port_a.Q_flow + (TC_445_499.port_a.Q_flow + (TC_445_1030.port_a.Q_flow + TC_445_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013005006.port.T = TC_282_445.port_b.T; CABI0CabiA013005006.port.T = TC_443_445.port_b.T; CABI0CabiA013005006.port.T = TC_445_0.port_a.T; CABI0CabiA013005006.port.T = TC_445_1030.port_a.T; CABI0CabiA013005006.port.T = TC_445_447.port_a.T; CABI0CabiA013005006.port.T = TC_445_499.port_a.T; CABI0CabiA013005006.port.T = TsCABI0CabiA013005006.port.T; TsCABI0CabiA001005006.port.Q_flow + (TC_442_444.port_b.Q_flow + (TC_281_444.port_b.Q_flow + (CABI0CabiA001005006.port.Q_flow + (TC_444_446.port_a.Q_flow + (TC_444_498.port_a.Q_flow + (TC_444_1095.port_a.Q_flow + TC_444_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001005006.port.T = TC_281_444.port_b.T; CABI0CabiA001005006.port.T = TC_442_444.port_b.T; CABI0CabiA001005006.port.T = TC_444_0.port_a.T; CABI0CabiA001005006.port.T = TC_444_1095.port_a.T; CABI0CabiA001005006.port.T = TC_444_446.port_a.T; CABI0CabiA001005006.port.T = TC_444_498.port_a.T; CABI0CabiA001005006.port.T = TsCABI0CabiA001005006.port.T; TsCABI0CabiA013004006.port.Q_flow + (TC_441_443.port_b.Q_flow + (TC_280_443.port_b.Q_flow + (CABI0CabiA013004006.port.Q_flow + (TC_443_445.port_a.Q_flow + (TC_443_497.port_a.Q_flow + (TC_443_1094.port_a.Q_flow + TC_443_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013004006.port.T = TC_280_443.port_b.T; CABI0CabiA013004006.port.T = TC_441_443.port_b.T; CABI0CabiA013004006.port.T = TC_443_0.port_a.T; CABI0CabiA013004006.port.T = TC_443_1094.port_a.T; CABI0CabiA013004006.port.T = TC_443_445.port_a.T; CABI0CabiA013004006.port.T = TC_443_497.port_a.T; CABI0CabiA013004006.port.T = TsCABI0CabiA013004006.port.T; TsCABI0CabiA001004006.port.Q_flow + (TC_440_442.port_b.Q_flow + (TC_279_442.port_b.Q_flow + (CABI0CabiA001004006.port.Q_flow + (TC_442_444.port_a.Q_flow + (TC_442_496.port_a.Q_flow + (TC_442_1088.port_a.Q_flow + TC_442_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001004006.port.T = TC_279_442.port_b.T; CABI0CabiA001004006.port.T = TC_440_442.port_b.T; CABI0CabiA001004006.port.T = TC_442_0.port_a.T; CABI0CabiA001004006.port.T = TC_442_1088.port_a.T; CABI0CabiA001004006.port.T = TC_442_444.port_a.T; CABI0CabiA001004006.port.T = TC_442_496.port_a.T; CABI0CabiA001004006.port.T = TsCABI0CabiA001004006.port.T; TsCABI0CabiA013003006.port.Q_flow + (TC_439_441.port_b.Q_flow + (TC_278_441.port_b.Q_flow + (CABI0CabiA013003006.port.Q_flow + (TC_441_443.port_a.Q_flow + (TC_441_495.port_a.Q_flow + (TC_441_1087.port_a.Q_flow + TC_441_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013003006.port.T = TC_278_441.port_b.T; CABI0CabiA013003006.port.T = TC_439_441.port_b.T; CABI0CabiA013003006.port.T = TC_441_0.port_a.T; CABI0CabiA013003006.port.T = TC_441_1087.port_a.T; CABI0CabiA013003006.port.T = TC_441_443.port_a.T; CABI0CabiA013003006.port.T = TC_441_495.port_a.T; CABI0CabiA013003006.port.T = TsCABI0CabiA013003006.port.T; TsCABI0CabiA001003006.port.Q_flow + (TC_438_440.port_b.Q_flow + (TC_277_440.port_b.Q_flow + (CABI0CabiA001003006.port.Q_flow + (TC_440_442.port_a.Q_flow + (TC_440_494.port_a.Q_flow + (TC_440_1077.port_a.Q_flow + TC_440_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001003006.port.T = TC_277_440.port_b.T; CABI0CabiA001003006.port.T = TC_438_440.port_b.T; CABI0CabiA001003006.port.T = TC_440_0.port_a.T; CABI0CabiA001003006.port.T = TC_440_1077.port_a.T; CABI0CabiA001003006.port.T = TC_440_442.port_a.T; CABI0CabiA001003006.port.T = TC_440_494.port_a.T; CABI0CabiA001003006.port.T = TsCABI0CabiA001003006.port.T; TsCABI0CabiA013002006.port.Q_flow + (TC_437_439.port_b.Q_flow + (TC_276_439.port_b.Q_flow + (CABI0CabiA013002006.port.Q_flow + (TC_439_441.port_a.Q_flow + (TC_439_493.port_a.Q_flow + (TC_439_1076.port_a.Q_flow + TC_439_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013002006.port.T = TC_276_439.port_b.T; CABI0CabiA013002006.port.T = TC_437_439.port_b.T; CABI0CabiA013002006.port.T = TC_439_0.port_a.T; CABI0CabiA013002006.port.T = TC_439_1076.port_a.T; CABI0CabiA013002006.port.T = TC_439_441.port_a.T; CABI0CabiA013002006.port.T = TC_439_493.port_a.T; CABI0CabiA013002006.port.T = TsCABI0CabiA013002006.port.T; TsCABI0CabiA001002006.port.Q_flow + (TC_425_438.port_b.Q_flow + (TC_275_438.port_b.Q_flow + (CABI0CabiA001002006.port.Q_flow + (TC_438_440.port_a.Q_flow + (TC_438_492.port_a.Q_flow + (TC_438_1066.port_a.Q_flow + TC_438_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001002006.port.T = TC_275_438.port_b.T; CABI0CabiA001002006.port.T = TC_425_438.port_b.T; CABI0CabiA001002006.port.T = TC_438_0.port_a.T; CABI0CabiA001002006.port.T = TC_438_1066.port_a.T; CABI0CabiA001002006.port.T = TC_438_440.port_a.T; CABI0CabiA001002006.port.T = TC_438_492.port_a.T; CABI0CabiA001002006.port.T = TsCABI0CabiA001002006.port.T; TsCABI0CabiA013001006.port.Q_flow + (TC_436_437.port_b.Q_flow + (TC_274_437.port_b.Q_flow + (CABI0CabiA013001006.port.Q_flow + (TC_437_439.port_a.Q_flow + (TC_437_491.port_a.Q_flow + TC_437_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013001006.port.T = TC_274_437.port_b.T; CABI0CabiA013001006.port.T = TC_436_437.port_b.T; CABI0CabiA013001006.port.T = TC_437_0.port_a.T; CABI0CabiA013001006.port.T = TC_437_439.port_a.T; CABI0CabiA013001006.port.T = TC_437_491.port_a.T; CABI0CabiA013001006.port.T = TsCABI0CabiA013001006.port.T; TsCABI0CabiA012001006.port.Q_flow + (TC_435_436.port_b.Q_flow + (TC_273_436.port_b.Q_flow + (CABI0CabiA012001006.port.Q_flow + (TC_436_437.port_a.Q_flow + (TC_436_490.port_a.Q_flow + (TC_436_1076.port_a.Q_flow + TC_436_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012001006.port.T = TC_273_436.port_b.T; CABI0CabiA012001006.port.T = TC_435_436.port_b.T; CABI0CabiA012001006.port.T = TC_436_0.port_a.T; CABI0CabiA012001006.port.T = TC_436_1076.port_a.T; CABI0CabiA012001006.port.T = TC_436_437.port_a.T; CABI0CabiA012001006.port.T = TC_436_490.port_a.T; CABI0CabiA012001006.port.T = TsCABI0CabiA012001006.port.T; TsCABI0CabiA011001006.port.Q_flow + (TC_434_435.port_b.Q_flow + (TC_272_435.port_b.Q_flow + (CABI0CabiA011001006.port.Q_flow + (TC_435_436.port_a.Q_flow + (TC_435_489.port_a.Q_flow + (TC_435_1075.port_a.Q_flow + TC_435_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011001006.port.T = TC_272_435.port_b.T; CABI0CabiA011001006.port.T = TC_434_435.port_b.T; CABI0CabiA011001006.port.T = TC_435_0.port_a.T; CABI0CabiA011001006.port.T = TC_435_1075.port_a.T; CABI0CabiA011001006.port.T = TC_435_436.port_a.T; CABI0CabiA011001006.port.T = TC_435_489.port_a.T; CABI0CabiA011001006.port.T = TsCABI0CabiA011001006.port.T; TsCABI0CabiA010001006.port.Q_flow + (TC_433_434.port_b.Q_flow + (TC_271_434.port_b.Q_flow + (CABI0CabiA010001006.port.Q_flow + (TC_434_435.port_a.Q_flow + (TC_434_488.port_a.Q_flow + (TC_434_1074.port_a.Q_flow + TC_434_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010001006.port.T = TC_271_434.port_b.T; CABI0CabiA010001006.port.T = TC_433_434.port_b.T; CABI0CabiA010001006.port.T = TC_434_0.port_a.T; CABI0CabiA010001006.port.T = TC_434_1074.port_a.T; CABI0CabiA010001006.port.T = TC_434_435.port_a.T; CABI0CabiA010001006.port.T = TC_434_488.port_a.T; CABI0CabiA010001006.port.T = TsCABI0CabiA010001006.port.T; TsCABI0CabiA009001006.port.Q_flow + (TC_432_433.port_b.Q_flow + (TC_270_433.port_b.Q_flow + (CABI0CabiA009001006.port.Q_flow + (TC_433_434.port_a.Q_flow + (TC_433_487.port_a.Q_flow + (TC_433_1073.port_a.Q_flow + TC_433_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009001006.port.T = TC_270_433.port_b.T; CABI0CabiA009001006.port.T = TC_432_433.port_b.T; CABI0CabiA009001006.port.T = TC_433_0.port_a.T; CABI0CabiA009001006.port.T = TC_433_1073.port_a.T; CABI0CabiA009001006.port.T = TC_433_434.port_a.T; CABI0CabiA009001006.port.T = TC_433_487.port_a.T; CABI0CabiA009001006.port.T = TsCABI0CabiA009001006.port.T; TsCABI0CabiA008001006.port.Q_flow + (TC_431_432.port_b.Q_flow + (TC_269_432.port_b.Q_flow + (CABI0CabiA008001006.port.Q_flow + (TC_432_433.port_a.Q_flow + (TC_432_486.port_a.Q_flow + (TC_432_1072.port_a.Q_flow + TC_432_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008001006.port.T = TC_269_432.port_b.T; CABI0CabiA008001006.port.T = TC_431_432.port_b.T; CABI0CabiA008001006.port.T = TC_432_0.port_a.T; CABI0CabiA008001006.port.T = TC_432_1072.port_a.T; CABI0CabiA008001006.port.T = TC_432_433.port_a.T; CABI0CabiA008001006.port.T = TC_432_486.port_a.T; CABI0CabiA008001006.port.T = TsCABI0CabiA008001006.port.T; TsCABI0CabiA007001006.port.Q_flow + (TC_430_431.port_b.Q_flow + (TC_268_431.port_b.Q_flow + (CABI0CabiA007001006.port.Q_flow + (TC_431_432.port_a.Q_flow + (TC_431_485.port_a.Q_flow + (TC_431_1071.port_a.Q_flow + TC_431_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007001006.port.T = TC_268_431.port_b.T; CABI0CabiA007001006.port.T = TC_430_431.port_b.T; CABI0CabiA007001006.port.T = TC_431_0.port_a.T; CABI0CabiA007001006.port.T = TC_431_1071.port_a.T; CABI0CabiA007001006.port.T = TC_431_432.port_a.T; CABI0CabiA007001006.port.T = TC_431_485.port_a.T; CABI0CabiA007001006.port.T = TsCABI0CabiA007001006.port.T; TsCABI0CabiA006001006.port.Q_flow + (TC_429_430.port_b.Q_flow + (TC_267_430.port_b.Q_flow + (CABI0CabiA006001006.port.Q_flow + (TC_430_431.port_a.Q_flow + (TC_430_484.port_a.Q_flow + (TC_430_1070.port_a.Q_flow + TC_430_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006001006.port.T = TC_267_430.port_b.T; CABI0CabiA006001006.port.T = TC_429_430.port_b.T; CABI0CabiA006001006.port.T = TC_430_0.port_a.T; CABI0CabiA006001006.port.T = TC_430_1070.port_a.T; CABI0CabiA006001006.port.T = TC_430_431.port_a.T; CABI0CabiA006001006.port.T = TC_430_484.port_a.T; CABI0CabiA006001006.port.T = TsCABI0CabiA006001006.port.T; TsCABI0CabiA005001006.port.Q_flow + (TC_428_429.port_b.Q_flow + (TC_266_429.port_b.Q_flow + (CABI0CabiA005001006.port.Q_flow + (TC_429_430.port_a.Q_flow + (TC_429_483.port_a.Q_flow + (TC_429_1069.port_a.Q_flow + TC_429_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005001006.port.T = TC_266_429.port_b.T; CABI0CabiA005001006.port.T = TC_428_429.port_b.T; CABI0CabiA005001006.port.T = TC_429_0.port_a.T; CABI0CabiA005001006.port.T = TC_429_1069.port_a.T; CABI0CabiA005001006.port.T = TC_429_430.port_a.T; CABI0CabiA005001006.port.T = TC_429_483.port_a.T; CABI0CabiA005001006.port.T = TsCABI0CabiA005001006.port.T; TsCABI0CabiA004001006.port.Q_flow + (TC_427_428.port_b.Q_flow + (TC_265_428.port_b.Q_flow + (CABI0CabiA004001006.port.Q_flow + (TC_428_429.port_a.Q_flow + (TC_428_482.port_a.Q_flow + (TC_428_1068.port_a.Q_flow + TC_428_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004001006.port.T = TC_265_428.port_b.T; CABI0CabiA004001006.port.T = TC_427_428.port_b.T; CABI0CabiA004001006.port.T = TC_428_0.port_a.T; CABI0CabiA004001006.port.T = TC_428_1068.port_a.T; CABI0CabiA004001006.port.T = TC_428_429.port_a.T; CABI0CabiA004001006.port.T = TC_428_482.port_a.T; CABI0CabiA004001006.port.T = TsCABI0CabiA004001006.port.T; TsCABI0CabiA003001006.port.Q_flow + (TC_426_427.port_b.Q_flow + (TC_264_427.port_b.Q_flow + (CABI0CabiA003001006.port.Q_flow + (TC_427_428.port_a.Q_flow + (TC_427_481.port_a.Q_flow + (TC_427_1067.port_a.Q_flow + TC_427_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003001006.port.T = TC_264_427.port_b.T; CABI0CabiA003001006.port.T = TC_426_427.port_b.T; CABI0CabiA003001006.port.T = TC_427_0.port_a.T; CABI0CabiA003001006.port.T = TC_427_1067.port_a.T; CABI0CabiA003001006.port.T = TC_427_428.port_a.T; CABI0CabiA003001006.port.T = TC_427_481.port_a.T; CABI0CabiA003001006.port.T = TsCABI0CabiA003001006.port.T; TsCABI0CabiA002001006.port.Q_flow + (TC_425_426.port_b.Q_flow + (TC_263_426.port_b.Q_flow + (CABI0CabiA002001006.port.Q_flow + (TC_426_427.port_a.Q_flow + (TC_426_480.port_a.Q_flow + (TC_426_1066.port_a.Q_flow + TC_426_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002001006.port.T = TC_263_426.port_b.T; CABI0CabiA002001006.port.T = TC_425_426.port_b.T; CABI0CabiA002001006.port.T = TC_426_0.port_a.T; CABI0CabiA002001006.port.T = TC_426_1066.port_a.T; CABI0CabiA002001006.port.T = TC_426_427.port_a.T; CABI0CabiA002001006.port.T = TC_426_480.port_a.T; CABI0CabiA002001006.port.T = TsCABI0CabiA002001006.port.T; TsCABI0CabiA001001006.port.Q_flow + (TC_262_425.port_b.Q_flow + (CABI0CabiA001001006.port.Q_flow + (TC_425_426.port_a.Q_flow + (TC_425_438.port_a.Q_flow + (TC_425_479.port_a.Q_flow + TC_425_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001001006.port.T = TC_262_425.port_b.T; CABI0CabiA001001006.port.T = TC_425_0.port_a.T; CABI0CabiA001001006.port.T = TC_425_426.port_a.T; CABI0CabiA001001006.port.T = TC_425_438.port_a.T; CABI0CabiA001001006.port.T = TC_425_479.port_a.T; CABI0CabiA001001006.port.T = TsCABI0CabiA001001006.port.T; TsCABI0CabiA001001002.port.Q_flow + (TC_370_424.port_b.Q_flow + (TC_221_424.port_b.Q_flow + (TC_209_424.port_b.Q_flow + (TC_1_424.port_b.Q_flow + (CABI0CabiA001001002.port.Q_flow + TC_424_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001001002.port.T = TC_1_424.port_b.T; CABI0CabiA001001002.port.T = TC_209_424.port_b.T; CABI0CabiA001001002.port.T = TC_221_424.port_b.T; CABI0CabiA001001002.port.T = TC_370_424.port_b.T; CABI0CabiA001001002.port.T = TC_424_0.port_a.T; CABI0CabiA001001002.port.T = TsCABI0CabiA001001002.port.T; TsCABI0CabiA013016003.port.Q_flow + (TC_422_423.port_b.Q_flow + (TC_410_423.port_b.Q_flow + (TC_369_423.port_b.Q_flow + (TC_261_423.port_b.Q_flow + (CABI0CabiA013016003.port.Q_flow + TC_423_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013016003.port.T = TC_261_423.port_b.T; CABI0CabiA013016003.port.T = TC_369_423.port_b.T; CABI0CabiA013016003.port.T = TC_410_423.port_b.T; CABI0CabiA013016003.port.T = TC_422_423.port_b.T; CABI0CabiA013016003.port.T = TC_423_0.port_a.T; CABI0CabiA013016003.port.T = TsCABI0CabiA013016003.port.T; TsCABI0CabiA012016003.port.Q_flow + (TC_421_422.port_b.Q_flow + (TC_368_422.port_b.Q_flow + (TC_260_422.port_b.Q_flow + (CABI0CabiA012016003.port.Q_flow + (TC_422_423.port_a.Q_flow + (TC_422_1413.port_a.Q_flow + TC_422_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012016003.port.T = TC_260_422.port_b.T; CABI0CabiA012016003.port.T = TC_368_422.port_b.T; CABI0CabiA012016003.port.T = TC_421_422.port_b.T; CABI0CabiA012016003.port.T = TC_422_0.port_a.T; CABI0CabiA012016003.port.T = TC_422_1413.port_a.T; CABI0CabiA012016003.port.T = TC_422_423.port_a.T; CABI0CabiA012016003.port.T = TsCABI0CabiA012016003.port.T; TsCABI0CabiA011016003.port.Q_flow + (TC_420_421.port_b.Q_flow + (TC_367_421.port_b.Q_flow + (TC_259_421.port_b.Q_flow + (CABI0CabiA011016003.port.Q_flow + (TC_421_422.port_a.Q_flow + (TC_421_1412.port_a.Q_flow + TC_421_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011016003.port.T = TC_259_421.port_b.T; CABI0CabiA011016003.port.T = TC_367_421.port_b.T; CABI0CabiA011016003.port.T = TC_420_421.port_b.T; CABI0CabiA011016003.port.T = TC_421_0.port_a.T; CABI0CabiA011016003.port.T = TC_421_1412.port_a.T; CABI0CabiA011016003.port.T = TC_421_422.port_a.T; CABI0CabiA011016003.port.T = TsCABI0CabiA011016003.port.T; TsCABI0CabiA010016003.port.Q_flow + (TC_419_420.port_b.Q_flow + (TC_366_420.port_b.Q_flow + (TC_258_420.port_b.Q_flow + (CABI0CabiA010016003.port.Q_flow + (TC_420_421.port_a.Q_flow + (TC_420_1411.port_a.Q_flow + TC_420_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010016003.port.T = TC_258_420.port_b.T; CABI0CabiA010016003.port.T = TC_366_420.port_b.T; CABI0CabiA010016003.port.T = TC_419_420.port_b.T; CABI0CabiA010016003.port.T = TC_420_0.port_a.T; CABI0CabiA010016003.port.T = TC_420_1411.port_a.T; CABI0CabiA010016003.port.T = TC_420_421.port_a.T; CABI0CabiA010016003.port.T = TsCABI0CabiA010016003.port.T; TsCABI0CabiA009016003.port.Q_flow + (TC_418_419.port_b.Q_flow + (TC_365_419.port_b.Q_flow + (TC_257_419.port_b.Q_flow + (CABI0CabiA009016003.port.Q_flow + (TC_419_420.port_a.Q_flow + (TC_419_1410.port_a.Q_flow + TC_419_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009016003.port.T = TC_257_419.port_b.T; CABI0CabiA009016003.port.T = TC_365_419.port_b.T; CABI0CabiA009016003.port.T = TC_418_419.port_b.T; CABI0CabiA009016003.port.T = TC_419_0.port_a.T; CABI0CabiA009016003.port.T = TC_419_1410.port_a.T; CABI0CabiA009016003.port.T = TC_419_420.port_a.T; CABI0CabiA009016003.port.T = TsCABI0CabiA009016003.port.T; TsCABI0CabiA008016003.port.Q_flow + (TC_417_418.port_b.Q_flow + (TC_364_418.port_b.Q_flow + (TC_256_418.port_b.Q_flow + (CABI0CabiA008016003.port.Q_flow + (TC_418_419.port_a.Q_flow + (TC_418_1409.port_a.Q_flow + TC_418_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008016003.port.T = TC_256_418.port_b.T; CABI0CabiA008016003.port.T = TC_364_418.port_b.T; CABI0CabiA008016003.port.T = TC_417_418.port_b.T; CABI0CabiA008016003.port.T = TC_418_0.port_a.T; CABI0CabiA008016003.port.T = TC_418_1409.port_a.T; CABI0CabiA008016003.port.T = TC_418_419.port_a.T; CABI0CabiA008016003.port.T = TsCABI0CabiA008016003.port.T; TsCABI0CabiA007016003.port.Q_flow + (TC_416_417.port_b.Q_flow + (TC_363_417.port_b.Q_flow + (TC_255_417.port_b.Q_flow + (CABI0CabiA007016003.port.Q_flow + (TC_417_418.port_a.Q_flow + (TC_417_1408.port_a.Q_flow + TC_417_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007016003.port.T = TC_255_417.port_b.T; CABI0CabiA007016003.port.T = TC_363_417.port_b.T; CABI0CabiA007016003.port.T = TC_416_417.port_b.T; CABI0CabiA007016003.port.T = TC_417_0.port_a.T; CABI0CabiA007016003.port.T = TC_417_1408.port_a.T; CABI0CabiA007016003.port.T = TC_417_418.port_a.T; CABI0CabiA007016003.port.T = TsCABI0CabiA007016003.port.T; TsCABI0CabiA006016003.port.Q_flow + (TC_415_416.port_b.Q_flow + (TC_362_416.port_b.Q_flow + (TC_254_416.port_b.Q_flow + (CABI0CabiA006016003.port.Q_flow + (TC_416_417.port_a.Q_flow + (TC_416_1407.port_a.Q_flow + TC_416_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006016003.port.T = TC_254_416.port_b.T; CABI0CabiA006016003.port.T = TC_362_416.port_b.T; CABI0CabiA006016003.port.T = TC_415_416.port_b.T; CABI0CabiA006016003.port.T = TC_416_0.port_a.T; CABI0CabiA006016003.port.T = TC_416_1407.port_a.T; CABI0CabiA006016003.port.T = TC_416_417.port_a.T; CABI0CabiA006016003.port.T = TsCABI0CabiA006016003.port.T; TsCABI0CabiA005016003.port.Q_flow + (TC_414_415.port_b.Q_flow + (TC_361_415.port_b.Q_flow + (TC_253_415.port_b.Q_flow + (CABI0CabiA005016003.port.Q_flow + (TC_415_416.port_a.Q_flow + (TC_415_1406.port_a.Q_flow + TC_415_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005016003.port.T = TC_253_415.port_b.T; CABI0CabiA005016003.port.T = TC_361_415.port_b.T; CABI0CabiA005016003.port.T = TC_414_415.port_b.T; CABI0CabiA005016003.port.T = TC_415_0.port_a.T; CABI0CabiA005016003.port.T = TC_415_1406.port_a.T; CABI0CabiA005016003.port.T = TC_415_416.port_a.T; CABI0CabiA005016003.port.T = TsCABI0CabiA005016003.port.T; TsCABI0CabiA004016003.port.Q_flow + (TC_413_414.port_b.Q_flow + (TC_360_414.port_b.Q_flow + (TC_252_414.port_b.Q_flow + (CABI0CabiA004016003.port.Q_flow + (TC_414_415.port_a.Q_flow + (TC_414_1405.port_a.Q_flow + TC_414_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004016003.port.T = TC_252_414.port_b.T; CABI0CabiA004016003.port.T = TC_360_414.port_b.T; CABI0CabiA004016003.port.T = TC_413_414.port_b.T; CABI0CabiA004016003.port.T = TC_414_0.port_a.T; CABI0CabiA004016003.port.T = TC_414_1405.port_a.T; CABI0CabiA004016003.port.T = TC_414_415.port_a.T; CABI0CabiA004016003.port.T = TsCABI0CabiA004016003.port.T; TsCABI0CabiA003016003.port.Q_flow + (TC_412_413.port_b.Q_flow + (TC_359_413.port_b.Q_flow + (TC_251_413.port_b.Q_flow + (CABI0CabiA003016003.port.Q_flow + (TC_413_414.port_a.Q_flow + (TC_413_1404.port_a.Q_flow + TC_413_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003016003.port.T = TC_251_413.port_b.T; CABI0CabiA003016003.port.T = TC_359_413.port_b.T; CABI0CabiA003016003.port.T = TC_412_413.port_b.T; CABI0CabiA003016003.port.T = TC_413_0.port_a.T; CABI0CabiA003016003.port.T = TC_413_1404.port_a.T; CABI0CabiA003016003.port.T = TC_413_414.port_a.T; CABI0CabiA003016003.port.T = TsCABI0CabiA003016003.port.T; TsCABI0CabiA002016003.port.Q_flow + (TC_411_412.port_b.Q_flow + (TC_358_412.port_b.Q_flow + (TC_250_412.port_b.Q_flow + (CABI0CabiA002016003.port.Q_flow + (TC_412_413.port_a.Q_flow + (TC_412_1403.port_a.Q_flow + TC_412_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002016003.port.T = TC_250_412.port_b.T; CABI0CabiA002016003.port.T = TC_358_412.port_b.T; CABI0CabiA002016003.port.T = TC_411_412.port_b.T; CABI0CabiA002016003.port.T = TC_412_0.port_a.T; CABI0CabiA002016003.port.T = TC_412_1403.port_a.T; CABI0CabiA002016003.port.T = TC_412_413.port_a.T; CABI0CabiA002016003.port.T = TsCABI0CabiA002016003.port.T; TsCABI0CabiA001016003.port.Q_flow + (TC_409_411.port_b.Q_flow + (TC_357_411.port_b.Q_flow + (TC_249_411.port_b.Q_flow + (CABI0CabiA001016003.port.Q_flow + (TC_411_412.port_a.Q_flow + TC_411_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001016003.port.T = TC_249_411.port_b.T; CABI0CabiA001016003.port.T = TC_357_411.port_b.T; CABI0CabiA001016003.port.T = TC_409_411.port_b.T; CABI0CabiA001016003.port.T = TC_411_0.port_a.T; CABI0CabiA001016003.port.T = TC_411_412.port_a.T; CABI0CabiA001016003.port.T = TsCABI0CabiA001016003.port.T; TsCABI0CabiA013015003.port.Q_flow + (TC_408_410.port_b.Q_flow + (TC_356_410.port_b.Q_flow + (TC_248_410.port_b.Q_flow + (CABI0CabiA013015003.port.Q_flow + (TC_410_423.port_a.Q_flow + (TC_410_1413.port_a.Q_flow + TC_410_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013015003.port.T = TC_248_410.port_b.T; CABI0CabiA013015003.port.T = TC_356_410.port_b.T; CABI0CabiA013015003.port.T = TC_408_410.port_b.T; CABI0CabiA013015003.port.T = TC_410_0.port_a.T; CABI0CabiA013015003.port.T = TC_410_1413.port_a.T; CABI0CabiA013015003.port.T = TC_410_423.port_a.T; CABI0CabiA013015003.port.T = TsCABI0CabiA013015003.port.T; TsCABI0CabiA001015003.port.Q_flow + (TC_407_409.port_b.Q_flow + (TC_355_409.port_b.Q_flow + (TC_247_409.port_b.Q_flow + (CABI0CabiA001015003.port.Q_flow + (TC_409_411.port_a.Q_flow + (TC_409_1403.port_a.Q_flow + TC_409_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001015003.port.T = TC_247_409.port_b.T; CABI0CabiA001015003.port.T = TC_355_409.port_b.T; CABI0CabiA001015003.port.T = TC_407_409.port_b.T; CABI0CabiA001015003.port.T = TC_409_0.port_a.T; CABI0CabiA001015003.port.T = TC_409_1403.port_a.T; CABI0CabiA001015003.port.T = TC_409_411.port_a.T; CABI0CabiA001015003.port.T = TsCABI0CabiA001015003.port.T; TsCABI0CabiA013014003.port.Q_flow + (TC_406_408.port_b.Q_flow + (TC_354_408.port_b.Q_flow + (TC_246_408.port_b.Q_flow + (CABI0CabiA013014003.port.Q_flow + (TC_408_410.port_a.Q_flow + (TC_408_1402.port_a.Q_flow + TC_408_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013014003.port.T = TC_246_408.port_b.T; CABI0CabiA013014003.port.T = TC_354_408.port_b.T; CABI0CabiA013014003.port.T = TC_406_408.port_b.T; CABI0CabiA013014003.port.T = TC_408_0.port_a.T; CABI0CabiA013014003.port.T = TC_408_1402.port_a.T; CABI0CabiA013014003.port.T = TC_408_410.port_a.T; CABI0CabiA013014003.port.T = TsCABI0CabiA013014003.port.T; TsCABI0CabiA001014003.port.Q_flow + (TC_405_407.port_b.Q_flow + (TC_353_407.port_b.Q_flow + (TC_245_407.port_b.Q_flow + (CABI0CabiA001014003.port.Q_flow + (TC_407_409.port_a.Q_flow + (TC_407_1392.port_a.Q_flow + TC_407_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001014003.port.T = TC_245_407.port_b.T; CABI0CabiA001014003.port.T = TC_353_407.port_b.T; CABI0CabiA001014003.port.T = TC_405_407.port_b.T; CABI0CabiA001014003.port.T = TC_407_0.port_a.T; CABI0CabiA001014003.port.T = TC_407_1392.port_a.T; CABI0CabiA001014003.port.T = TC_407_409.port_a.T; CABI0CabiA001014003.port.T = TsCABI0CabiA001014003.port.T; TsCABI0CabiA013013003.port.Q_flow + (TC_404_406.port_b.Q_flow + (TC_352_406.port_b.Q_flow + (TC_244_406.port_b.Q_flow + (CABI0CabiA013013003.port.Q_flow + (TC_406_408.port_a.Q_flow + (TC_406_1391.port_a.Q_flow + TC_406_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013013003.port.T = TC_244_406.port_b.T; CABI0CabiA013013003.port.T = TC_352_406.port_b.T; CABI0CabiA013013003.port.T = TC_404_406.port_b.T; CABI0CabiA013013003.port.T = TC_406_0.port_a.T; CABI0CabiA013013003.port.T = TC_406_1391.port_a.T; CABI0CabiA013013003.port.T = TC_406_408.port_a.T; CABI0CabiA013013003.port.T = TsCABI0CabiA013013003.port.T; TsCABI0CabiA001013003.port.Q_flow + (TC_403_405.port_b.Q_flow + (TC_351_405.port_b.Q_flow + (TC_243_405.port_b.Q_flow + (CABI0CabiA001013003.port.Q_flow + (TC_405_407.port_a.Q_flow + (TC_405_1381.port_a.Q_flow + TC_405_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001013003.port.T = TC_243_405.port_b.T; CABI0CabiA001013003.port.T = TC_351_405.port_b.T; CABI0CabiA001013003.port.T = TC_403_405.port_b.T; CABI0CabiA001013003.port.T = TC_405_0.port_a.T; CABI0CabiA001013003.port.T = TC_405_1381.port_a.T; CABI0CabiA001013003.port.T = TC_405_407.port_a.T; CABI0CabiA001013003.port.T = TsCABI0CabiA001013003.port.T; TsCABI0CabiA013012003.port.Q_flow + (TC_402_404.port_b.Q_flow + (TC_350_404.port_b.Q_flow + (TC_242_404.port_b.Q_flow + (CABI0CabiA013012003.port.Q_flow + (TC_404_406.port_a.Q_flow + (TC_404_1380.port_a.Q_flow + TC_404_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013012003.port.T = TC_242_404.port_b.T; CABI0CabiA013012003.port.T = TC_350_404.port_b.T; CABI0CabiA013012003.port.T = TC_402_404.port_b.T; CABI0CabiA013012003.port.T = TC_404_0.port_a.T; CABI0CabiA013012003.port.T = TC_404_1380.port_a.T; CABI0CabiA013012003.port.T = TC_404_406.port_a.T; CABI0CabiA013012003.port.T = TsCABI0CabiA013012003.port.T; TsCABI0CabiA001012003.port.Q_flow + (TC_401_403.port_b.Q_flow + (TC_349_403.port_b.Q_flow + (TC_241_403.port_b.Q_flow + (CABI0CabiA001012003.port.Q_flow + (TC_403_405.port_a.Q_flow + (TC_403_1370.port_a.Q_flow + TC_403_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001012003.port.T = TC_241_403.port_b.T; CABI0CabiA001012003.port.T = TC_349_403.port_b.T; CABI0CabiA001012003.port.T = TC_401_403.port_b.T; CABI0CabiA001012003.port.T = TC_403_0.port_a.T; CABI0CabiA001012003.port.T = TC_403_1370.port_a.T; CABI0CabiA001012003.port.T = TC_403_405.port_a.T; CABI0CabiA001012003.port.T = TsCABI0CabiA001012003.port.T; TsCABI0CabiA013011003.port.Q_flow + (TC_400_402.port_b.Q_flow + (TC_348_402.port_b.Q_flow + (TC_240_402.port_b.Q_flow + (CABI0CabiA013011003.port.Q_flow + (TC_402_404.port_a.Q_flow + (TC_402_1369.port_a.Q_flow + TC_402_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013011003.port.T = TC_240_402.port_b.T; CABI0CabiA013011003.port.T = TC_348_402.port_b.T; CABI0CabiA013011003.port.T = TC_400_402.port_b.T; CABI0CabiA013011003.port.T = TC_402_0.port_a.T; CABI0CabiA013011003.port.T = TC_402_1369.port_a.T; CABI0CabiA013011003.port.T = TC_402_404.port_a.T; CABI0CabiA013011003.port.T = TsCABI0CabiA013011003.port.T; TsCABI0CabiA001011003.port.Q_flow + (TC_399_401.port_b.Q_flow + (TC_347_401.port_b.Q_flow + (TC_239_401.port_b.Q_flow + (CABI0CabiA001011003.port.Q_flow + (TC_401_403.port_a.Q_flow + (TC_401_1359.port_a.Q_flow + TC_401_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001011003.port.T = TC_239_401.port_b.T; CABI0CabiA001011003.port.T = TC_347_401.port_b.T; CABI0CabiA001011003.port.T = TC_399_401.port_b.T; CABI0CabiA001011003.port.T = TC_401_0.port_a.T; CABI0CabiA001011003.port.T = TC_401_1359.port_a.T; CABI0CabiA001011003.port.T = TC_401_403.port_a.T; CABI0CabiA001011003.port.T = TsCABI0CabiA001011003.port.T; TsCABI0CabiA013010003.port.Q_flow + (TC_398_400.port_b.Q_flow + (TC_346_400.port_b.Q_flow + (TC_238_400.port_b.Q_flow + (CABI0CabiA013010003.port.Q_flow + (TC_400_402.port_a.Q_flow + (TC_400_1358.port_a.Q_flow + TC_400_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013010003.port.T = TC_238_400.port_b.T; CABI0CabiA013010003.port.T = TC_346_400.port_b.T; CABI0CabiA013010003.port.T = TC_398_400.port_b.T; CABI0CabiA013010003.port.T = TC_400_0.port_a.T; CABI0CabiA013010003.port.T = TC_400_1358.port_a.T; CABI0CabiA013010003.port.T = TC_400_402.port_a.T; CABI0CabiA013010003.port.T = TsCABI0CabiA013010003.port.T; TsCABI0CabiA001010003.port.Q_flow + (TC_397_399.port_b.Q_flow + (TC_345_399.port_b.Q_flow + (TC_237_399.port_b.Q_flow + (CABI0CabiA001010003.port.Q_flow + (TC_399_401.port_a.Q_flow + (TC_399_1351.port_a.Q_flow + TC_399_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001010003.port.T = TC_237_399.port_b.T; CABI0CabiA001010003.port.T = TC_345_399.port_b.T; CABI0CabiA001010003.port.T = TC_397_399.port_b.T; CABI0CabiA001010003.port.T = TC_399_0.port_a.T; CABI0CabiA001010003.port.T = TC_399_1351.port_a.T; CABI0CabiA001010003.port.T = TC_399_401.port_a.T; CABI0CabiA001010003.port.T = TsCABI0CabiA001010003.port.T; TsCABI0CabiA013009003.port.Q_flow + (TC_396_398.port_b.Q_flow + (TC_344_398.port_b.Q_flow + (TC_236_398.port_b.Q_flow + (CABI0CabiA013009003.port.Q_flow + (TC_398_400.port_a.Q_flow + (TC_398_1350.port_a.Q_flow + TC_398_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013009003.port.T = TC_236_398.port_b.T; CABI0CabiA013009003.port.T = TC_344_398.port_b.T; CABI0CabiA013009003.port.T = TC_396_398.port_b.T; CABI0CabiA013009003.port.T = TC_398_0.port_a.T; CABI0CabiA013009003.port.T = TC_398_1350.port_a.T; CABI0CabiA013009003.port.T = TC_398_400.port_a.T; CABI0CabiA013009003.port.T = TsCABI0CabiA013009003.port.T; TsCABI0CabiA001009003.port.Q_flow + (TC_395_397.port_b.Q_flow + (TC_343_397.port_b.Q_flow + (TC_235_397.port_b.Q_flow + (CABI0CabiA001009003.port.Q_flow + (TC_397_399.port_a.Q_flow + (TC_397_1343.port_a.Q_flow + TC_397_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001009003.port.T = TC_235_397.port_b.T; CABI0CabiA001009003.port.T = TC_343_397.port_b.T; CABI0CabiA001009003.port.T = TC_395_397.port_b.T; CABI0CabiA001009003.port.T = TC_397_0.port_a.T; CABI0CabiA001009003.port.T = TC_397_1343.port_a.T; CABI0CabiA001009003.port.T = TC_397_399.port_a.T; CABI0CabiA001009003.port.T = TsCABI0CabiA001009003.port.T; TsCABI0CabiA013008003.port.Q_flow + (TC_394_396.port_b.Q_flow + (TC_342_396.port_b.Q_flow + (TC_234_396.port_b.Q_flow + (CABI0CabiA013008003.port.Q_flow + (TC_396_398.port_a.Q_flow + (TC_396_1342.port_a.Q_flow + TC_396_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013008003.port.T = TC_234_396.port_b.T; CABI0CabiA013008003.port.T = TC_342_396.port_b.T; CABI0CabiA013008003.port.T = TC_394_396.port_b.T; CABI0CabiA013008003.port.T = TC_396_0.port_a.T; CABI0CabiA013008003.port.T = TC_396_1342.port_a.T; CABI0CabiA013008003.port.T = TC_396_398.port_a.T; CABI0CabiA013008003.port.T = TsCABI0CabiA013008003.port.T; TsCABI0CabiA001008003.port.Q_flow + (TC_393_395.port_b.Q_flow + (TC_341_395.port_b.Q_flow + (TC_233_395.port_b.Q_flow + (CABI0CabiA001008003.port.Q_flow + (TC_395_397.port_a.Q_flow + (TC_395_1335.port_a.Q_flow + TC_395_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001008003.port.T = TC_233_395.port_b.T; CABI0CabiA001008003.port.T = TC_341_395.port_b.T; CABI0CabiA001008003.port.T = TC_393_395.port_b.T; CABI0CabiA001008003.port.T = TC_395_0.port_a.T; CABI0CabiA001008003.port.T = TC_395_1335.port_a.T; CABI0CabiA001008003.port.T = TC_395_397.port_a.T; CABI0CabiA001008003.port.T = TsCABI0CabiA001008003.port.T; TsCABI0CabiA013007003.port.Q_flow + (TC_392_394.port_b.Q_flow + (TC_340_394.port_b.Q_flow + (TC_232_394.port_b.Q_flow + (CABI0CabiA013007003.port.Q_flow + (TC_394_396.port_a.Q_flow + (TC_394_1334.port_a.Q_flow + TC_394_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013007003.port.T = TC_232_394.port_b.T; CABI0CabiA013007003.port.T = TC_340_394.port_b.T; CABI0CabiA013007003.port.T = TC_392_394.port_b.T; CABI0CabiA013007003.port.T = TC_394_0.port_a.T; CABI0CabiA013007003.port.T = TC_394_1334.port_a.T; CABI0CabiA013007003.port.T = TC_394_396.port_a.T; CABI0CabiA013007003.port.T = TsCABI0CabiA013007003.port.T; TsCABI0CabiA001007003.port.Q_flow + (TC_391_393.port_b.Q_flow + (TC_339_393.port_b.Q_flow + (TC_231_393.port_b.Q_flow + (CABI0CabiA001007003.port.Q_flow + (TC_393_395.port_a.Q_flow + (TC_393_1324.port_a.Q_flow + TC_393_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001007003.port.T = TC_231_393.port_b.T; CABI0CabiA001007003.port.T = TC_339_393.port_b.T; CABI0CabiA001007003.port.T = TC_391_393.port_b.T; CABI0CabiA001007003.port.T = TC_393_0.port_a.T; CABI0CabiA001007003.port.T = TC_393_1324.port_a.T; CABI0CabiA001007003.port.T = TC_393_395.port_a.T; CABI0CabiA001007003.port.T = TsCABI0CabiA001007003.port.T; TsCABI0CabiA013006003.port.Q_flow + (TC_390_392.port_b.Q_flow + (TC_338_392.port_b.Q_flow + (TC_230_392.port_b.Q_flow + (CABI0CabiA013006003.port.Q_flow + (TC_392_394.port_a.Q_flow + (TC_392_1323.port_a.Q_flow + TC_392_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013006003.port.T = TC_230_392.port_b.T; CABI0CabiA013006003.port.T = TC_338_392.port_b.T; CABI0CabiA013006003.port.T = TC_390_392.port_b.T; CABI0CabiA013006003.port.T = TC_392_0.port_a.T; CABI0CabiA013006003.port.T = TC_392_1323.port_a.T; CABI0CabiA013006003.port.T = TC_392_394.port_a.T; CABI0CabiA013006003.port.T = TsCABI0CabiA013006003.port.T; TsCABI0CabiA001006003.port.Q_flow + (TC_389_391.port_b.Q_flow + (TC_337_391.port_b.Q_flow + (TC_229_391.port_b.Q_flow + (CABI0CabiA001006003.port.Q_flow + (TC_391_393.port_a.Q_flow + (TC_391_1313.port_a.Q_flow + TC_391_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001006003.port.T = TC_229_391.port_b.T; CABI0CabiA001006003.port.T = TC_337_391.port_b.T; CABI0CabiA001006003.port.T = TC_389_391.port_b.T; CABI0CabiA001006003.port.T = TC_391_0.port_a.T; CABI0CabiA001006003.port.T = TC_391_1313.port_a.T; CABI0CabiA001006003.port.T = TC_391_393.port_a.T; CABI0CabiA001006003.port.T = TsCABI0CabiA001006003.port.T; TsCABI0CabiA013005003.port.Q_flow + (TC_388_390.port_b.Q_flow + (TC_336_390.port_b.Q_flow + (TC_228_390.port_b.Q_flow + (CABI0CabiA013005003.port.Q_flow + (TC_390_392.port_a.Q_flow + (TC_390_1312.port_a.Q_flow + TC_390_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013005003.port.T = TC_228_390.port_b.T; CABI0CabiA013005003.port.T = TC_336_390.port_b.T; CABI0CabiA013005003.port.T = TC_388_390.port_b.T; CABI0CabiA013005003.port.T = TC_390_0.port_a.T; CABI0CabiA013005003.port.T = TC_390_1312.port_a.T; CABI0CabiA013005003.port.T = TC_390_392.port_a.T; CABI0CabiA013005003.port.T = TsCABI0CabiA013005003.port.T; TsCABI0CabiA001005003.port.Q_flow + (TC_387_389.port_b.Q_flow + (TC_335_389.port_b.Q_flow + (TC_227_389.port_b.Q_flow + (CABI0CabiA001005003.port.Q_flow + (TC_389_391.port_a.Q_flow + (TC_389_1302.port_a.Q_flow + TC_389_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001005003.port.T = TC_227_389.port_b.T; CABI0CabiA001005003.port.T = TC_335_389.port_b.T; CABI0CabiA001005003.port.T = TC_387_389.port_b.T; CABI0CabiA001005003.port.T = TC_389_0.port_a.T; CABI0CabiA001005003.port.T = TC_389_1302.port_a.T; CABI0CabiA001005003.port.T = TC_389_391.port_a.T; CABI0CabiA001005003.port.T = TsCABI0CabiA001005003.port.T; TsCABI0CabiA013004003.port.Q_flow + (TC_386_388.port_b.Q_flow + (TC_334_388.port_b.Q_flow + (TC_226_388.port_b.Q_flow + (CABI0CabiA013004003.port.Q_flow + (TC_388_390.port_a.Q_flow + (TC_388_1301.port_a.Q_flow + TC_388_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013004003.port.T = TC_226_388.port_b.T; CABI0CabiA013004003.port.T = TC_334_388.port_b.T; CABI0CabiA013004003.port.T = TC_386_388.port_b.T; CABI0CabiA013004003.port.T = TC_388_0.port_a.T; CABI0CabiA013004003.port.T = TC_388_1301.port_a.T; CABI0CabiA013004003.port.T = TC_388_390.port_a.T; CABI0CabiA013004003.port.T = TsCABI0CabiA013004003.port.T; TsCABI0CabiA001004003.port.Q_flow + (TC_385_387.port_b.Q_flow + (TC_333_387.port_b.Q_flow + (TC_225_387.port_b.Q_flow + (CABI0CabiA001004003.port.Q_flow + (TC_387_389.port_a.Q_flow + (TC_387_1291.port_a.Q_flow + TC_387_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001004003.port.T = TC_225_387.port_b.T; CABI0CabiA001004003.port.T = TC_333_387.port_b.T; CABI0CabiA001004003.port.T = TC_385_387.port_b.T; CABI0CabiA001004003.port.T = TC_387_0.port_a.T; CABI0CabiA001004003.port.T = TC_387_1291.port_a.T; CABI0CabiA001004003.port.T = TC_387_389.port_a.T; CABI0CabiA001004003.port.T = TsCABI0CabiA001004003.port.T; TsCABI0CabiA013003003.port.Q_flow + (TC_384_386.port_b.Q_flow + (TC_332_386.port_b.Q_flow + (TC_224_386.port_b.Q_flow + (CABI0CabiA013003003.port.Q_flow + (TC_386_388.port_a.Q_flow + (TC_386_1290.port_a.Q_flow + TC_386_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013003003.port.T = TC_224_386.port_b.T; CABI0CabiA013003003.port.T = TC_332_386.port_b.T; CABI0CabiA013003003.port.T = TC_384_386.port_b.T; CABI0CabiA013003003.port.T = TC_386_0.port_a.T; CABI0CabiA013003003.port.T = TC_386_1290.port_a.T; CABI0CabiA013003003.port.T = TC_386_388.port_a.T; CABI0CabiA013003003.port.T = TsCABI0CabiA013003003.port.T; TsCABI0CabiA001003003.port.Q_flow + (TC_383_385.port_b.Q_flow + (TC_331_385.port_b.Q_flow + (TC_223_385.port_b.Q_flow + (CABI0CabiA001003003.port.Q_flow + (TC_385_387.port_a.Q_flow + (TC_385_1280.port_a.Q_flow + TC_385_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001003003.port.T = TC_223_385.port_b.T; CABI0CabiA001003003.port.T = TC_331_385.port_b.T; CABI0CabiA001003003.port.T = TC_383_385.port_b.T; CABI0CabiA001003003.port.T = TC_385_0.port_a.T; CABI0CabiA001003003.port.T = TC_385_1280.port_a.T; CABI0CabiA001003003.port.T = TC_385_387.port_a.T; CABI0CabiA001003003.port.T = TsCABI0CabiA001003003.port.T; TsCABI0CabiA013002003.port.Q_flow + (TC_382_384.port_b.Q_flow + (TC_330_384.port_b.Q_flow + (TC_222_384.port_b.Q_flow + (CABI0CabiA013002003.port.Q_flow + (TC_384_386.port_a.Q_flow + (TC_384_1279.port_a.Q_flow + TC_384_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013002003.port.T = TC_222_384.port_b.T; CABI0CabiA013002003.port.T = TC_330_384.port_b.T; CABI0CabiA013002003.port.T = TC_382_384.port_b.T; CABI0CabiA013002003.port.T = TC_384_0.port_a.T; CABI0CabiA013002003.port.T = TC_384_1279.port_a.T; CABI0CabiA013002003.port.T = TC_384_386.port_a.T; CABI0CabiA013002003.port.T = TsCABI0CabiA013002003.port.T; TsCABI0CabiA001002003.port.Q_flow + (TC_370_383.port_b.Q_flow + (TC_329_383.port_b.Q_flow + (TC_221_383.port_b.Q_flow + (CABI0CabiA001002003.port.Q_flow + (TC_383_385.port_a.Q_flow + (TC_383_1269.port_a.Q_flow + TC_383_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001002003.port.T = TC_221_383.port_b.T; CABI0CabiA001002003.port.T = TC_329_383.port_b.T; CABI0CabiA001002003.port.T = TC_370_383.port_b.T; CABI0CabiA001002003.port.T = TC_383_0.port_a.T; CABI0CabiA001002003.port.T = TC_383_1269.port_a.T; CABI0CabiA001002003.port.T = TC_383_385.port_a.T; CABI0CabiA001002003.port.T = TsCABI0CabiA001002003.port.T; TsCABI0CabiA013001003.port.Q_flow + (TC_381_382.port_b.Q_flow + (TC_328_382.port_b.Q_flow + (TC_220_382.port_b.Q_flow + (CABI0CabiA013001003.port.Q_flow + (TC_382_384.port_a.Q_flow + TC_382_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013001003.port.T = TC_220_382.port_b.T; CABI0CabiA013001003.port.T = TC_328_382.port_b.T; CABI0CabiA013001003.port.T = TC_381_382.port_b.T; CABI0CabiA013001003.port.T = TC_382_0.port_a.T; CABI0CabiA013001003.port.T = TC_382_384.port_a.T; CABI0CabiA013001003.port.T = TsCABI0CabiA013001003.port.T; TsCABI0CabiA012001003.port.Q_flow + (TC_380_381.port_b.Q_flow + (TC_327_381.port_b.Q_flow + (TC_219_381.port_b.Q_flow + (CABI0CabiA012001003.port.Q_flow + (TC_381_382.port_a.Q_flow + (TC_381_1279.port_a.Q_flow + TC_381_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012001003.port.T = TC_219_381.port_b.T; CABI0CabiA012001003.port.T = TC_327_381.port_b.T; CABI0CabiA012001003.port.T = TC_380_381.port_b.T; CABI0CabiA012001003.port.T = TC_381_0.port_a.T; CABI0CabiA012001003.port.T = TC_381_1279.port_a.T; CABI0CabiA012001003.port.T = TC_381_382.port_a.T; CABI0CabiA012001003.port.T = TsCABI0CabiA012001003.port.T; TsCABI0CabiA011001003.port.Q_flow + (TC_379_380.port_b.Q_flow + (TC_326_380.port_b.Q_flow + (TC_218_380.port_b.Q_flow + (CABI0CabiA011001003.port.Q_flow + (TC_380_381.port_a.Q_flow + (TC_380_1278.port_a.Q_flow + TC_380_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011001003.port.T = TC_218_380.port_b.T; CABI0CabiA011001003.port.T = TC_326_380.port_b.T; CABI0CabiA011001003.port.T = TC_379_380.port_b.T; CABI0CabiA011001003.port.T = TC_380_0.port_a.T; CABI0CabiA011001003.port.T = TC_380_1278.port_a.T; CABI0CabiA011001003.port.T = TC_380_381.port_a.T; CABI0CabiA011001003.port.T = TsCABI0CabiA011001003.port.T; TsCABI0CabiA010001003.port.Q_flow + (TC_378_379.port_b.Q_flow + (TC_325_379.port_b.Q_flow + (TC_217_379.port_b.Q_flow + (CABI0CabiA010001003.port.Q_flow + (TC_379_380.port_a.Q_flow + (TC_379_1277.port_a.Q_flow + TC_379_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010001003.port.T = TC_217_379.port_b.T; CABI0CabiA010001003.port.T = TC_325_379.port_b.T; CABI0CabiA010001003.port.T = TC_378_379.port_b.T; CABI0CabiA010001003.port.T = TC_379_0.port_a.T; CABI0CabiA010001003.port.T = TC_379_1277.port_a.T; CABI0CabiA010001003.port.T = TC_379_380.port_a.T; CABI0CabiA010001003.port.T = TsCABI0CabiA010001003.port.T; TsCABI0CabiA009001003.port.Q_flow + (TC_377_378.port_b.Q_flow + (TC_324_378.port_b.Q_flow + (TC_216_378.port_b.Q_flow + (CABI0CabiA009001003.port.Q_flow + (TC_378_379.port_a.Q_flow + (TC_378_1276.port_a.Q_flow + TC_378_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009001003.port.T = TC_216_378.port_b.T; CABI0CabiA009001003.port.T = TC_324_378.port_b.T; CABI0CabiA009001003.port.T = TC_377_378.port_b.T; CABI0CabiA009001003.port.T = TC_378_0.port_a.T; CABI0CabiA009001003.port.T = TC_378_1276.port_a.T; CABI0CabiA009001003.port.T = TC_378_379.port_a.T; CABI0CabiA009001003.port.T = TsCABI0CabiA009001003.port.T; TsCABI0CabiA008001003.port.Q_flow + (TC_376_377.port_b.Q_flow + (TC_323_377.port_b.Q_flow + (TC_215_377.port_b.Q_flow + (CABI0CabiA008001003.port.Q_flow + (TC_377_378.port_a.Q_flow + (TC_377_1275.port_a.Q_flow + TC_377_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008001003.port.T = TC_215_377.port_b.T; CABI0CabiA008001003.port.T = TC_323_377.port_b.T; CABI0CabiA008001003.port.T = TC_376_377.port_b.T; CABI0CabiA008001003.port.T = TC_377_0.port_a.T; CABI0CabiA008001003.port.T = TC_377_1275.port_a.T; CABI0CabiA008001003.port.T = TC_377_378.port_a.T; CABI0CabiA008001003.port.T = TsCABI0CabiA008001003.port.T; TsCABI0CabiA007001003.port.Q_flow + (TC_375_376.port_b.Q_flow + (TC_322_376.port_b.Q_flow + (TC_214_376.port_b.Q_flow + (CABI0CabiA007001003.port.Q_flow + (TC_376_377.port_a.Q_flow + (TC_376_1274.port_a.Q_flow + TC_376_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007001003.port.T = TC_214_376.port_b.T; CABI0CabiA007001003.port.T = TC_322_376.port_b.T; CABI0CabiA007001003.port.T = TC_375_376.port_b.T; CABI0CabiA007001003.port.T = TC_376_0.port_a.T; CABI0CabiA007001003.port.T = TC_376_1274.port_a.T; CABI0CabiA007001003.port.T = TC_376_377.port_a.T; CABI0CabiA007001003.port.T = TsCABI0CabiA007001003.port.T; TsCABI0CabiA006001003.port.Q_flow + (TC_374_375.port_b.Q_flow + (TC_321_375.port_b.Q_flow + (TC_213_375.port_b.Q_flow + (CABI0CabiA006001003.port.Q_flow + (TC_375_376.port_a.Q_flow + (TC_375_1273.port_a.Q_flow + TC_375_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006001003.port.T = TC_213_375.port_b.T; CABI0CabiA006001003.port.T = TC_321_375.port_b.T; CABI0CabiA006001003.port.T = TC_374_375.port_b.T; CABI0CabiA006001003.port.T = TC_375_0.port_a.T; CABI0CabiA006001003.port.T = TC_375_1273.port_a.T; CABI0CabiA006001003.port.T = TC_375_376.port_a.T; CABI0CabiA006001003.port.T = TsCABI0CabiA006001003.port.T; TsCABI0CabiA005001003.port.Q_flow + (TC_373_374.port_b.Q_flow + (TC_320_374.port_b.Q_flow + (TC_212_374.port_b.Q_flow + (CABI0CabiA005001003.port.Q_flow + (TC_374_375.port_a.Q_flow + (TC_374_1272.port_a.Q_flow + TC_374_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005001003.port.T = TC_212_374.port_b.T; CABI0CabiA005001003.port.T = TC_320_374.port_b.T; CABI0CabiA005001003.port.T = TC_373_374.port_b.T; CABI0CabiA005001003.port.T = TC_374_0.port_a.T; CABI0CabiA005001003.port.T = TC_374_1272.port_a.T; CABI0CabiA005001003.port.T = TC_374_375.port_a.T; CABI0CabiA005001003.port.T = TsCABI0CabiA005001003.port.T; TsCABI0CabiA004001003.port.Q_flow + (TC_372_373.port_b.Q_flow + (TC_319_373.port_b.Q_flow + (TC_211_373.port_b.Q_flow + (CABI0CabiA004001003.port.Q_flow + (TC_373_374.port_a.Q_flow + (TC_373_1271.port_a.Q_flow + TC_373_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004001003.port.T = TC_211_373.port_b.T; CABI0CabiA004001003.port.T = TC_319_373.port_b.T; CABI0CabiA004001003.port.T = TC_372_373.port_b.T; CABI0CabiA004001003.port.T = TC_373_0.port_a.T; CABI0CabiA004001003.port.T = TC_373_1271.port_a.T; CABI0CabiA004001003.port.T = TC_373_374.port_a.T; CABI0CabiA004001003.port.T = TsCABI0CabiA004001003.port.T; TsCABI0CabiA003001003.port.Q_flow + (TC_371_372.port_b.Q_flow + (TC_318_372.port_b.Q_flow + (TC_210_372.port_b.Q_flow + (CABI0CabiA003001003.port.Q_flow + (TC_372_373.port_a.Q_flow + (TC_372_1270.port_a.Q_flow + TC_372_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003001003.port.T = TC_210_372.port_b.T; CABI0CabiA003001003.port.T = TC_318_372.port_b.T; CABI0CabiA003001003.port.T = TC_371_372.port_b.T; CABI0CabiA003001003.port.T = TC_372_0.port_a.T; CABI0CabiA003001003.port.T = TC_372_1270.port_a.T; CABI0CabiA003001003.port.T = TC_372_373.port_a.T; CABI0CabiA003001003.port.T = TsCABI0CabiA003001003.port.T; TsCABI0CabiA002001003.port.Q_flow + (TC_370_371.port_b.Q_flow + (TC_317_371.port_b.Q_flow + (TC_209_371.port_b.Q_flow + (CABI0CabiA002001003.port.Q_flow + (TC_371_372.port_a.Q_flow + (TC_371_1269.port_a.Q_flow + TC_371_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002001003.port.T = TC_209_371.port_b.T; CABI0CabiA002001003.port.T = TC_317_371.port_b.T; CABI0CabiA002001003.port.T = TC_370_371.port_b.T; CABI0CabiA002001003.port.T = TC_371_0.port_a.T; CABI0CabiA002001003.port.T = TC_371_1269.port_a.T; CABI0CabiA002001003.port.T = TC_371_372.port_a.T; CABI0CabiA002001003.port.T = TsCABI0CabiA002001003.port.T; TsCABI0CabiA001001003.port.Q_flow + (TC_316_370.port_b.Q_flow + (CABI0CabiA001001003.port.Q_flow + (TC_370_371.port_a.Q_flow + (TC_370_383.port_a.Q_flow + (TC_370_424.port_a.Q_flow + TC_370_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001001003.port.T = TC_316_370.port_b.T; CABI0CabiA001001003.port.T = TC_370_0.port_a.T; CABI0CabiA001001003.port.T = TC_370_371.port_a.T; CABI0CabiA001001003.port.T = TC_370_383.port_a.T; CABI0CabiA001001003.port.T = TC_370_424.port_a.T; CABI0CabiA001001003.port.T = TsCABI0CabiA001001003.port.T; TsCABI0CabiA013016004.port.Q_flow + (TC_368_369.port_b.Q_flow + (TC_356_369.port_b.Q_flow + (TC_315_369.port_b.Q_flow + (CABI0CabiA013016004.port.Q_flow + (TC_369_423.port_a.Q_flow + TC_369_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013016004.port.T = TC_315_369.port_b.T; CABI0CabiA013016004.port.T = TC_356_369.port_b.T; CABI0CabiA013016004.port.T = TC_368_369.port_b.T; CABI0CabiA013016004.port.T = TC_369_0.port_a.T; CABI0CabiA013016004.port.T = TC_369_423.port_a.T; CABI0CabiA013016004.port.T = TsCABI0CabiA013016004.port.T; TsCABI0CabiA012016004.port.Q_flow + (TC_367_368.port_b.Q_flow + (TC_314_368.port_b.Q_flow + (CABI0CabiA012016004.port.Q_flow + (TC_368_369.port_a.Q_flow + (TC_368_422.port_a.Q_flow + (TC_368_1268.port_a.Q_flow + TC_368_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012016004.port.T = TC_314_368.port_b.T; CABI0CabiA012016004.port.T = TC_367_368.port_b.T; CABI0CabiA012016004.port.T = TC_368_0.port_a.T; CABI0CabiA012016004.port.T = TC_368_1268.port_a.T; CABI0CabiA012016004.port.T = TC_368_369.port_a.T; CABI0CabiA012016004.port.T = TC_368_422.port_a.T; CABI0CabiA012016004.port.T = TsCABI0CabiA012016004.port.T; TsCABI0CabiA011016004.port.Q_flow + (TC_366_367.port_b.Q_flow + (TC_313_367.port_b.Q_flow + (CABI0CabiA011016004.port.Q_flow + (TC_367_368.port_a.Q_flow + (TC_367_421.port_a.Q_flow + (TC_367_1267.port_a.Q_flow + TC_367_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011016004.port.T = TC_313_367.port_b.T; CABI0CabiA011016004.port.T = TC_366_367.port_b.T; CABI0CabiA011016004.port.T = TC_367_0.port_a.T; CABI0CabiA011016004.port.T = TC_367_1267.port_a.T; CABI0CabiA011016004.port.T = TC_367_368.port_a.T; CABI0CabiA011016004.port.T = TC_367_421.port_a.T; CABI0CabiA011016004.port.T = TsCABI0CabiA011016004.port.T; TsCABI0CabiA010016004.port.Q_flow + (TC_365_366.port_b.Q_flow + (TC_312_366.port_b.Q_flow + (CABI0CabiA010016004.port.Q_flow + (TC_366_367.port_a.Q_flow + (TC_366_420.port_a.Q_flow + (TC_366_1266.port_a.Q_flow + TC_366_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010016004.port.T = TC_312_366.port_b.T; CABI0CabiA010016004.port.T = TC_365_366.port_b.T; CABI0CabiA010016004.port.T = TC_366_0.port_a.T; CABI0CabiA010016004.port.T = TC_366_1266.port_a.T; CABI0CabiA010016004.port.T = TC_366_367.port_a.T; CABI0CabiA010016004.port.T = TC_366_420.port_a.T; CABI0CabiA010016004.port.T = TsCABI0CabiA010016004.port.T; TsCABI0CabiA009016004.port.Q_flow + (TC_364_365.port_b.Q_flow + (TC_311_365.port_b.Q_flow + (CABI0CabiA009016004.port.Q_flow + (TC_365_366.port_a.Q_flow + (TC_365_419.port_a.Q_flow + (TC_365_1265.port_a.Q_flow + TC_365_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009016004.port.T = TC_311_365.port_b.T; CABI0CabiA009016004.port.T = TC_364_365.port_b.T; CABI0CabiA009016004.port.T = TC_365_0.port_a.T; CABI0CabiA009016004.port.T = TC_365_1265.port_a.T; CABI0CabiA009016004.port.T = TC_365_366.port_a.T; CABI0CabiA009016004.port.T = TC_365_419.port_a.T; CABI0CabiA009016004.port.T = TsCABI0CabiA009016004.port.T; TsCABI0CabiA008016004.port.Q_flow + (TC_363_364.port_b.Q_flow + (TC_310_364.port_b.Q_flow + (CABI0CabiA008016004.port.Q_flow + (TC_364_365.port_a.Q_flow + (TC_364_418.port_a.Q_flow + (TC_364_1264.port_a.Q_flow + TC_364_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008016004.port.T = TC_310_364.port_b.T; CABI0CabiA008016004.port.T = TC_363_364.port_b.T; CABI0CabiA008016004.port.T = TC_364_0.port_a.T; CABI0CabiA008016004.port.T = TC_364_1264.port_a.T; CABI0CabiA008016004.port.T = TC_364_365.port_a.T; CABI0CabiA008016004.port.T = TC_364_418.port_a.T; CABI0CabiA008016004.port.T = TsCABI0CabiA008016004.port.T; TsCABI0CabiA007016004.port.Q_flow + (TC_362_363.port_b.Q_flow + (TC_309_363.port_b.Q_flow + (CABI0CabiA007016004.port.Q_flow + (TC_363_364.port_a.Q_flow + (TC_363_417.port_a.Q_flow + (TC_363_1263.port_a.Q_flow + TC_363_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007016004.port.T = TC_309_363.port_b.T; CABI0CabiA007016004.port.T = TC_362_363.port_b.T; CABI0CabiA007016004.port.T = TC_363_0.port_a.T; CABI0CabiA007016004.port.T = TC_363_1263.port_a.T; CABI0CabiA007016004.port.T = TC_363_364.port_a.T; CABI0CabiA007016004.port.T = TC_363_417.port_a.T; CABI0CabiA007016004.port.T = TsCABI0CabiA007016004.port.T; TsCABI0CabiA006016004.port.Q_flow + (TC_361_362.port_b.Q_flow + (TC_308_362.port_b.Q_flow + (CABI0CabiA006016004.port.Q_flow + (TC_362_363.port_a.Q_flow + (TC_362_416.port_a.Q_flow + (TC_362_1262.port_a.Q_flow + TC_362_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006016004.port.T = TC_308_362.port_b.T; CABI0CabiA006016004.port.T = TC_361_362.port_b.T; CABI0CabiA006016004.port.T = TC_362_0.port_a.T; CABI0CabiA006016004.port.T = TC_362_1262.port_a.T; CABI0CabiA006016004.port.T = TC_362_363.port_a.T; CABI0CabiA006016004.port.T = TC_362_416.port_a.T; CABI0CabiA006016004.port.T = TsCABI0CabiA006016004.port.T; TsCABI0CabiA005016004.port.Q_flow + (TC_360_361.port_b.Q_flow + (TC_307_361.port_b.Q_flow + (CABI0CabiA005016004.port.Q_flow + (TC_361_362.port_a.Q_flow + (TC_361_415.port_a.Q_flow + (TC_361_1261.port_a.Q_flow + TC_361_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005016004.port.T = TC_307_361.port_b.T; CABI0CabiA005016004.port.T = TC_360_361.port_b.T; CABI0CabiA005016004.port.T = TC_361_0.port_a.T; CABI0CabiA005016004.port.T = TC_361_1261.port_a.T; CABI0CabiA005016004.port.T = TC_361_362.port_a.T; CABI0CabiA005016004.port.T = TC_361_415.port_a.T; CABI0CabiA005016004.port.T = TsCABI0CabiA005016004.port.T; TsCABI0CabiA004016004.port.Q_flow + (TC_359_360.port_b.Q_flow + (TC_306_360.port_b.Q_flow + (CABI0CabiA004016004.port.Q_flow + (TC_360_361.port_a.Q_flow + (TC_360_414.port_a.Q_flow + (TC_360_1260.port_a.Q_flow + TC_360_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004016004.port.T = TC_306_360.port_b.T; CABI0CabiA004016004.port.T = TC_359_360.port_b.T; CABI0CabiA004016004.port.T = TC_360_0.port_a.T; CABI0CabiA004016004.port.T = TC_360_1260.port_a.T; CABI0CabiA004016004.port.T = TC_360_361.port_a.T; CABI0CabiA004016004.port.T = TC_360_414.port_a.T; CABI0CabiA004016004.port.T = TsCABI0CabiA004016004.port.T; TsCABI0CabiA003016004.port.Q_flow + (TC_358_359.port_b.Q_flow + (TC_305_359.port_b.Q_flow + (CABI0CabiA003016004.port.Q_flow + (TC_359_360.port_a.Q_flow + (TC_359_413.port_a.Q_flow + (TC_359_1259.port_a.Q_flow + TC_359_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003016004.port.T = TC_305_359.port_b.T; CABI0CabiA003016004.port.T = TC_358_359.port_b.T; CABI0CabiA003016004.port.T = TC_359_0.port_a.T; CABI0CabiA003016004.port.T = TC_359_1259.port_a.T; CABI0CabiA003016004.port.T = TC_359_360.port_a.T; CABI0CabiA003016004.port.T = TC_359_413.port_a.T; CABI0CabiA003016004.port.T = TsCABI0CabiA003016004.port.T; TsCABI0CabiA002016004.port.Q_flow + (TC_357_358.port_b.Q_flow + (TC_304_358.port_b.Q_flow + (CABI0CabiA002016004.port.Q_flow + (TC_358_359.port_a.Q_flow + (TC_358_412.port_a.Q_flow + (TC_358_1258.port_a.Q_flow + TC_358_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002016004.port.T = TC_304_358.port_b.T; CABI0CabiA002016004.port.T = TC_357_358.port_b.T; CABI0CabiA002016004.port.T = TC_358_0.port_a.T; CABI0CabiA002016004.port.T = TC_358_1258.port_a.T; CABI0CabiA002016004.port.T = TC_358_359.port_a.T; CABI0CabiA002016004.port.T = TC_358_412.port_a.T; CABI0CabiA002016004.port.T = TsCABI0CabiA002016004.port.T; TsCABI0CabiA001016004.port.Q_flow + (TC_355_357.port_b.Q_flow + (TC_303_357.port_b.Q_flow + (CABI0CabiA001016004.port.Q_flow + (TC_357_358.port_a.Q_flow + (TC_357_411.port_a.Q_flow + TC_357_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001016004.port.T = TC_303_357.port_b.T; CABI0CabiA001016004.port.T = TC_355_357.port_b.T; CABI0CabiA001016004.port.T = TC_357_0.port_a.T; CABI0CabiA001016004.port.T = TC_357_358.port_a.T; CABI0CabiA001016004.port.T = TC_357_411.port_a.T; CABI0CabiA001016004.port.T = TsCABI0CabiA001016004.port.T; TsCABI0CabiA013015004.port.Q_flow + (TC_354_356.port_b.Q_flow + (TC_302_356.port_b.Q_flow + (CABI0CabiA013015004.port.Q_flow + (TC_356_369.port_a.Q_flow + (TC_356_410.port_a.Q_flow + (TC_356_1268.port_a.Q_flow + TC_356_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013015004.port.T = TC_302_356.port_b.T; CABI0CabiA013015004.port.T = TC_354_356.port_b.T; CABI0CabiA013015004.port.T = TC_356_0.port_a.T; CABI0CabiA013015004.port.T = TC_356_1268.port_a.T; CABI0CabiA013015004.port.T = TC_356_369.port_a.T; CABI0CabiA013015004.port.T = TC_356_410.port_a.T; CABI0CabiA013015004.port.T = TsCABI0CabiA013015004.port.T; TsCABI0CabiA001015004.port.Q_flow + (TC_353_355.port_b.Q_flow + (TC_301_355.port_b.Q_flow + (CABI0CabiA001015004.port.Q_flow + (TC_355_357.port_a.Q_flow + (TC_355_409.port_a.Q_flow + (TC_355_1258.port_a.Q_flow + TC_355_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001015004.port.T = TC_301_355.port_b.T; CABI0CabiA001015004.port.T = TC_353_355.port_b.T; CABI0CabiA001015004.port.T = TC_355_0.port_a.T; CABI0CabiA001015004.port.T = TC_355_1258.port_a.T; CABI0CabiA001015004.port.T = TC_355_357.port_a.T; CABI0CabiA001015004.port.T = TC_355_409.port_a.T; CABI0CabiA001015004.port.T = TsCABI0CabiA001015004.port.T; TsCABI0CabiA013014004.port.Q_flow + (TC_352_354.port_b.Q_flow + (TC_300_354.port_b.Q_flow + (CABI0CabiA013014004.port.Q_flow + (TC_354_356.port_a.Q_flow + (TC_354_408.port_a.Q_flow + (TC_354_1257.port_a.Q_flow + TC_354_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013014004.port.T = TC_300_354.port_b.T; CABI0CabiA013014004.port.T = TC_352_354.port_b.T; CABI0CabiA013014004.port.T = TC_354_0.port_a.T; CABI0CabiA013014004.port.T = TC_354_1257.port_a.T; CABI0CabiA013014004.port.T = TC_354_356.port_a.T; CABI0CabiA013014004.port.T = TC_354_408.port_a.T; CABI0CabiA013014004.port.T = TsCABI0CabiA013014004.port.T; TsCABI0CabiA001014004.port.Q_flow + (TC_351_353.port_b.Q_flow + (TC_299_353.port_b.Q_flow + (CABI0CabiA001014004.port.Q_flow + (TC_353_355.port_a.Q_flow + (TC_353_407.port_a.Q_flow + (TC_353_1247.port_a.Q_flow + TC_353_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001014004.port.T = TC_299_353.port_b.T; CABI0CabiA001014004.port.T = TC_351_353.port_b.T; CABI0CabiA001014004.port.T = TC_353_0.port_a.T; CABI0CabiA001014004.port.T = TC_353_1247.port_a.T; CABI0CabiA001014004.port.T = TC_353_355.port_a.T; CABI0CabiA001014004.port.T = TC_353_407.port_a.T; CABI0CabiA001014004.port.T = TsCABI0CabiA001014004.port.T; TsCABI0CabiA013013004.port.Q_flow + (TC_350_352.port_b.Q_flow + (TC_298_352.port_b.Q_flow + (CABI0CabiA013013004.port.Q_flow + (TC_352_354.port_a.Q_flow + (TC_352_406.port_a.Q_flow + (TC_352_1246.port_a.Q_flow + TC_352_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013013004.port.T = TC_298_352.port_b.T; CABI0CabiA013013004.port.T = TC_350_352.port_b.T; CABI0CabiA013013004.port.T = TC_352_0.port_a.T; CABI0CabiA013013004.port.T = TC_352_1246.port_a.T; CABI0CabiA013013004.port.T = TC_352_354.port_a.T; CABI0CabiA013013004.port.T = TC_352_406.port_a.T; CABI0CabiA013013004.port.T = TsCABI0CabiA013013004.port.T; TsCABI0CabiA001013004.port.Q_flow + (TC_349_351.port_b.Q_flow + (TC_297_351.port_b.Q_flow + (CABI0CabiA001013004.port.Q_flow + (TC_351_353.port_a.Q_flow + (TC_351_405.port_a.Q_flow + (TC_351_1239.port_a.Q_flow + TC_351_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001013004.port.T = TC_297_351.port_b.T; CABI0CabiA001013004.port.T = TC_349_351.port_b.T; CABI0CabiA001013004.port.T = TC_351_0.port_a.T; CABI0CabiA001013004.port.T = TC_351_1239.port_a.T; CABI0CabiA001013004.port.T = TC_351_353.port_a.T; CABI0CabiA001013004.port.T = TC_351_405.port_a.T; CABI0CabiA001013004.port.T = TsCABI0CabiA001013004.port.T; TsCABI0CabiA013012004.port.Q_flow + (TC_348_350.port_b.Q_flow + (TC_296_350.port_b.Q_flow + (CABI0CabiA013012004.port.Q_flow + (TC_350_352.port_a.Q_flow + (TC_350_404.port_a.Q_flow + (TC_350_1238.port_a.Q_flow + TC_350_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013012004.port.T = TC_296_350.port_b.T; CABI0CabiA013012004.port.T = TC_348_350.port_b.T; CABI0CabiA013012004.port.T = TC_350_0.port_a.T; CABI0CabiA013012004.port.T = TC_350_1238.port_a.T; CABI0CabiA013012004.port.T = TC_350_352.port_a.T; CABI0CabiA013012004.port.T = TC_350_404.port_a.T; CABI0CabiA013012004.port.T = TsCABI0CabiA013012004.port.T; TsCABI0CabiA001012004.port.Q_flow + (TC_347_349.port_b.Q_flow + (TC_295_349.port_b.Q_flow + (CABI0CabiA001012004.port.Q_flow + (TC_349_351.port_a.Q_flow + (TC_349_403.port_a.Q_flow + (TC_349_1231.port_a.Q_flow + TC_349_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001012004.port.T = TC_295_349.port_b.T; CABI0CabiA001012004.port.T = TC_347_349.port_b.T; CABI0CabiA001012004.port.T = TC_349_0.port_a.T; CABI0CabiA001012004.port.T = TC_349_1231.port_a.T; CABI0CabiA001012004.port.T = TC_349_351.port_a.T; CABI0CabiA001012004.port.T = TC_349_403.port_a.T; CABI0CabiA001012004.port.T = TsCABI0CabiA001012004.port.T; TsCABI0CabiA013011004.port.Q_flow + (TC_346_348.port_b.Q_flow + (TC_294_348.port_b.Q_flow + (CABI0CabiA013011004.port.Q_flow + (TC_348_350.port_a.Q_flow + (TC_348_402.port_a.Q_flow + (TC_348_1230.port_a.Q_flow + TC_348_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013011004.port.T = TC_294_348.port_b.T; CABI0CabiA013011004.port.T = TC_346_348.port_b.T; CABI0CabiA013011004.port.T = TC_348_0.port_a.T; CABI0CabiA013011004.port.T = TC_348_1230.port_a.T; CABI0CabiA013011004.port.T = TC_348_350.port_a.T; CABI0CabiA013011004.port.T = TC_348_402.port_a.T; CABI0CabiA013011004.port.T = TsCABI0CabiA013011004.port.T; TsCABI0CabiA001011004.port.Q_flow + (TC_345_347.port_b.Q_flow + (TC_293_347.port_b.Q_flow + (CABI0CabiA001011004.port.Q_flow + (TC_347_349.port_a.Q_flow + (TC_347_401.port_a.Q_flow + (TC_347_1223.port_a.Q_flow + TC_347_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001011004.port.T = TC_293_347.port_b.T; CABI0CabiA001011004.port.T = TC_345_347.port_b.T; CABI0CabiA001011004.port.T = TC_347_0.port_a.T; CABI0CabiA001011004.port.T = TC_347_1223.port_a.T; CABI0CabiA001011004.port.T = TC_347_349.port_a.T; CABI0CabiA001011004.port.T = TC_347_401.port_a.T; CABI0CabiA001011004.port.T = TsCABI0CabiA001011004.port.T; TsCABI0CabiA013010004.port.Q_flow + (TC_344_346.port_b.Q_flow + (TC_292_346.port_b.Q_flow + (CABI0CabiA013010004.port.Q_flow + (TC_346_348.port_a.Q_flow + (TC_346_400.port_a.Q_flow + (TC_346_1222.port_a.Q_flow + TC_346_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013010004.port.T = TC_292_346.port_b.T; CABI0CabiA013010004.port.T = TC_344_346.port_b.T; CABI0CabiA013010004.port.T = TC_346_0.port_a.T; CABI0CabiA013010004.port.T = TC_346_1222.port_a.T; CABI0CabiA013010004.port.T = TC_346_348.port_a.T; CABI0CabiA013010004.port.T = TC_346_400.port_a.T; CABI0CabiA013010004.port.T = TsCABI0CabiA013010004.port.T; TsCABI0CabiA001010004.port.Q_flow + (TC_343_345.port_b.Q_flow + (TC_291_345.port_b.Q_flow + (CABI0CabiA001010004.port.Q_flow + (TC_345_347.port_a.Q_flow + (TC_345_399.port_a.Q_flow + (TC_345_1215.port_a.Q_flow + TC_345_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001010004.port.T = TC_291_345.port_b.T; CABI0CabiA001010004.port.T = TC_343_345.port_b.T; CABI0CabiA001010004.port.T = TC_345_0.port_a.T; CABI0CabiA001010004.port.T = TC_345_1215.port_a.T; CABI0CabiA001010004.port.T = TC_345_347.port_a.T; CABI0CabiA001010004.port.T = TC_345_399.port_a.T; CABI0CabiA001010004.port.T = TsCABI0CabiA001010004.port.T; TsCABI0CabiA013009004.port.Q_flow + (TC_342_344.port_b.Q_flow + (TC_290_344.port_b.Q_flow + (CABI0CabiA013009004.port.Q_flow + (TC_344_346.port_a.Q_flow + (TC_344_398.port_a.Q_flow + (TC_344_1214.port_a.Q_flow + TC_344_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013009004.port.T = TC_290_344.port_b.T; CABI0CabiA013009004.port.T = TC_342_344.port_b.T; CABI0CabiA013009004.port.T = TC_344_0.port_a.T; CABI0CabiA013009004.port.T = TC_344_1214.port_a.T; CABI0CabiA013009004.port.T = TC_344_346.port_a.T; CABI0CabiA013009004.port.T = TC_344_398.port_a.T; CABI0CabiA013009004.port.T = TsCABI0CabiA013009004.port.T; TsCABI0CabiA001009004.port.Q_flow + (TC_341_343.port_b.Q_flow + (TC_289_343.port_b.Q_flow + (CABI0CabiA001009004.port.Q_flow + (TC_343_345.port_a.Q_flow + (TC_343_397.port_a.Q_flow + (TC_343_1207.port_a.Q_flow + TC_343_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001009004.port.T = TC_289_343.port_b.T; CABI0CabiA001009004.port.T = TC_341_343.port_b.T; CABI0CabiA001009004.port.T = TC_343_0.port_a.T; CABI0CabiA001009004.port.T = TC_343_1207.port_a.T; CABI0CabiA001009004.port.T = TC_343_345.port_a.T; CABI0CabiA001009004.port.T = TC_343_397.port_a.T; CABI0CabiA001009004.port.T = TsCABI0CabiA001009004.port.T; TsCABI0CabiA013008004.port.Q_flow + (TC_340_342.port_b.Q_flow + (TC_288_342.port_b.Q_flow + (CABI0CabiA013008004.port.Q_flow + (TC_342_344.port_a.Q_flow + (TC_342_396.port_a.Q_flow + (TC_342_1206.port_a.Q_flow + TC_342_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013008004.port.T = TC_288_342.port_b.T; CABI0CabiA013008004.port.T = TC_340_342.port_b.T; CABI0CabiA013008004.port.T = TC_342_0.port_a.T; CABI0CabiA013008004.port.T = TC_342_1206.port_a.T; CABI0CabiA013008004.port.T = TC_342_344.port_a.T; CABI0CabiA013008004.port.T = TC_342_396.port_a.T; CABI0CabiA013008004.port.T = TsCABI0CabiA013008004.port.T; TsCABI0CabiA001008004.port.Q_flow + (TC_339_341.port_b.Q_flow + (TC_287_341.port_b.Q_flow + (CABI0CabiA001008004.port.Q_flow + (TC_341_343.port_a.Q_flow + (TC_341_395.port_a.Q_flow + (TC_341_1199.port_a.Q_flow + TC_341_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001008004.port.T = TC_287_341.port_b.T; CABI0CabiA001008004.port.T = TC_339_341.port_b.T; CABI0CabiA001008004.port.T = TC_341_0.port_a.T; CABI0CabiA001008004.port.T = TC_341_1199.port_a.T; CABI0CabiA001008004.port.T = TC_341_343.port_a.T; CABI0CabiA001008004.port.T = TC_341_395.port_a.T; CABI0CabiA001008004.port.T = TsCABI0CabiA001008004.port.T; TsCABI0CabiA013007004.port.Q_flow + (TC_338_340.port_b.Q_flow + (TC_286_340.port_b.Q_flow + (CABI0CabiA013007004.port.Q_flow + (TC_340_342.port_a.Q_flow + (TC_340_394.port_a.Q_flow + (TC_340_1198.port_a.Q_flow + TC_340_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013007004.port.T = TC_286_340.port_b.T; CABI0CabiA013007004.port.T = TC_338_340.port_b.T; CABI0CabiA013007004.port.T = TC_340_0.port_a.T; CABI0CabiA013007004.port.T = TC_340_1198.port_a.T; CABI0CabiA013007004.port.T = TC_340_342.port_a.T; CABI0CabiA013007004.port.T = TC_340_394.port_a.T; CABI0CabiA013007004.port.T = TsCABI0CabiA013007004.port.T; TsCABI0CabiA001007004.port.Q_flow + (TC_337_339.port_b.Q_flow + (TC_285_339.port_b.Q_flow + (CABI0CabiA001007004.port.Q_flow + (TC_339_341.port_a.Q_flow + (TC_339_393.port_a.Q_flow + (TC_339_1188.port_a.Q_flow + TC_339_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001007004.port.T = TC_285_339.port_b.T; CABI0CabiA001007004.port.T = TC_337_339.port_b.T; CABI0CabiA001007004.port.T = TC_339_0.port_a.T; CABI0CabiA001007004.port.T = TC_339_1188.port_a.T; CABI0CabiA001007004.port.T = TC_339_341.port_a.T; CABI0CabiA001007004.port.T = TC_339_393.port_a.T; CABI0CabiA001007004.port.T = TsCABI0CabiA001007004.port.T; TsCABI0CabiA013006004.port.Q_flow + (TC_336_338.port_b.Q_flow + (TC_284_338.port_b.Q_flow + (CABI0CabiA013006004.port.Q_flow + (TC_338_340.port_a.Q_flow + (TC_338_392.port_a.Q_flow + (TC_338_1187.port_a.Q_flow + TC_338_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013006004.port.T = TC_284_338.port_b.T; CABI0CabiA013006004.port.T = TC_336_338.port_b.T; CABI0CabiA013006004.port.T = TC_338_0.port_a.T; CABI0CabiA013006004.port.T = TC_338_1187.port_a.T; CABI0CabiA013006004.port.T = TC_338_340.port_a.T; CABI0CabiA013006004.port.T = TC_338_392.port_a.T; CABI0CabiA013006004.port.T = TsCABI0CabiA013006004.port.T; TsCABI0CabiA001006004.port.Q_flow + (TC_335_337.port_b.Q_flow + (TC_283_337.port_b.Q_flow + (CABI0CabiA001006004.port.Q_flow + (TC_337_339.port_a.Q_flow + (TC_337_391.port_a.Q_flow + (TC_337_1181.port_a.Q_flow + TC_337_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001006004.port.T = TC_283_337.port_b.T; CABI0CabiA001006004.port.T = TC_335_337.port_b.T; CABI0CabiA001006004.port.T = TC_337_0.port_a.T; CABI0CabiA001006004.port.T = TC_337_1181.port_a.T; CABI0CabiA001006004.port.T = TC_337_339.port_a.T; CABI0CabiA001006004.port.T = TC_337_391.port_a.T; CABI0CabiA001006004.port.T = TsCABI0CabiA001006004.port.T; TsCABI0CabiA013005004.port.Q_flow + (TC_334_336.port_b.Q_flow + (TC_282_336.port_b.Q_flow + (CABI0CabiA013005004.port.Q_flow + (TC_336_338.port_a.Q_flow + (TC_336_390.port_a.Q_flow + (TC_336_1180.port_a.Q_flow + TC_336_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013005004.port.T = TC_282_336.port_b.T; CABI0CabiA013005004.port.T = TC_334_336.port_b.T; CABI0CabiA013005004.port.T = TC_336_0.port_a.T; CABI0CabiA013005004.port.T = TC_336_1180.port_a.T; CABI0CabiA013005004.port.T = TC_336_338.port_a.T; CABI0CabiA013005004.port.T = TC_336_390.port_a.T; CABI0CabiA013005004.port.T = TsCABI0CabiA013005004.port.T; TsCABI0CabiA001005004.port.Q_flow + (TC_333_335.port_b.Q_flow + (TC_281_335.port_b.Q_flow + (CABI0CabiA001005004.port.Q_flow + (TC_335_337.port_a.Q_flow + (TC_335_389.port_a.Q_flow + (TC_335_1174.port_a.Q_flow + TC_335_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001005004.port.T = TC_281_335.port_b.T; CABI0CabiA001005004.port.T = TC_333_335.port_b.T; CABI0CabiA001005004.port.T = TC_335_0.port_a.T; CABI0CabiA001005004.port.T = TC_335_1174.port_a.T; CABI0CabiA001005004.port.T = TC_335_337.port_a.T; CABI0CabiA001005004.port.T = TC_335_389.port_a.T; CABI0CabiA001005004.port.T = TsCABI0CabiA001005004.port.T; TsCABI0CabiA013004004.port.Q_flow + (TC_332_334.port_b.Q_flow + (TC_280_334.port_b.Q_flow + (CABI0CabiA013004004.port.Q_flow + (TC_334_336.port_a.Q_flow + (TC_334_388.port_a.Q_flow + (TC_334_1173.port_a.Q_flow + TC_334_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013004004.port.T = TC_280_334.port_b.T; CABI0CabiA013004004.port.T = TC_332_334.port_b.T; CABI0CabiA013004004.port.T = TC_334_0.port_a.T; CABI0CabiA013004004.port.T = TC_334_1173.port_a.T; CABI0CabiA013004004.port.T = TC_334_336.port_a.T; CABI0CabiA013004004.port.T = TC_334_388.port_a.T; CABI0CabiA013004004.port.T = TsCABI0CabiA013004004.port.T; TsCABI0CabiA001004004.port.Q_flow + (TC_331_333.port_b.Q_flow + (TC_279_333.port_b.Q_flow + (CABI0CabiA001004004.port.Q_flow + (TC_333_335.port_a.Q_flow + (TC_333_387.port_a.Q_flow + (TC_333_1167.port_a.Q_flow + TC_333_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001004004.port.T = TC_279_333.port_b.T; CABI0CabiA001004004.port.T = TC_331_333.port_b.T; CABI0CabiA001004004.port.T = TC_333_0.port_a.T; CABI0CabiA001004004.port.T = TC_333_1167.port_a.T; CABI0CabiA001004004.port.T = TC_333_335.port_a.T; CABI0CabiA001004004.port.T = TC_333_387.port_a.T; CABI0CabiA001004004.port.T = TsCABI0CabiA001004004.port.T; TsCABI0CabiA013003004.port.Q_flow + (TC_330_332.port_b.Q_flow + (TC_278_332.port_b.Q_flow + (CABI0CabiA013003004.port.Q_flow + (TC_332_334.port_a.Q_flow + (TC_332_386.port_a.Q_flow + (TC_332_1166.port_a.Q_flow + TC_332_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013003004.port.T = TC_278_332.port_b.T; CABI0CabiA013003004.port.T = TC_330_332.port_b.T; CABI0CabiA013003004.port.T = TC_332_0.port_a.T; CABI0CabiA013003004.port.T = TC_332_1166.port_a.T; CABI0CabiA013003004.port.T = TC_332_334.port_a.T; CABI0CabiA013003004.port.T = TC_332_386.port_a.T; CABI0CabiA013003004.port.T = TsCABI0CabiA013003004.port.T; TsCABI0CabiA001003004.port.Q_flow + (TC_329_331.port_b.Q_flow + (TC_277_331.port_b.Q_flow + (CABI0CabiA001003004.port.Q_flow + (TC_331_333.port_a.Q_flow + (TC_331_385.port_a.Q_flow + (TC_331_1156.port_a.Q_flow + TC_331_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001003004.port.T = TC_277_331.port_b.T; CABI0CabiA001003004.port.T = TC_329_331.port_b.T; CABI0CabiA001003004.port.T = TC_331_0.port_a.T; CABI0CabiA001003004.port.T = TC_331_1156.port_a.T; CABI0CabiA001003004.port.T = TC_331_333.port_a.T; CABI0CabiA001003004.port.T = TC_331_385.port_a.T; CABI0CabiA001003004.port.T = TsCABI0CabiA001003004.port.T; TsCABI0CabiA013002004.port.Q_flow + (TC_328_330.port_b.Q_flow + (TC_276_330.port_b.Q_flow + (CABI0CabiA013002004.port.Q_flow + (TC_330_332.port_a.Q_flow + (TC_330_384.port_a.Q_flow + (TC_330_1155.port_a.Q_flow + TC_330_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013002004.port.T = TC_276_330.port_b.T; CABI0CabiA013002004.port.T = TC_328_330.port_b.T; CABI0CabiA013002004.port.T = TC_330_0.port_a.T; CABI0CabiA013002004.port.T = TC_330_1155.port_a.T; CABI0CabiA013002004.port.T = TC_330_332.port_a.T; CABI0CabiA013002004.port.T = TC_330_384.port_a.T; CABI0CabiA013002004.port.T = TsCABI0CabiA013002004.port.T; TsCABI0CabiA001002004.port.Q_flow + (TC_316_329.port_b.Q_flow + (TC_275_329.port_b.Q_flow + (CABI0CabiA001002004.port.Q_flow + (TC_329_331.port_a.Q_flow + (TC_329_383.port_a.Q_flow + (TC_329_1145.port_a.Q_flow + TC_329_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001002004.port.T = TC_275_329.port_b.T; CABI0CabiA001002004.port.T = TC_316_329.port_b.T; CABI0CabiA001002004.port.T = TC_329_0.port_a.T; CABI0CabiA001002004.port.T = TC_329_1145.port_a.T; CABI0CabiA001002004.port.T = TC_329_331.port_a.T; CABI0CabiA001002004.port.T = TC_329_383.port_a.T; CABI0CabiA001002004.port.T = TsCABI0CabiA001002004.port.T; TsCABI0CabiA013001004.port.Q_flow + (TC_327_328.port_b.Q_flow + (TC_274_328.port_b.Q_flow + (CABI0CabiA013001004.port.Q_flow + (TC_328_330.port_a.Q_flow + (TC_328_382.port_a.Q_flow + TC_328_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013001004.port.T = TC_274_328.port_b.T; CABI0CabiA013001004.port.T = TC_327_328.port_b.T; CABI0CabiA013001004.port.T = TC_328_0.port_a.T; CABI0CabiA013001004.port.T = TC_328_330.port_a.T; CABI0CabiA013001004.port.T = TC_328_382.port_a.T; CABI0CabiA013001004.port.T = TsCABI0CabiA013001004.port.T; TsCABI0CabiA012001004.port.Q_flow + (TC_326_327.port_b.Q_flow + (TC_273_327.port_b.Q_flow + (CABI0CabiA012001004.port.Q_flow + (TC_327_328.port_a.Q_flow + (TC_327_381.port_a.Q_flow + (TC_327_1155.port_a.Q_flow + TC_327_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012001004.port.T = TC_273_327.port_b.T; CABI0CabiA012001004.port.T = TC_326_327.port_b.T; CABI0CabiA012001004.port.T = TC_327_0.port_a.T; CABI0CabiA012001004.port.T = TC_327_1155.port_a.T; CABI0CabiA012001004.port.T = TC_327_328.port_a.T; CABI0CabiA012001004.port.T = TC_327_381.port_a.T; CABI0CabiA012001004.port.T = TsCABI0CabiA012001004.port.T; TsCABI0CabiA011001004.port.Q_flow + (TC_325_326.port_b.Q_flow + (TC_272_326.port_b.Q_flow + (CABI0CabiA011001004.port.Q_flow + (TC_326_327.port_a.Q_flow + (TC_326_380.port_a.Q_flow + (TC_326_1154.port_a.Q_flow + TC_326_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011001004.port.T = TC_272_326.port_b.T; CABI0CabiA011001004.port.T = TC_325_326.port_b.T; CABI0CabiA011001004.port.T = TC_326_0.port_a.T; CABI0CabiA011001004.port.T = TC_326_1154.port_a.T; CABI0CabiA011001004.port.T = TC_326_327.port_a.T; CABI0CabiA011001004.port.T = TC_326_380.port_a.T; CABI0CabiA011001004.port.T = TsCABI0CabiA011001004.port.T; TsCABI0CabiA010001004.port.Q_flow + (TC_324_325.port_b.Q_flow + (TC_271_325.port_b.Q_flow + (CABI0CabiA010001004.port.Q_flow + (TC_325_326.port_a.Q_flow + (TC_325_379.port_a.Q_flow + (TC_325_1153.port_a.Q_flow + TC_325_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010001004.port.T = TC_271_325.port_b.T; CABI0CabiA010001004.port.T = TC_324_325.port_b.T; CABI0CabiA010001004.port.T = TC_325_0.port_a.T; CABI0CabiA010001004.port.T = TC_325_1153.port_a.T; CABI0CabiA010001004.port.T = TC_325_326.port_a.T; CABI0CabiA010001004.port.T = TC_325_379.port_a.T; CABI0CabiA010001004.port.T = TsCABI0CabiA010001004.port.T; TsCABI0CabiA009001004.port.Q_flow + (TC_323_324.port_b.Q_flow + (TC_270_324.port_b.Q_flow + (CABI0CabiA009001004.port.Q_flow + (TC_324_325.port_a.Q_flow + (TC_324_378.port_a.Q_flow + (TC_324_1152.port_a.Q_flow + TC_324_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009001004.port.T = TC_270_324.port_b.T; CABI0CabiA009001004.port.T = TC_323_324.port_b.T; CABI0CabiA009001004.port.T = TC_324_0.port_a.T; CABI0CabiA009001004.port.T = TC_324_1152.port_a.T; CABI0CabiA009001004.port.T = TC_324_325.port_a.T; CABI0CabiA009001004.port.T = TC_324_378.port_a.T; CABI0CabiA009001004.port.T = TsCABI0CabiA009001004.port.T; TsCABI0CabiA008001004.port.Q_flow + (TC_322_323.port_b.Q_flow + (TC_269_323.port_b.Q_flow + (CABI0CabiA008001004.port.Q_flow + (TC_323_324.port_a.Q_flow + (TC_323_377.port_a.Q_flow + (TC_323_1151.port_a.Q_flow + TC_323_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008001004.port.T = TC_269_323.port_b.T; CABI0CabiA008001004.port.T = TC_322_323.port_b.T; CABI0CabiA008001004.port.T = TC_323_0.port_a.T; CABI0CabiA008001004.port.T = TC_323_1151.port_a.T; CABI0CabiA008001004.port.T = TC_323_324.port_a.T; CABI0CabiA008001004.port.T = TC_323_377.port_a.T; CABI0CabiA008001004.port.T = TsCABI0CabiA008001004.port.T; TsCABI0CabiA007001004.port.Q_flow + (TC_321_322.port_b.Q_flow + (TC_268_322.port_b.Q_flow + (CABI0CabiA007001004.port.Q_flow + (TC_322_323.port_a.Q_flow + (TC_322_376.port_a.Q_flow + (TC_322_1150.port_a.Q_flow + TC_322_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007001004.port.T = TC_268_322.port_b.T; CABI0CabiA007001004.port.T = TC_321_322.port_b.T; CABI0CabiA007001004.port.T = TC_322_0.port_a.T; CABI0CabiA007001004.port.T = TC_322_1150.port_a.T; CABI0CabiA007001004.port.T = TC_322_323.port_a.T; CABI0CabiA007001004.port.T = TC_322_376.port_a.T; CABI0CabiA007001004.port.T = TsCABI0CabiA007001004.port.T; TsCABI0CabiA006001004.port.Q_flow + (TC_320_321.port_b.Q_flow + (TC_267_321.port_b.Q_flow + (CABI0CabiA006001004.port.Q_flow + (TC_321_322.port_a.Q_flow + (TC_321_375.port_a.Q_flow + (TC_321_1149.port_a.Q_flow + TC_321_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006001004.port.T = TC_267_321.port_b.T; CABI0CabiA006001004.port.T = TC_320_321.port_b.T; CABI0CabiA006001004.port.T = TC_321_0.port_a.T; CABI0CabiA006001004.port.T = TC_321_1149.port_a.T; CABI0CabiA006001004.port.T = TC_321_322.port_a.T; CABI0CabiA006001004.port.T = TC_321_375.port_a.T; CABI0CabiA006001004.port.T = TsCABI0CabiA006001004.port.T; TsCABI0CabiA005001004.port.Q_flow + (TC_319_320.port_b.Q_flow + (TC_266_320.port_b.Q_flow + (CABI0CabiA005001004.port.Q_flow + (TC_320_321.port_a.Q_flow + (TC_320_374.port_a.Q_flow + (TC_320_1148.port_a.Q_flow + TC_320_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005001004.port.T = TC_266_320.port_b.T; CABI0CabiA005001004.port.T = TC_319_320.port_b.T; CABI0CabiA005001004.port.T = TC_320_0.port_a.T; CABI0CabiA005001004.port.T = TC_320_1148.port_a.T; CABI0CabiA005001004.port.T = TC_320_321.port_a.T; CABI0CabiA005001004.port.T = TC_320_374.port_a.T; CABI0CabiA005001004.port.T = TsCABI0CabiA005001004.port.T; TsCABI0CabiA004001004.port.Q_flow + (TC_318_319.port_b.Q_flow + (TC_265_319.port_b.Q_flow + (CABI0CabiA004001004.port.Q_flow + (TC_319_320.port_a.Q_flow + (TC_319_373.port_a.Q_flow + (TC_319_1147.port_a.Q_flow + TC_319_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004001004.port.T = TC_265_319.port_b.T; CABI0CabiA004001004.port.T = TC_318_319.port_b.T; CABI0CabiA004001004.port.T = TC_319_0.port_a.T; CABI0CabiA004001004.port.T = TC_319_1147.port_a.T; CABI0CabiA004001004.port.T = TC_319_320.port_a.T; CABI0CabiA004001004.port.T = TC_319_373.port_a.T; CABI0CabiA004001004.port.T = TsCABI0CabiA004001004.port.T; TsCABI0CabiA003001004.port.Q_flow + (TC_317_318.port_b.Q_flow + (TC_264_318.port_b.Q_flow + (CABI0CabiA003001004.port.Q_flow + (TC_318_319.port_a.Q_flow + (TC_318_372.port_a.Q_flow + (TC_318_1146.port_a.Q_flow + TC_318_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003001004.port.T = TC_264_318.port_b.T; CABI0CabiA003001004.port.T = TC_317_318.port_b.T; CABI0CabiA003001004.port.T = TC_318_0.port_a.T; CABI0CabiA003001004.port.T = TC_318_1146.port_a.T; CABI0CabiA003001004.port.T = TC_318_319.port_a.T; CABI0CabiA003001004.port.T = TC_318_372.port_a.T; CABI0CabiA003001004.port.T = TsCABI0CabiA003001004.port.T; TsCABI0CabiA002001004.port.Q_flow + (TC_316_317.port_b.Q_flow + (TC_263_317.port_b.Q_flow + (CABI0CabiA002001004.port.Q_flow + (TC_317_318.port_a.Q_flow + (TC_317_371.port_a.Q_flow + (TC_317_1145.port_a.Q_flow + TC_317_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002001004.port.T = TC_263_317.port_b.T; CABI0CabiA002001004.port.T = TC_316_317.port_b.T; CABI0CabiA002001004.port.T = TC_317_0.port_a.T; CABI0CabiA002001004.port.T = TC_317_1145.port_a.T; CABI0CabiA002001004.port.T = TC_317_318.port_a.T; CABI0CabiA002001004.port.T = TC_317_371.port_a.T; CABI0CabiA002001004.port.T = TsCABI0CabiA002001004.port.T; TsCABI0CabiA001001004.port.Q_flow + (TC_262_316.port_b.Q_flow + (CABI0CabiA001001004.port.Q_flow + (TC_316_317.port_a.Q_flow + (TC_316_329.port_a.Q_flow + (TC_316_370.port_a.Q_flow + TC_316_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001001004.port.T = TC_262_316.port_b.T; CABI0CabiA001001004.port.T = TC_316_0.port_a.T; CABI0CabiA001001004.port.T = TC_316_317.port_a.T; CABI0CabiA001001004.port.T = TC_316_329.port_a.T; CABI0CabiA001001004.port.T = TC_316_370.port_a.T; CABI0CabiA001001004.port.T = TsCABI0CabiA001001004.port.T; TsCABI0CabiA013016005.port.Q_flow + (TC_314_315.port_b.Q_flow + (TC_302_315.port_b.Q_flow + (CABI0CabiA013016005.port.Q_flow + (TC_315_369.port_a.Q_flow + (TC_315_478.port_a.Q_flow + TC_315_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013016005.port.T = TC_302_315.port_b.T; CABI0CabiA013016005.port.T = TC_314_315.port_b.T; CABI0CabiA013016005.port.T = TC_315_0.port_a.T; CABI0CabiA013016005.port.T = TC_315_369.port_a.T; CABI0CabiA013016005.port.T = TC_315_478.port_a.T; CABI0CabiA013016005.port.T = TsCABI0CabiA013016005.port.T; TsCABI0CabiA012016005.port.Q_flow + (TC_313_314.port_b.Q_flow + (CABI0CabiA012016005.port.Q_flow + (TC_314_315.port_a.Q_flow + (TC_314_368.port_a.Q_flow + (TC_314_477.port_a.Q_flow + (TC_314_1144.port_a.Q_flow + TC_314_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012016005.port.T = TC_313_314.port_b.T; CABI0CabiA012016005.port.T = TC_314_0.port_a.T; CABI0CabiA012016005.port.T = TC_314_1144.port_a.T; CABI0CabiA012016005.port.T = TC_314_315.port_a.T; CABI0CabiA012016005.port.T = TC_314_368.port_a.T; CABI0CabiA012016005.port.T = TC_314_477.port_a.T; CABI0CabiA012016005.port.T = TsCABI0CabiA012016005.port.T; TsCABI0CabiA011016005.port.Q_flow + (TC_312_313.port_b.Q_flow + (CABI0CabiA011016005.port.Q_flow + (TC_313_314.port_a.Q_flow + (TC_313_367.port_a.Q_flow + (TC_313_476.port_a.Q_flow + (TC_313_1143.port_a.Q_flow + TC_313_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011016005.port.T = TC_312_313.port_b.T; CABI0CabiA011016005.port.T = TC_313_0.port_a.T; CABI0CabiA011016005.port.T = TC_313_1143.port_a.T; CABI0CabiA011016005.port.T = TC_313_314.port_a.T; CABI0CabiA011016005.port.T = TC_313_367.port_a.T; CABI0CabiA011016005.port.T = TC_313_476.port_a.T; CABI0CabiA011016005.port.T = TsCABI0CabiA011016005.port.T; TsCABI0CabiA010016005.port.Q_flow + (TC_311_312.port_b.Q_flow + (CABI0CabiA010016005.port.Q_flow + (TC_312_313.port_a.Q_flow + (TC_312_366.port_a.Q_flow + (TC_312_475.port_a.Q_flow + (TC_312_1142.port_a.Q_flow + TC_312_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010016005.port.T = TC_311_312.port_b.T; CABI0CabiA010016005.port.T = TC_312_0.port_a.T; CABI0CabiA010016005.port.T = TC_312_1142.port_a.T; CABI0CabiA010016005.port.T = TC_312_313.port_a.T; CABI0CabiA010016005.port.T = TC_312_366.port_a.T; CABI0CabiA010016005.port.T = TC_312_475.port_a.T; CABI0CabiA010016005.port.T = TsCABI0CabiA010016005.port.T; TsCABI0CabiA009016005.port.Q_flow + (TC_310_311.port_b.Q_flow + (CABI0CabiA009016005.port.Q_flow + (TC_311_312.port_a.Q_flow + (TC_311_365.port_a.Q_flow + (TC_311_474.port_a.Q_flow + (TC_311_1141.port_a.Q_flow + TC_311_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009016005.port.T = TC_310_311.port_b.T; CABI0CabiA009016005.port.T = TC_311_0.port_a.T; CABI0CabiA009016005.port.T = TC_311_1141.port_a.T; CABI0CabiA009016005.port.T = TC_311_312.port_a.T; CABI0CabiA009016005.port.T = TC_311_365.port_a.T; CABI0CabiA009016005.port.T = TC_311_474.port_a.T; CABI0CabiA009016005.port.T = TsCABI0CabiA009016005.port.T; TsCABI0CabiA008016005.port.Q_flow + (TC_309_310.port_b.Q_flow + (CABI0CabiA008016005.port.Q_flow + (TC_310_311.port_a.Q_flow + (TC_310_364.port_a.Q_flow + (TC_310_473.port_a.Q_flow + (TC_310_1140.port_a.Q_flow + TC_310_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008016005.port.T = TC_309_310.port_b.T; CABI0CabiA008016005.port.T = TC_310_0.port_a.T; CABI0CabiA008016005.port.T = TC_310_1140.port_a.T; CABI0CabiA008016005.port.T = TC_310_311.port_a.T; CABI0CabiA008016005.port.T = TC_310_364.port_a.T; CABI0CabiA008016005.port.T = TC_310_473.port_a.T; CABI0CabiA008016005.port.T = TsCABI0CabiA008016005.port.T; TsCABI0CabiA007016005.port.Q_flow + (TC_308_309.port_b.Q_flow + (CABI0CabiA007016005.port.Q_flow + (TC_309_310.port_a.Q_flow + (TC_309_363.port_a.Q_flow + (TC_309_472.port_a.Q_flow + (TC_309_1139.port_a.Q_flow + TC_309_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007016005.port.T = TC_308_309.port_b.T; CABI0CabiA007016005.port.T = TC_309_0.port_a.T; CABI0CabiA007016005.port.T = TC_309_1139.port_a.T; CABI0CabiA007016005.port.T = TC_309_310.port_a.T; CABI0CabiA007016005.port.T = TC_309_363.port_a.T; CABI0CabiA007016005.port.T = TC_309_472.port_a.T; CABI0CabiA007016005.port.T = TsCABI0CabiA007016005.port.T; TsCABI0CabiA006016005.port.Q_flow + (TC_307_308.port_b.Q_flow + (CABI0CabiA006016005.port.Q_flow + (TC_308_309.port_a.Q_flow + (TC_308_362.port_a.Q_flow + (TC_308_471.port_a.Q_flow + (TC_308_1138.port_a.Q_flow + TC_308_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006016005.port.T = TC_307_308.port_b.T; CABI0CabiA006016005.port.T = TC_308_0.port_a.T; CABI0CabiA006016005.port.T = TC_308_1138.port_a.T; CABI0CabiA006016005.port.T = TC_308_309.port_a.T; CABI0CabiA006016005.port.T = TC_308_362.port_a.T; CABI0CabiA006016005.port.T = TC_308_471.port_a.T; CABI0CabiA006016005.port.T = TsCABI0CabiA006016005.port.T; TsCABI0CabiA005016005.port.Q_flow + (TC_306_307.port_b.Q_flow + (CABI0CabiA005016005.port.Q_flow + (TC_307_308.port_a.Q_flow + (TC_307_361.port_a.Q_flow + (TC_307_470.port_a.Q_flow + (TC_307_1137.port_a.Q_flow + TC_307_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005016005.port.T = TC_306_307.port_b.T; CABI0CabiA005016005.port.T = TC_307_0.port_a.T; CABI0CabiA005016005.port.T = TC_307_1137.port_a.T; CABI0CabiA005016005.port.T = TC_307_308.port_a.T; CABI0CabiA005016005.port.T = TC_307_361.port_a.T; CABI0CabiA005016005.port.T = TC_307_470.port_a.T; CABI0CabiA005016005.port.T = TsCABI0CabiA005016005.port.T; TsCABI0CabiA004016005.port.Q_flow + (TC_305_306.port_b.Q_flow + (CABI0CabiA004016005.port.Q_flow + (TC_306_307.port_a.Q_flow + (TC_306_360.port_a.Q_flow + (TC_306_469.port_a.Q_flow + (TC_306_1136.port_a.Q_flow + TC_306_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004016005.port.T = TC_305_306.port_b.T; CABI0CabiA004016005.port.T = TC_306_0.port_a.T; CABI0CabiA004016005.port.T = TC_306_1136.port_a.T; CABI0CabiA004016005.port.T = TC_306_307.port_a.T; CABI0CabiA004016005.port.T = TC_306_360.port_a.T; CABI0CabiA004016005.port.T = TC_306_469.port_a.T; CABI0CabiA004016005.port.T = TsCABI0CabiA004016005.port.T; TsCABI0CabiA003016005.port.Q_flow + (TC_304_305.port_b.Q_flow + (CABI0CabiA003016005.port.Q_flow + (TC_305_306.port_a.Q_flow + (TC_305_359.port_a.Q_flow + (TC_305_468.port_a.Q_flow + (TC_305_1135.port_a.Q_flow + TC_305_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003016005.port.T = TC_304_305.port_b.T; CABI0CabiA003016005.port.T = TC_305_0.port_a.T; CABI0CabiA003016005.port.T = TC_305_1135.port_a.T; CABI0CabiA003016005.port.T = TC_305_306.port_a.T; CABI0CabiA003016005.port.T = TC_305_359.port_a.T; CABI0CabiA003016005.port.T = TC_305_468.port_a.T; CABI0CabiA003016005.port.T = TsCABI0CabiA003016005.port.T; TsCABI0CabiA002016005.port.Q_flow + (TC_303_304.port_b.Q_flow + (CABI0CabiA002016005.port.Q_flow + (TC_304_305.port_a.Q_flow + (TC_304_358.port_a.Q_flow + (TC_304_467.port_a.Q_flow + (TC_304_1134.port_a.Q_flow + TC_304_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002016005.port.T = TC_303_304.port_b.T; CABI0CabiA002016005.port.T = TC_304_0.port_a.T; CABI0CabiA002016005.port.T = TC_304_1134.port_a.T; CABI0CabiA002016005.port.T = TC_304_305.port_a.T; CABI0CabiA002016005.port.T = TC_304_358.port_a.T; CABI0CabiA002016005.port.T = TC_304_467.port_a.T; CABI0CabiA002016005.port.T = TsCABI0CabiA002016005.port.T; TsCABI0CabiA001016005.port.Q_flow + (TC_301_303.port_b.Q_flow + (CABI0CabiA001016005.port.Q_flow + (TC_303_304.port_a.Q_flow + (TC_303_357.port_a.Q_flow + (TC_303_466.port_a.Q_flow + TC_303_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001016005.port.T = TC_301_303.port_b.T; CABI0CabiA001016005.port.T = TC_303_0.port_a.T; CABI0CabiA001016005.port.T = TC_303_304.port_a.T; CABI0CabiA001016005.port.T = TC_303_357.port_a.T; CABI0CabiA001016005.port.T = TC_303_466.port_a.T; CABI0CabiA001016005.port.T = TsCABI0CabiA001016005.port.T; TsCABI0CabiA013015005.port.Q_flow + (TC_300_302.port_b.Q_flow + (CABI0CabiA013015005.port.Q_flow + (TC_302_315.port_a.Q_flow + (TC_302_356.port_a.Q_flow + (TC_302_465.port_a.Q_flow + (TC_302_1144.port_a.Q_flow + TC_302_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013015005.port.T = TC_300_302.port_b.T; CABI0CabiA013015005.port.T = TC_302_0.port_a.T; CABI0CabiA013015005.port.T = TC_302_1144.port_a.T; CABI0CabiA013015005.port.T = TC_302_315.port_a.T; CABI0CabiA013015005.port.T = TC_302_356.port_a.T; CABI0CabiA013015005.port.T = TC_302_465.port_a.T; CABI0CabiA013015005.port.T = TsCABI0CabiA013015005.port.T; TsCABI0CabiA001015005.port.Q_flow + (TC_299_301.port_b.Q_flow + (CABI0CabiA001015005.port.Q_flow + (TC_301_303.port_a.Q_flow + (TC_301_355.port_a.Q_flow + (TC_301_464.port_a.Q_flow + (TC_301_1134.port_a.Q_flow + TC_301_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001015005.port.T = TC_299_301.port_b.T; CABI0CabiA001015005.port.T = TC_301_0.port_a.T; CABI0CabiA001015005.port.T = TC_301_1134.port_a.T; CABI0CabiA001015005.port.T = TC_301_303.port_a.T; CABI0CabiA001015005.port.T = TC_301_355.port_a.T; CABI0CabiA001015005.port.T = TC_301_464.port_a.T; CABI0CabiA001015005.port.T = TsCABI0CabiA001015005.port.T; TsCABI0CabiA013014005.port.Q_flow + (TC_298_300.port_b.Q_flow + (CABI0CabiA013014005.port.Q_flow + (TC_300_302.port_a.Q_flow + (TC_300_354.port_a.Q_flow + (TC_300_463.port_a.Q_flow + (TC_300_1133.port_a.Q_flow + TC_300_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013014005.port.T = TC_298_300.port_b.T; CABI0CabiA013014005.port.T = TC_300_0.port_a.T; CABI0CabiA013014005.port.T = TC_300_1133.port_a.T; CABI0CabiA013014005.port.T = TC_300_302.port_a.T; CABI0CabiA013014005.port.T = TC_300_354.port_a.T; CABI0CabiA013014005.port.T = TC_300_463.port_a.T; CABI0CabiA013014005.port.T = TsCABI0CabiA013014005.port.T; TsCABI0CabiA001014005.port.Q_flow + (TC_297_299.port_b.Q_flow + (CABI0CabiA001014005.port.Q_flow + (TC_299_301.port_a.Q_flow + (TC_299_353.port_a.Q_flow + (TC_299_462.port_a.Q_flow + (TC_299_1132.port_a.Q_flow + TC_299_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001014005.port.T = TC_297_299.port_b.T; CABI0CabiA001014005.port.T = TC_299_0.port_a.T; CABI0CabiA001014005.port.T = TC_299_1132.port_a.T; CABI0CabiA001014005.port.T = TC_299_301.port_a.T; CABI0CabiA001014005.port.T = TC_299_353.port_a.T; CABI0CabiA001014005.port.T = TC_299_462.port_a.T; CABI0CabiA001014005.port.T = TsCABI0CabiA001014005.port.T; TsCABI0CabiA013013005.port.Q_flow + (TC_296_298.port_b.Q_flow + (CABI0CabiA013013005.port.Q_flow + (TC_298_300.port_a.Q_flow + (TC_298_352.port_a.Q_flow + (TC_298_461.port_a.Q_flow + (TC_298_1131.port_a.Q_flow + TC_298_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013013005.port.T = TC_296_298.port_b.T; CABI0CabiA013013005.port.T = TC_298_0.port_a.T; CABI0CabiA013013005.port.T = TC_298_1131.port_a.T; CABI0CabiA013013005.port.T = TC_298_300.port_a.T; CABI0CabiA013013005.port.T = TC_298_352.port_a.T; CABI0CabiA013013005.port.T = TC_298_461.port_a.T; CABI0CabiA013013005.port.T = TsCABI0CabiA013013005.port.T; TsCABI0CabiA001013005.port.Q_flow + (TC_295_297.port_b.Q_flow + (CABI0CabiA001013005.port.Q_flow + (TC_297_299.port_a.Q_flow + (TC_297_351.port_a.Q_flow + (TC_297_460.port_a.Q_flow + (TC_297_1130.port_a.Q_flow + TC_297_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001013005.port.T = TC_295_297.port_b.T; CABI0CabiA001013005.port.T = TC_297_0.port_a.T; CABI0CabiA001013005.port.T = TC_297_1130.port_a.T; CABI0CabiA001013005.port.T = TC_297_299.port_a.T; CABI0CabiA001013005.port.T = TC_297_351.port_a.T; CABI0CabiA001013005.port.T = TC_297_460.port_a.T; CABI0CabiA001013005.port.T = TsCABI0CabiA001013005.port.T; TsCABI0CabiA013012005.port.Q_flow + (TC_294_296.port_b.Q_flow + (CABI0CabiA013012005.port.Q_flow + (TC_296_298.port_a.Q_flow + (TC_296_350.port_a.Q_flow + (TC_296_459.port_a.Q_flow + (TC_296_1129.port_a.Q_flow + TC_296_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013012005.port.T = TC_294_296.port_b.T; CABI0CabiA013012005.port.T = TC_296_0.port_a.T; CABI0CabiA013012005.port.T = TC_296_1129.port_a.T; CABI0CabiA013012005.port.T = TC_296_298.port_a.T; CABI0CabiA013012005.port.T = TC_296_350.port_a.T; CABI0CabiA013012005.port.T = TC_296_459.port_a.T; CABI0CabiA013012005.port.T = TsCABI0CabiA013012005.port.T; TsCABI0CabiA001012005.port.Q_flow + (TC_293_295.port_b.Q_flow + (CABI0CabiA001012005.port.Q_flow + (TC_295_297.port_a.Q_flow + (TC_295_349.port_a.Q_flow + (TC_295_458.port_a.Q_flow + (TC_295_1128.port_a.Q_flow + TC_295_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001012005.port.T = TC_293_295.port_b.T; CABI0CabiA001012005.port.T = TC_295_0.port_a.T; CABI0CabiA001012005.port.T = TC_295_1128.port_a.T; CABI0CabiA001012005.port.T = TC_295_297.port_a.T; CABI0CabiA001012005.port.T = TC_295_349.port_a.T; CABI0CabiA001012005.port.T = TC_295_458.port_a.T; CABI0CabiA001012005.port.T = TsCABI0CabiA001012005.port.T; TsCABI0CabiA013011005.port.Q_flow + (TC_292_294.port_b.Q_flow + (CABI0CabiA013011005.port.Q_flow + (TC_294_296.port_a.Q_flow + (TC_294_348.port_a.Q_flow + (TC_294_457.port_a.Q_flow + (TC_294_1127.port_a.Q_flow + TC_294_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013011005.port.T = TC_292_294.port_b.T; CABI0CabiA013011005.port.T = TC_294_0.port_a.T; CABI0CabiA013011005.port.T = TC_294_1127.port_a.T; CABI0CabiA013011005.port.T = TC_294_296.port_a.T; CABI0CabiA013011005.port.T = TC_294_348.port_a.T; CABI0CabiA013011005.port.T = TC_294_457.port_a.T; CABI0CabiA013011005.port.T = TsCABI0CabiA013011005.port.T; TsCABI0CabiA001011005.port.Q_flow + (TC_291_293.port_b.Q_flow + (CABI0CabiA001011005.port.Q_flow + (TC_293_295.port_a.Q_flow + (TC_293_347.port_a.Q_flow + (TC_293_456.port_a.Q_flow + (TC_293_1126.port_a.Q_flow + TC_293_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001011005.port.T = TC_291_293.port_b.T; CABI0CabiA001011005.port.T = TC_293_0.port_a.T; CABI0CabiA001011005.port.T = TC_293_1126.port_a.T; CABI0CabiA001011005.port.T = TC_293_295.port_a.T; CABI0CabiA001011005.port.T = TC_293_347.port_a.T; CABI0CabiA001011005.port.T = TC_293_456.port_a.T; CABI0CabiA001011005.port.T = TsCABI0CabiA001011005.port.T; TsCABI0CabiA013010005.port.Q_flow + (TC_290_292.port_b.Q_flow + (CABI0CabiA013010005.port.Q_flow + (TC_292_294.port_a.Q_flow + (TC_292_346.port_a.Q_flow + (TC_292_455.port_a.Q_flow + (TC_292_1125.port_a.Q_flow + TC_292_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013010005.port.T = TC_290_292.port_b.T; CABI0CabiA013010005.port.T = TC_292_0.port_a.T; CABI0CabiA013010005.port.T = TC_292_1125.port_a.T; CABI0CabiA013010005.port.T = TC_292_294.port_a.T; CABI0CabiA013010005.port.T = TC_292_346.port_a.T; CABI0CabiA013010005.port.T = TC_292_455.port_a.T; CABI0CabiA013010005.port.T = TsCABI0CabiA013010005.port.T; TsCABI0CabiA001010005.port.Q_flow + (TC_289_291.port_b.Q_flow + (CABI0CabiA001010005.port.Q_flow + (TC_291_293.port_a.Q_flow + (TC_291_345.port_a.Q_flow + (TC_291_454.port_a.Q_flow + (TC_291_1124.port_a.Q_flow + TC_291_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001010005.port.T = TC_289_291.port_b.T; CABI0CabiA001010005.port.T = TC_291_0.port_a.T; CABI0CabiA001010005.port.T = TC_291_1124.port_a.T; CABI0CabiA001010005.port.T = TC_291_293.port_a.T; CABI0CabiA001010005.port.T = TC_291_345.port_a.T; CABI0CabiA001010005.port.T = TC_291_454.port_a.T; CABI0CabiA001010005.port.T = TsCABI0CabiA001010005.port.T; TsCABI0CabiA013009005.port.Q_flow + (TC_288_290.port_b.Q_flow + (CABI0CabiA013009005.port.Q_flow + (TC_290_292.port_a.Q_flow + (TC_290_344.port_a.Q_flow + (TC_290_453.port_a.Q_flow + (TC_290_1123.port_a.Q_flow + TC_290_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013009005.port.T = TC_288_290.port_b.T; CABI0CabiA013009005.port.T = TC_290_0.port_a.T; CABI0CabiA013009005.port.T = TC_290_1123.port_a.T; CABI0CabiA013009005.port.T = TC_290_292.port_a.T; CABI0CabiA013009005.port.T = TC_290_344.port_a.T; CABI0CabiA013009005.port.T = TC_290_453.port_a.T; CABI0CabiA013009005.port.T = TsCABI0CabiA013009005.port.T; TsCABI0CabiA001009005.port.Q_flow + (TC_287_289.port_b.Q_flow + (CABI0CabiA001009005.port.Q_flow + (TC_289_291.port_a.Q_flow + (TC_289_343.port_a.Q_flow + (TC_289_452.port_a.Q_flow + (TC_289_1122.port_a.Q_flow + TC_289_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001009005.port.T = TC_287_289.port_b.T; CABI0CabiA001009005.port.T = TC_289_0.port_a.T; CABI0CabiA001009005.port.T = TC_289_1122.port_a.T; CABI0CabiA001009005.port.T = TC_289_291.port_a.T; CABI0CabiA001009005.port.T = TC_289_343.port_a.T; CABI0CabiA001009005.port.T = TC_289_452.port_a.T; CABI0CabiA001009005.port.T = TsCABI0CabiA001009005.port.T; TsCABI0CabiA013008005.port.Q_flow + (TC_286_288.port_b.Q_flow + (CABI0CabiA013008005.port.Q_flow + (TC_288_290.port_a.Q_flow + (TC_288_342.port_a.Q_flow + (TC_288_451.port_a.Q_flow + (TC_288_1121.port_a.Q_flow + TC_288_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013008005.port.T = TC_286_288.port_b.T; CABI0CabiA013008005.port.T = TC_288_0.port_a.T; CABI0CabiA013008005.port.T = TC_288_1121.port_a.T; CABI0CabiA013008005.port.T = TC_288_290.port_a.T; CABI0CabiA013008005.port.T = TC_288_342.port_a.T; CABI0CabiA013008005.port.T = TC_288_451.port_a.T; CABI0CabiA013008005.port.T = TsCABI0CabiA013008005.port.T; TsCABI0CabiA001008005.port.Q_flow + (TC_285_287.port_b.Q_flow + (CABI0CabiA001008005.port.Q_flow + (TC_287_289.port_a.Q_flow + (TC_287_341.port_a.Q_flow + (TC_287_450.port_a.Q_flow + (TC_287_1120.port_a.Q_flow + TC_287_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001008005.port.T = TC_285_287.port_b.T; CABI0CabiA001008005.port.T = TC_287_0.port_a.T; CABI0CabiA001008005.port.T = TC_287_1120.port_a.T; CABI0CabiA001008005.port.T = TC_287_289.port_a.T; CABI0CabiA001008005.port.T = TC_287_341.port_a.T; CABI0CabiA001008005.port.T = TC_287_450.port_a.T; CABI0CabiA001008005.port.T = TsCABI0CabiA001008005.port.T; TsCABI0CabiA013007005.port.Q_flow + (TC_284_286.port_b.Q_flow + (CABI0CabiA013007005.port.Q_flow + (TC_286_288.port_a.Q_flow + (TC_286_340.port_a.Q_flow + (TC_286_449.port_a.Q_flow + (TC_286_1119.port_a.Q_flow + TC_286_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013007005.port.T = TC_284_286.port_b.T; CABI0CabiA013007005.port.T = TC_286_0.port_a.T; CABI0CabiA013007005.port.T = TC_286_1119.port_a.T; CABI0CabiA013007005.port.T = TC_286_288.port_a.T; CABI0CabiA013007005.port.T = TC_286_340.port_a.T; CABI0CabiA013007005.port.T = TC_286_449.port_a.T; CABI0CabiA013007005.port.T = TsCABI0CabiA013007005.port.T; TsCABI0CabiA001007005.port.Q_flow + (TC_283_285.port_b.Q_flow + (CABI0CabiA001007005.port.Q_flow + (TC_285_287.port_a.Q_flow + (TC_285_339.port_a.Q_flow + (TC_285_448.port_a.Q_flow + (TC_285_1118.port_a.Q_flow + TC_285_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001007005.port.T = TC_283_285.port_b.T; CABI0CabiA001007005.port.T = TC_285_0.port_a.T; CABI0CabiA001007005.port.T = TC_285_1118.port_a.T; CABI0CabiA001007005.port.T = TC_285_287.port_a.T; CABI0CabiA001007005.port.T = TC_285_339.port_a.T; CABI0CabiA001007005.port.T = TC_285_448.port_a.T; CABI0CabiA001007005.port.T = TsCABI0CabiA001007005.port.T; TsCABI0CabiA013006005.port.Q_flow + (TC_282_284.port_b.Q_flow + (CABI0CabiA013006005.port.Q_flow + (TC_284_286.port_a.Q_flow + (TC_284_338.port_a.Q_flow + (TC_284_447.port_a.Q_flow + (TC_284_1117.port_a.Q_flow + TC_284_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013006005.port.T = TC_282_284.port_b.T; CABI0CabiA013006005.port.T = TC_284_0.port_a.T; CABI0CabiA013006005.port.T = TC_284_1117.port_a.T; CABI0CabiA013006005.port.T = TC_284_286.port_a.T; CABI0CabiA013006005.port.T = TC_284_338.port_a.T; CABI0CabiA013006005.port.T = TC_284_447.port_a.T; CABI0CabiA013006005.port.T = TsCABI0CabiA013006005.port.T; TsCABI0CabiA001006005.port.Q_flow + (TC_281_283.port_b.Q_flow + (CABI0CabiA001006005.port.Q_flow + (TC_283_285.port_a.Q_flow + (TC_283_337.port_a.Q_flow + (TC_283_446.port_a.Q_flow + (TC_283_1116.port_a.Q_flow + TC_283_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001006005.port.T = TC_281_283.port_b.T; CABI0CabiA001006005.port.T = TC_283_0.port_a.T; CABI0CabiA001006005.port.T = TC_283_1116.port_a.T; CABI0CabiA001006005.port.T = TC_283_285.port_a.T; CABI0CabiA001006005.port.T = TC_283_337.port_a.T; CABI0CabiA001006005.port.T = TC_283_446.port_a.T; CABI0CabiA001006005.port.T = TsCABI0CabiA001006005.port.T; TsCABI0CabiA013005005.port.Q_flow + (TC_280_282.port_b.Q_flow + (CABI0CabiA013005005.port.Q_flow + (TC_282_284.port_a.Q_flow + (TC_282_336.port_a.Q_flow + (TC_282_445.port_a.Q_flow + (TC_282_1115.port_a.Q_flow + TC_282_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013005005.port.T = TC_280_282.port_b.T; CABI0CabiA013005005.port.T = TC_282_0.port_a.T; CABI0CabiA013005005.port.T = TC_282_1115.port_a.T; CABI0CabiA013005005.port.T = TC_282_284.port_a.T; CABI0CabiA013005005.port.T = TC_282_336.port_a.T; CABI0CabiA013005005.port.T = TC_282_445.port_a.T; CABI0CabiA013005005.port.T = TsCABI0CabiA013005005.port.T; TsCABI0CabiA001005005.port.Q_flow + (TC_279_281.port_b.Q_flow + (CABI0CabiA001005005.port.Q_flow + (TC_281_283.port_a.Q_flow + (TC_281_335.port_a.Q_flow + (TC_281_444.port_a.Q_flow + (TC_281_1114.port_a.Q_flow + TC_281_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001005005.port.T = TC_279_281.port_b.T; CABI0CabiA001005005.port.T = TC_281_0.port_a.T; CABI0CabiA001005005.port.T = TC_281_1114.port_a.T; CABI0CabiA001005005.port.T = TC_281_283.port_a.T; CABI0CabiA001005005.port.T = TC_281_335.port_a.T; CABI0CabiA001005005.port.T = TC_281_444.port_a.T; CABI0CabiA001005005.port.T = TsCABI0CabiA001005005.port.T; TsCABI0CabiA013004005.port.Q_flow + (TC_278_280.port_b.Q_flow + (CABI0CabiA013004005.port.Q_flow + (TC_280_282.port_a.Q_flow + (TC_280_334.port_a.Q_flow + (TC_280_443.port_a.Q_flow + (TC_280_1113.port_a.Q_flow + TC_280_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013004005.port.T = TC_278_280.port_b.T; CABI0CabiA013004005.port.T = TC_280_0.port_a.T; CABI0CabiA013004005.port.T = TC_280_1113.port_a.T; CABI0CabiA013004005.port.T = TC_280_282.port_a.T; CABI0CabiA013004005.port.T = TC_280_334.port_a.T; CABI0CabiA013004005.port.T = TC_280_443.port_a.T; CABI0CabiA013004005.port.T = TsCABI0CabiA013004005.port.T; TsCABI0CabiA001004005.port.Q_flow + (TC_277_279.port_b.Q_flow + (CABI0CabiA001004005.port.Q_flow + (TC_279_281.port_a.Q_flow + (TC_279_333.port_a.Q_flow + (TC_279_442.port_a.Q_flow + (TC_279_1112.port_a.Q_flow + TC_279_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001004005.port.T = TC_277_279.port_b.T; CABI0CabiA001004005.port.T = TC_279_0.port_a.T; CABI0CabiA001004005.port.T = TC_279_1112.port_a.T; CABI0CabiA001004005.port.T = TC_279_281.port_a.T; CABI0CabiA001004005.port.T = TC_279_333.port_a.T; CABI0CabiA001004005.port.T = TC_279_442.port_a.T; CABI0CabiA001004005.port.T = TsCABI0CabiA001004005.port.T; TsCABI0CabiA013003005.port.Q_flow + (TC_276_278.port_b.Q_flow + (CABI0CabiA013003005.port.Q_flow + (TC_278_280.port_a.Q_flow + (TC_278_332.port_a.Q_flow + (TC_278_441.port_a.Q_flow + (TC_278_1111.port_a.Q_flow + TC_278_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013003005.port.T = TC_276_278.port_b.T; CABI0CabiA013003005.port.T = TC_278_0.port_a.T; CABI0CabiA013003005.port.T = TC_278_1111.port_a.T; CABI0CabiA013003005.port.T = TC_278_280.port_a.T; CABI0CabiA013003005.port.T = TC_278_332.port_a.T; CABI0CabiA013003005.port.T = TC_278_441.port_a.T; CABI0CabiA013003005.port.T = TsCABI0CabiA013003005.port.T; TsCABI0CabiA001003005.port.Q_flow + (TC_275_277.port_b.Q_flow + (CABI0CabiA001003005.port.Q_flow + (TC_277_279.port_a.Q_flow + (TC_277_331.port_a.Q_flow + (TC_277_440.port_a.Q_flow + (TC_277_1110.port_a.Q_flow + TC_277_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001003005.port.T = TC_275_277.port_b.T; CABI0CabiA001003005.port.T = TC_277_0.port_a.T; CABI0CabiA001003005.port.T = TC_277_1110.port_a.T; CABI0CabiA001003005.port.T = TC_277_279.port_a.T; CABI0CabiA001003005.port.T = TC_277_331.port_a.T; CABI0CabiA001003005.port.T = TC_277_440.port_a.T; CABI0CabiA001003005.port.T = TsCABI0CabiA001003005.port.T; TsCABI0CabiA013002005.port.Q_flow + (TC_274_276.port_b.Q_flow + (CABI0CabiA013002005.port.Q_flow + (TC_276_278.port_a.Q_flow + (TC_276_330.port_a.Q_flow + (TC_276_439.port_a.Q_flow + (TC_276_1109.port_a.Q_flow + TC_276_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013002005.port.T = TC_274_276.port_b.T; CABI0CabiA013002005.port.T = TC_276_0.port_a.T; CABI0CabiA013002005.port.T = TC_276_1109.port_a.T; CABI0CabiA013002005.port.T = TC_276_278.port_a.T; CABI0CabiA013002005.port.T = TC_276_330.port_a.T; CABI0CabiA013002005.port.T = TC_276_439.port_a.T; CABI0CabiA013002005.port.T = TsCABI0CabiA013002005.port.T; TsCABI0CabiA001002005.port.Q_flow + (TC_262_275.port_b.Q_flow + (CABI0CabiA001002005.port.Q_flow + (TC_275_277.port_a.Q_flow + (TC_275_329.port_a.Q_flow + (TC_275_438.port_a.Q_flow + (TC_275_1099.port_a.Q_flow + TC_275_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001002005.port.T = TC_262_275.port_b.T; CABI0CabiA001002005.port.T = TC_275_0.port_a.T; CABI0CabiA001002005.port.T = TC_275_1099.port_a.T; CABI0CabiA001002005.port.T = TC_275_277.port_a.T; CABI0CabiA001002005.port.T = TC_275_329.port_a.T; CABI0CabiA001002005.port.T = TC_275_438.port_a.T; CABI0CabiA001002005.port.T = TsCABI0CabiA001002005.port.T; TsCABI0CabiA013001005.port.Q_flow + (TC_273_274.port_b.Q_flow + (CABI0CabiA013001005.port.Q_flow + (TC_274_276.port_a.Q_flow + (TC_274_328.port_a.Q_flow + (TC_274_437.port_a.Q_flow + TC_274_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013001005.port.T = TC_273_274.port_b.T; CABI0CabiA013001005.port.T = TC_274_0.port_a.T; CABI0CabiA013001005.port.T = TC_274_276.port_a.T; CABI0CabiA013001005.port.T = TC_274_328.port_a.T; CABI0CabiA013001005.port.T = TC_274_437.port_a.T; CABI0CabiA013001005.port.T = TsCABI0CabiA013001005.port.T; TsCABI0CabiA012001005.port.Q_flow + (TC_272_273.port_b.Q_flow + (CABI0CabiA012001005.port.Q_flow + (TC_273_274.port_a.Q_flow + (TC_273_327.port_a.Q_flow + (TC_273_436.port_a.Q_flow + (TC_273_1109.port_a.Q_flow + TC_273_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012001005.port.T = TC_272_273.port_b.T; CABI0CabiA012001005.port.T = TC_273_0.port_a.T; CABI0CabiA012001005.port.T = TC_273_1109.port_a.T; CABI0CabiA012001005.port.T = TC_273_274.port_a.T; CABI0CabiA012001005.port.T = TC_273_327.port_a.T; CABI0CabiA012001005.port.T = TC_273_436.port_a.T; CABI0CabiA012001005.port.T = TsCABI0CabiA012001005.port.T; TsCABI0CabiA011001005.port.Q_flow + (TC_271_272.port_b.Q_flow + (CABI0CabiA011001005.port.Q_flow + (TC_272_273.port_a.Q_flow + (TC_272_326.port_a.Q_flow + (TC_272_435.port_a.Q_flow + (TC_272_1108.port_a.Q_flow + TC_272_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011001005.port.T = TC_271_272.port_b.T; CABI0CabiA011001005.port.T = TC_272_0.port_a.T; CABI0CabiA011001005.port.T = TC_272_1108.port_a.T; CABI0CabiA011001005.port.T = TC_272_273.port_a.T; CABI0CabiA011001005.port.T = TC_272_326.port_a.T; CABI0CabiA011001005.port.T = TC_272_435.port_a.T; CABI0CabiA011001005.port.T = TsCABI0CabiA011001005.port.T; TsCABI0CabiA010001005.port.Q_flow + (TC_270_271.port_b.Q_flow + (CABI0CabiA010001005.port.Q_flow + (TC_271_272.port_a.Q_flow + (TC_271_325.port_a.Q_flow + (TC_271_434.port_a.Q_flow + (TC_271_1107.port_a.Q_flow + TC_271_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010001005.port.T = TC_270_271.port_b.T; CABI0CabiA010001005.port.T = TC_271_0.port_a.T; CABI0CabiA010001005.port.T = TC_271_1107.port_a.T; CABI0CabiA010001005.port.T = TC_271_272.port_a.T; CABI0CabiA010001005.port.T = TC_271_325.port_a.T; CABI0CabiA010001005.port.T = TC_271_434.port_a.T; CABI0CabiA010001005.port.T = TsCABI0CabiA010001005.port.T; TsCABI0CabiA009001005.port.Q_flow + (TC_269_270.port_b.Q_flow + (CABI0CabiA009001005.port.Q_flow + (TC_270_271.port_a.Q_flow + (TC_270_324.port_a.Q_flow + (TC_270_433.port_a.Q_flow + (TC_270_1106.port_a.Q_flow + TC_270_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009001005.port.T = TC_269_270.port_b.T; CABI0CabiA009001005.port.T = TC_270_0.port_a.T; CABI0CabiA009001005.port.T = TC_270_1106.port_a.T; CABI0CabiA009001005.port.T = TC_270_271.port_a.T; CABI0CabiA009001005.port.T = TC_270_324.port_a.T; CABI0CabiA009001005.port.T = TC_270_433.port_a.T; CABI0CabiA009001005.port.T = TsCABI0CabiA009001005.port.T; TsCABI0CabiA008001005.port.Q_flow + (TC_268_269.port_b.Q_flow + (CABI0CabiA008001005.port.Q_flow + (TC_269_270.port_a.Q_flow + (TC_269_323.port_a.Q_flow + (TC_269_432.port_a.Q_flow + (TC_269_1105.port_a.Q_flow + TC_269_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008001005.port.T = TC_268_269.port_b.T; CABI0CabiA008001005.port.T = TC_269_0.port_a.T; CABI0CabiA008001005.port.T = TC_269_1105.port_a.T; CABI0CabiA008001005.port.T = TC_269_270.port_a.T; CABI0CabiA008001005.port.T = TC_269_323.port_a.T; CABI0CabiA008001005.port.T = TC_269_432.port_a.T; CABI0CabiA008001005.port.T = TsCABI0CabiA008001005.port.T; TsCABI0CabiA007001005.port.Q_flow + (TC_267_268.port_b.Q_flow + (CABI0CabiA007001005.port.Q_flow + (TC_268_269.port_a.Q_flow + (TC_268_322.port_a.Q_flow + (TC_268_431.port_a.Q_flow + (TC_268_1104.port_a.Q_flow + TC_268_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007001005.port.T = TC_267_268.port_b.T; CABI0CabiA007001005.port.T = TC_268_0.port_a.T; CABI0CabiA007001005.port.T = TC_268_1104.port_a.T; CABI0CabiA007001005.port.T = TC_268_269.port_a.T; CABI0CabiA007001005.port.T = TC_268_322.port_a.T; CABI0CabiA007001005.port.T = TC_268_431.port_a.T; CABI0CabiA007001005.port.T = TsCABI0CabiA007001005.port.T; TsCABI0CabiA006001005.port.Q_flow + (TC_266_267.port_b.Q_flow + (CABI0CabiA006001005.port.Q_flow + (TC_267_268.port_a.Q_flow + (TC_267_321.port_a.Q_flow + (TC_267_430.port_a.Q_flow + (TC_267_1103.port_a.Q_flow + TC_267_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006001005.port.T = TC_266_267.port_b.T; CABI0CabiA006001005.port.T = TC_267_0.port_a.T; CABI0CabiA006001005.port.T = TC_267_1103.port_a.T; CABI0CabiA006001005.port.T = TC_267_268.port_a.T; CABI0CabiA006001005.port.T = TC_267_321.port_a.T; CABI0CabiA006001005.port.T = TC_267_430.port_a.T; CABI0CabiA006001005.port.T = TsCABI0CabiA006001005.port.T; TsCABI0CabiA005001005.port.Q_flow + (TC_265_266.port_b.Q_flow + (CABI0CabiA005001005.port.Q_flow + (TC_266_267.port_a.Q_flow + (TC_266_320.port_a.Q_flow + (TC_266_429.port_a.Q_flow + (TC_266_1102.port_a.Q_flow + TC_266_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005001005.port.T = TC_265_266.port_b.T; CABI0CabiA005001005.port.T = TC_266_0.port_a.T; CABI0CabiA005001005.port.T = TC_266_1102.port_a.T; CABI0CabiA005001005.port.T = TC_266_267.port_a.T; CABI0CabiA005001005.port.T = TC_266_320.port_a.T; CABI0CabiA005001005.port.T = TC_266_429.port_a.T; CABI0CabiA005001005.port.T = TsCABI0CabiA005001005.port.T; TsCABI0CabiA004001005.port.Q_flow + (TC_264_265.port_b.Q_flow + (CABI0CabiA004001005.port.Q_flow + (TC_265_266.port_a.Q_flow + (TC_265_319.port_a.Q_flow + (TC_265_428.port_a.Q_flow + (TC_265_1101.port_a.Q_flow + TC_265_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004001005.port.T = TC_264_265.port_b.T; CABI0CabiA004001005.port.T = TC_265_0.port_a.T; CABI0CabiA004001005.port.T = TC_265_1101.port_a.T; CABI0CabiA004001005.port.T = TC_265_266.port_a.T; CABI0CabiA004001005.port.T = TC_265_319.port_a.T; CABI0CabiA004001005.port.T = TC_265_428.port_a.T; CABI0CabiA004001005.port.T = TsCABI0CabiA004001005.port.T; TsCABI0CabiA003001005.port.Q_flow + (TC_263_264.port_b.Q_flow + (CABI0CabiA003001005.port.Q_flow + (TC_264_265.port_a.Q_flow + (TC_264_318.port_a.Q_flow + (TC_264_427.port_a.Q_flow + (TC_264_1100.port_a.Q_flow + TC_264_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003001005.port.T = TC_263_264.port_b.T; CABI0CabiA003001005.port.T = TC_264_0.port_a.T; CABI0CabiA003001005.port.T = TC_264_1100.port_a.T; CABI0CabiA003001005.port.T = TC_264_265.port_a.T; CABI0CabiA003001005.port.T = TC_264_318.port_a.T; CABI0CabiA003001005.port.T = TC_264_427.port_a.T; CABI0CabiA003001005.port.T = TsCABI0CabiA003001005.port.T; TsCABI0CabiA002001005.port.Q_flow + (TC_262_263.port_b.Q_flow + (CABI0CabiA002001005.port.Q_flow + (TC_263_264.port_a.Q_flow + (TC_263_317.port_a.Q_flow + (TC_263_426.port_a.Q_flow + (TC_263_1099.port_a.Q_flow + TC_263_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002001005.port.T = TC_262_263.port_b.T; CABI0CabiA002001005.port.T = TC_263_0.port_a.T; CABI0CabiA002001005.port.T = TC_263_1099.port_a.T; CABI0CabiA002001005.port.T = TC_263_264.port_a.T; CABI0CabiA002001005.port.T = TC_263_317.port_a.T; CABI0CabiA002001005.port.T = TC_263_426.port_a.T; CABI0CabiA002001005.port.T = TsCABI0CabiA002001005.port.T; TsCABI0CabiA001001005.port.Q_flow + (CABI0CabiA001001005.port.Q_flow + (TC_262_263.port_a.Q_flow + (TC_262_275.port_a.Q_flow + (TC_262_316.port_a.Q_flow + (TC_262_425.port_a.Q_flow + TC_262_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001001005.port.T = TC_262_0.port_a.T; CABI0CabiA001001005.port.T = TC_262_263.port_a.T; CABI0CabiA001001005.port.T = TC_262_275.port_a.T; CABI0CabiA001001005.port.T = TC_262_316.port_a.T; CABI0CabiA001001005.port.T = TC_262_425.port_a.T; CABI0CabiA001001005.port.T = TsCABI0CabiA001001005.port.T; TsCABI0CabiA013016002.port.Q_flow + (TC_260_261.port_b.Q_flow + (TC_248_261.port_b.Q_flow + (TC_208_261.port_b.Q_flow + (CABI0CabiA013016002.port.Q_flow + (TC_261_423.port_a.Q_flow + TC_261_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013016002.port.T = TC_208_261.port_b.T; CABI0CabiA013016002.port.T = TC_248_261.port_b.T; CABI0CabiA013016002.port.T = TC_260_261.port_b.T; CABI0CabiA013016002.port.T = TC_261_0.port_a.T; CABI0CabiA013016002.port.T = TC_261_423.port_a.T; CABI0CabiA013016002.port.T = TsCABI0CabiA013016002.port.T; TsCABI0CabiA012016002.port.Q_flow + (TC_259_260.port_b.Q_flow + (TC_207_260.port_b.Q_flow + (CABI0CabiA012016002.port.Q_flow + (TC_260_261.port_a.Q_flow + (TC_260_422.port_a.Q_flow + (TC_260_1460.port_a.Q_flow + TC_260_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012016002.port.T = TC_207_260.port_b.T; CABI0CabiA012016002.port.T = TC_259_260.port_b.T; CABI0CabiA012016002.port.T = TC_260_0.port_a.T; CABI0CabiA012016002.port.T = TC_260_1460.port_a.T; CABI0CabiA012016002.port.T = TC_260_261.port_a.T; CABI0CabiA012016002.port.T = TC_260_422.port_a.T; CABI0CabiA012016002.port.T = TsCABI0CabiA012016002.port.T; TsCABI0CabiA011016002.port.Q_flow + (TC_258_259.port_b.Q_flow + (TC_206_259.port_b.Q_flow + (CABI0CabiA011016002.port.Q_flow + (TC_259_260.port_a.Q_flow + (TC_259_421.port_a.Q_flow + (TC_259_1459.port_a.Q_flow + TC_259_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011016002.port.T = TC_206_259.port_b.T; CABI0CabiA011016002.port.T = TC_258_259.port_b.T; CABI0CabiA011016002.port.T = TC_259_0.port_a.T; CABI0CabiA011016002.port.T = TC_259_1459.port_a.T; CABI0CabiA011016002.port.T = TC_259_260.port_a.T; CABI0CabiA011016002.port.T = TC_259_421.port_a.T; CABI0CabiA011016002.port.T = TsCABI0CabiA011016002.port.T; TsCABI0CabiA010016002.port.Q_flow + (TC_257_258.port_b.Q_flow + (TC_205_258.port_b.Q_flow + (CABI0CabiA010016002.port.Q_flow + (TC_258_259.port_a.Q_flow + (TC_258_420.port_a.Q_flow + (TC_258_1458.port_a.Q_flow + TC_258_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010016002.port.T = TC_205_258.port_b.T; CABI0CabiA010016002.port.T = TC_257_258.port_b.T; CABI0CabiA010016002.port.T = TC_258_0.port_a.T; CABI0CabiA010016002.port.T = TC_258_1458.port_a.T; CABI0CabiA010016002.port.T = TC_258_259.port_a.T; CABI0CabiA010016002.port.T = TC_258_420.port_a.T; CABI0CabiA010016002.port.T = TsCABI0CabiA010016002.port.T; TsCABI0CabiA009016002.port.Q_flow + (TC_256_257.port_b.Q_flow + (TC_204_257.port_b.Q_flow + (CABI0CabiA009016002.port.Q_flow + (TC_257_258.port_a.Q_flow + (TC_257_419.port_a.Q_flow + (TC_257_1457.port_a.Q_flow + TC_257_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009016002.port.T = TC_204_257.port_b.T; CABI0CabiA009016002.port.T = TC_256_257.port_b.T; CABI0CabiA009016002.port.T = TC_257_0.port_a.T; CABI0CabiA009016002.port.T = TC_257_1457.port_a.T; CABI0CabiA009016002.port.T = TC_257_258.port_a.T; CABI0CabiA009016002.port.T = TC_257_419.port_a.T; CABI0CabiA009016002.port.T = TsCABI0CabiA009016002.port.T; TsCABI0CabiA008016002.port.Q_flow + (TC_255_256.port_b.Q_flow + (TC_203_256.port_b.Q_flow + (CABI0CabiA008016002.port.Q_flow + (TC_256_257.port_a.Q_flow + (TC_256_418.port_a.Q_flow + (TC_256_1456.port_a.Q_flow + TC_256_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008016002.port.T = TC_203_256.port_b.T; CABI0CabiA008016002.port.T = TC_255_256.port_b.T; CABI0CabiA008016002.port.T = TC_256_0.port_a.T; CABI0CabiA008016002.port.T = TC_256_1456.port_a.T; CABI0CabiA008016002.port.T = TC_256_257.port_a.T; CABI0CabiA008016002.port.T = TC_256_418.port_a.T; CABI0CabiA008016002.port.T = TsCABI0CabiA008016002.port.T; TsCABI0CabiA007016002.port.Q_flow + (TC_254_255.port_b.Q_flow + (TC_202_255.port_b.Q_flow + (CABI0CabiA007016002.port.Q_flow + (TC_255_256.port_a.Q_flow + (TC_255_417.port_a.Q_flow + (TC_255_1455.port_a.Q_flow + TC_255_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007016002.port.T = TC_202_255.port_b.T; CABI0CabiA007016002.port.T = TC_254_255.port_b.T; CABI0CabiA007016002.port.T = TC_255_0.port_a.T; CABI0CabiA007016002.port.T = TC_255_1455.port_a.T; CABI0CabiA007016002.port.T = TC_255_256.port_a.T; CABI0CabiA007016002.port.T = TC_255_417.port_a.T; CABI0CabiA007016002.port.T = TsCABI0CabiA007016002.port.T; TsCABI0CabiA006016002.port.Q_flow + (TC_253_254.port_b.Q_flow + (TC_201_254.port_b.Q_flow + (CABI0CabiA006016002.port.Q_flow + (TC_254_255.port_a.Q_flow + (TC_254_416.port_a.Q_flow + (TC_254_1454.port_a.Q_flow + TC_254_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006016002.port.T = TC_201_254.port_b.T; CABI0CabiA006016002.port.T = TC_253_254.port_b.T; CABI0CabiA006016002.port.T = TC_254_0.port_a.T; CABI0CabiA006016002.port.T = TC_254_1454.port_a.T; CABI0CabiA006016002.port.T = TC_254_255.port_a.T; CABI0CabiA006016002.port.T = TC_254_416.port_a.T; CABI0CabiA006016002.port.T = TsCABI0CabiA006016002.port.T; TsCABI0CabiA005016002.port.Q_flow + (TC_252_253.port_b.Q_flow + (TC_200_253.port_b.Q_flow + (CABI0CabiA005016002.port.Q_flow + (TC_253_254.port_a.Q_flow + (TC_253_415.port_a.Q_flow + (TC_253_1453.port_a.Q_flow + TC_253_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005016002.port.T = TC_200_253.port_b.T; CABI0CabiA005016002.port.T = TC_252_253.port_b.T; CABI0CabiA005016002.port.T = TC_253_0.port_a.T; CABI0CabiA005016002.port.T = TC_253_1453.port_a.T; CABI0CabiA005016002.port.T = TC_253_254.port_a.T; CABI0CabiA005016002.port.T = TC_253_415.port_a.T; CABI0CabiA005016002.port.T = TsCABI0CabiA005016002.port.T; TsCABI0CabiA004016002.port.Q_flow + (TC_251_252.port_b.Q_flow + (TC_199_252.port_b.Q_flow + (CABI0CabiA004016002.port.Q_flow + (TC_252_253.port_a.Q_flow + (TC_252_414.port_a.Q_flow + (TC_252_1452.port_a.Q_flow + TC_252_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004016002.port.T = TC_199_252.port_b.T; CABI0CabiA004016002.port.T = TC_251_252.port_b.T; CABI0CabiA004016002.port.T = TC_252_0.port_a.T; CABI0CabiA004016002.port.T = TC_252_1452.port_a.T; CABI0CabiA004016002.port.T = TC_252_253.port_a.T; CABI0CabiA004016002.port.T = TC_252_414.port_a.T; CABI0CabiA004016002.port.T = TsCABI0CabiA004016002.port.T; TsCABI0CabiA003016002.port.Q_flow + (TC_250_251.port_b.Q_flow + (TC_198_251.port_b.Q_flow + (CABI0CabiA003016002.port.Q_flow + (TC_251_252.port_a.Q_flow + (TC_251_413.port_a.Q_flow + (TC_251_1451.port_a.Q_flow + TC_251_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003016002.port.T = TC_198_251.port_b.T; CABI0CabiA003016002.port.T = TC_250_251.port_b.T; CABI0CabiA003016002.port.T = TC_251_0.port_a.T; CABI0CabiA003016002.port.T = TC_251_1451.port_a.T; CABI0CabiA003016002.port.T = TC_251_252.port_a.T; CABI0CabiA003016002.port.T = TC_251_413.port_a.T; CABI0CabiA003016002.port.T = TsCABI0CabiA003016002.port.T; TsCABI0CabiA002016002.port.Q_flow + (TC_249_250.port_b.Q_flow + (TC_197_250.port_b.Q_flow + (CABI0CabiA002016002.port.Q_flow + (TC_250_251.port_a.Q_flow + (TC_250_412.port_a.Q_flow + (TC_250_1450.port_a.Q_flow + TC_250_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002016002.port.T = TC_197_250.port_b.T; CABI0CabiA002016002.port.T = TC_249_250.port_b.T; CABI0CabiA002016002.port.T = TC_250_0.port_a.T; CABI0CabiA002016002.port.T = TC_250_1450.port_a.T; CABI0CabiA002016002.port.T = TC_250_251.port_a.T; CABI0CabiA002016002.port.T = TC_250_412.port_a.T; CABI0CabiA002016002.port.T = TsCABI0CabiA002016002.port.T; TsCABI0CabiA001016002.port.Q_flow + (TC_247_249.port_b.Q_flow + (TC_196_249.port_b.Q_flow + (CABI0CabiA001016002.port.Q_flow + (TC_249_250.port_a.Q_flow + (TC_249_411.port_a.Q_flow + TC_249_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001016002.port.T = TC_196_249.port_b.T; CABI0CabiA001016002.port.T = TC_247_249.port_b.T; CABI0CabiA001016002.port.T = TC_249_0.port_a.T; CABI0CabiA001016002.port.T = TC_249_250.port_a.T; CABI0CabiA001016002.port.T = TC_249_411.port_a.T; CABI0CabiA001016002.port.T = TsCABI0CabiA001016002.port.T; TsCABI0CabiA013015002.port.Q_flow + (TC_246_248.port_b.Q_flow + (TC_195_248.port_b.Q_flow + (CABI0CabiA013015002.port.Q_flow + (TC_248_261.port_a.Q_flow + (TC_248_410.port_a.Q_flow + (TC_248_1460.port_a.Q_flow + TC_248_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013015002.port.T = TC_195_248.port_b.T; CABI0CabiA013015002.port.T = TC_246_248.port_b.T; CABI0CabiA013015002.port.T = TC_248_0.port_a.T; CABI0CabiA013015002.port.T = TC_248_1460.port_a.T; CABI0CabiA013015002.port.T = TC_248_261.port_a.T; CABI0CabiA013015002.port.T = TC_248_410.port_a.T; CABI0CabiA013015002.port.T = TsCABI0CabiA013015002.port.T; TsCABI0CabiA001015002.port.Q_flow + (TC_245_247.port_b.Q_flow + (TC_183_247.port_b.Q_flow + (CABI0CabiA001015002.port.Q_flow + (TC_247_249.port_a.Q_flow + (TC_247_409.port_a.Q_flow + (TC_247_1450.port_a.Q_flow + TC_247_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001015002.port.T = TC_183_247.port_b.T; CABI0CabiA001015002.port.T = TC_245_247.port_b.T; CABI0CabiA001015002.port.T = TC_247_0.port_a.T; CABI0CabiA001015002.port.T = TC_247_1450.port_a.T; CABI0CabiA001015002.port.T = TC_247_249.port_a.T; CABI0CabiA001015002.port.T = TC_247_409.port_a.T; CABI0CabiA001015002.port.T = TsCABI0CabiA001015002.port.T; TsCABI0CabiA013014002.port.Q_flow + (TC_244_246.port_b.Q_flow + (TC_182_246.port_b.Q_flow + (CABI0CabiA013014002.port.Q_flow + (TC_246_248.port_a.Q_flow + (TC_246_408.port_a.Q_flow + (TC_246_1449.port_a.Q_flow + TC_246_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013014002.port.T = TC_182_246.port_b.T; CABI0CabiA013014002.port.T = TC_244_246.port_b.T; CABI0CabiA013014002.port.T = TC_246_0.port_a.T; CABI0CabiA013014002.port.T = TC_246_1449.port_a.T; CABI0CabiA013014002.port.T = TC_246_248.port_a.T; CABI0CabiA013014002.port.T = TC_246_408.port_a.T; CABI0CabiA013014002.port.T = TsCABI0CabiA013014002.port.T; TsCABI0CabiA001014002.port.Q_flow + (TC_243_245.port_b.Q_flow + (TC_170_245.port_b.Q_flow + (CABI0CabiA001014002.port.Q_flow + (TC_245_247.port_a.Q_flow + (TC_245_407.port_a.Q_flow + (TC_245_1439.port_a.Q_flow + TC_245_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001014002.port.T = TC_170_245.port_b.T; CABI0CabiA001014002.port.T = TC_243_245.port_b.T; CABI0CabiA001014002.port.T = TC_245_0.port_a.T; CABI0CabiA001014002.port.T = TC_245_1439.port_a.T; CABI0CabiA001014002.port.T = TC_245_247.port_a.T; CABI0CabiA001014002.port.T = TC_245_407.port_a.T; CABI0CabiA001014002.port.T = TsCABI0CabiA001014002.port.T; TsCABI0CabiA013013002.port.Q_flow + (TC_242_244.port_b.Q_flow + (TC_169_244.port_b.Q_flow + (CABI0CabiA013013002.port.Q_flow + (TC_244_246.port_a.Q_flow + (TC_244_406.port_a.Q_flow + (TC_244_1438.port_a.Q_flow + TC_244_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013013002.port.T = TC_169_244.port_b.T; CABI0CabiA013013002.port.T = TC_242_244.port_b.T; CABI0CabiA013013002.port.T = TC_244_0.port_a.T; CABI0CabiA013013002.port.T = TC_244_1438.port_a.T; CABI0CabiA013013002.port.T = TC_244_246.port_a.T; CABI0CabiA013013002.port.T = TC_244_406.port_a.T; CABI0CabiA013013002.port.T = TsCABI0CabiA013013002.port.T; TsCABI0CabiA001013002.port.Q_flow + (TC_241_243.port_b.Q_flow + (TC_157_243.port_b.Q_flow + (CABI0CabiA001013002.port.Q_flow + (TC_243_245.port_a.Q_flow + (TC_243_405.port_a.Q_flow + (TC_243_1436.port_a.Q_flow + TC_243_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001013002.port.T = TC_157_243.port_b.T; CABI0CabiA001013002.port.T = TC_241_243.port_b.T; CABI0CabiA001013002.port.T = TC_243_0.port_a.T; CABI0CabiA001013002.port.T = TC_243_1436.port_a.T; CABI0CabiA001013002.port.T = TC_243_245.port_a.T; CABI0CabiA001013002.port.T = TC_243_405.port_a.T; CABI0CabiA001013002.port.T = TsCABI0CabiA001013002.port.T; TsCABI0CabiA013012002.port.Q_flow + (TC_240_242.port_b.Q_flow + (TC_156_242.port_b.Q_flow + (CABI0CabiA013012002.port.Q_flow + (TC_242_244.port_a.Q_flow + (TC_242_404.port_a.Q_flow + (TC_242_1435.port_a.Q_flow + TC_242_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013012002.port.T = TC_156_242.port_b.T; CABI0CabiA013012002.port.T = TC_240_242.port_b.T; CABI0CabiA013012002.port.T = TC_242_0.port_a.T; CABI0CabiA013012002.port.T = TC_242_1435.port_a.T; CABI0CabiA013012002.port.T = TC_242_244.port_a.T; CABI0CabiA013012002.port.T = TC_242_404.port_a.T; CABI0CabiA013012002.port.T = TsCABI0CabiA013012002.port.T; TsCABI0CabiA001012002.port.Q_flow + (TC_239_241.port_b.Q_flow + (TC_144_241.port_b.Q_flow + (CABI0CabiA001012002.port.Q_flow + (TC_241_243.port_a.Q_flow + (TC_241_403.port_a.Q_flow + (TC_241_1433.port_a.Q_flow + TC_241_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001012002.port.T = TC_144_241.port_b.T; CABI0CabiA001012002.port.T = TC_239_241.port_b.T; CABI0CabiA001012002.port.T = TC_241_0.port_a.T; CABI0CabiA001012002.port.T = TC_241_1433.port_a.T; CABI0CabiA001012002.port.T = TC_241_243.port_a.T; CABI0CabiA001012002.port.T = TC_241_403.port_a.T; CABI0CabiA001012002.port.T = TsCABI0CabiA001012002.port.T; TsCABI0CabiA013011002.port.Q_flow + (TC_238_240.port_b.Q_flow + (TC_143_240.port_b.Q_flow + (CABI0CabiA013011002.port.Q_flow + (TC_240_242.port_a.Q_flow + (TC_240_402.port_a.Q_flow + (TC_240_1432.port_a.Q_flow + TC_240_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013011002.port.T = TC_143_240.port_b.T; CABI0CabiA013011002.port.T = TC_238_240.port_b.T; CABI0CabiA013011002.port.T = TC_240_0.port_a.T; CABI0CabiA013011002.port.T = TC_240_1432.port_a.T; CABI0CabiA013011002.port.T = TC_240_242.port_a.T; CABI0CabiA013011002.port.T = TC_240_402.port_a.T; CABI0CabiA013011002.port.T = TsCABI0CabiA013011002.port.T; TsCABI0CabiA001011002.port.Q_flow + (TC_237_239.port_b.Q_flow + (TC_131_239.port_b.Q_flow + (CABI0CabiA001011002.port.Q_flow + (TC_239_241.port_a.Q_flow + (TC_239_401.port_a.Q_flow + (TC_239_1430.port_a.Q_flow + TC_239_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001011002.port.T = TC_131_239.port_b.T; CABI0CabiA001011002.port.T = TC_237_239.port_b.T; CABI0CabiA001011002.port.T = TC_239_0.port_a.T; CABI0CabiA001011002.port.T = TC_239_1430.port_a.T; CABI0CabiA001011002.port.T = TC_239_241.port_a.T; CABI0CabiA001011002.port.T = TC_239_401.port_a.T; CABI0CabiA001011002.port.T = TsCABI0CabiA001011002.port.T; TsCABI0CabiA013010002.port.Q_flow + (TC_236_238.port_b.Q_flow + (TC_130_238.port_b.Q_flow + (CABI0CabiA013010002.port.Q_flow + (TC_238_240.port_a.Q_flow + (TC_238_400.port_a.Q_flow + (TC_238_1429.port_a.Q_flow + TC_238_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013010002.port.T = TC_130_238.port_b.T; CABI0CabiA013010002.port.T = TC_236_238.port_b.T; CABI0CabiA013010002.port.T = TC_238_0.port_a.T; CABI0CabiA013010002.port.T = TC_238_1429.port_a.T; CABI0CabiA013010002.port.T = TC_238_240.port_a.T; CABI0CabiA013010002.port.T = TC_238_400.port_a.T; CABI0CabiA013010002.port.T = TsCABI0CabiA013010002.port.T; TsCABI0CabiA001010002.port.Q_flow + (TC_235_237.port_b.Q_flow + (TC_118_237.port_b.Q_flow + (CABI0CabiA001010002.port.Q_flow + (TC_237_239.port_a.Q_flow + (TC_237_399.port_a.Q_flow + (TC_237_1427.port_a.Q_flow + TC_237_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001010002.port.T = TC_118_237.port_b.T; CABI0CabiA001010002.port.T = TC_235_237.port_b.T; CABI0CabiA001010002.port.T = TC_237_0.port_a.T; CABI0CabiA001010002.port.T = TC_237_1427.port_a.T; CABI0CabiA001010002.port.T = TC_237_239.port_a.T; CABI0CabiA001010002.port.T = TC_237_399.port_a.T; CABI0CabiA001010002.port.T = TsCABI0CabiA001010002.port.T; TsCABI0CabiA013009002.port.Q_flow + (TC_234_236.port_b.Q_flow + (TC_117_236.port_b.Q_flow + (CABI0CabiA013009002.port.Q_flow + (TC_236_238.port_a.Q_flow + (TC_236_398.port_a.Q_flow + (TC_236_1426.port_a.Q_flow + TC_236_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013009002.port.T = TC_117_236.port_b.T; CABI0CabiA013009002.port.T = TC_234_236.port_b.T; CABI0CabiA013009002.port.T = TC_236_0.port_a.T; CABI0CabiA013009002.port.T = TC_236_1426.port_a.T; CABI0CabiA013009002.port.T = TC_236_238.port_a.T; CABI0CabiA013009002.port.T = TC_236_398.port_a.T; CABI0CabiA013009002.port.T = TsCABI0CabiA013009002.port.T; TsCABI0CabiA001009002.port.Q_flow + (TC_233_235.port_b.Q_flow + (TC_105_235.port_b.Q_flow + (CABI0CabiA001009002.port.Q_flow + (TC_235_237.port_a.Q_flow + (TC_235_397.port_a.Q_flow + (TC_235_1424.port_a.Q_flow + TC_235_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001009002.port.T = TC_105_235.port_b.T; CABI0CabiA001009002.port.T = TC_233_235.port_b.T; CABI0CabiA001009002.port.T = TC_235_0.port_a.T; CABI0CabiA001009002.port.T = TC_235_1424.port_a.T; CABI0CabiA001009002.port.T = TC_235_237.port_a.T; CABI0CabiA001009002.port.T = TC_235_397.port_a.T; CABI0CabiA001009002.port.T = TsCABI0CabiA001009002.port.T; TsCABI0CabiA013008002.port.Q_flow + (TC_232_234.port_b.Q_flow + (TC_104_234.port_b.Q_flow + (CABI0CabiA013008002.port.Q_flow + (TC_234_236.port_a.Q_flow + (TC_234_396.port_a.Q_flow + (TC_234_1423.port_a.Q_flow + TC_234_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013008002.port.T = TC_104_234.port_b.T; CABI0CabiA013008002.port.T = TC_232_234.port_b.T; CABI0CabiA013008002.port.T = TC_234_0.port_a.T; CABI0CabiA013008002.port.T = TC_234_1423.port_a.T; CABI0CabiA013008002.port.T = TC_234_236.port_a.T; CABI0CabiA013008002.port.T = TC_234_396.port_a.T; CABI0CabiA013008002.port.T = TsCABI0CabiA013008002.port.T; TsCABI0CabiA001008002.port.Q_flow + (TC_231_233.port_b.Q_flow + (TC_92_233.port_b.Q_flow + (CABI0CabiA001008002.port.Q_flow + (TC_233_235.port_a.Q_flow + (TC_233_395.port_a.Q_flow + (TC_233_1421.port_a.Q_flow + TC_233_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001008002.port.T = TC_231_233.port_b.T; CABI0CabiA001008002.port.T = TC_233_0.port_a.T; CABI0CabiA001008002.port.T = TC_233_1421.port_a.T; CABI0CabiA001008002.port.T = TC_233_235.port_a.T; CABI0CabiA001008002.port.T = TC_233_395.port_a.T; CABI0CabiA001008002.port.T = TC_92_233.port_b.T; CABI0CabiA001008002.port.T = TsCABI0CabiA001008002.port.T; TsCABI0CabiA013007002.port.Q_flow + (TC_230_232.port_b.Q_flow + (TC_91_232.port_b.Q_flow + (CABI0CabiA013007002.port.Q_flow + (TC_232_234.port_a.Q_flow + (TC_232_394.port_a.Q_flow + (TC_232_1420.port_a.Q_flow + TC_232_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013007002.port.T = TC_230_232.port_b.T; CABI0CabiA013007002.port.T = TC_232_0.port_a.T; CABI0CabiA013007002.port.T = TC_232_1420.port_a.T; CABI0CabiA013007002.port.T = TC_232_234.port_a.T; CABI0CabiA013007002.port.T = TC_232_394.port_a.T; CABI0CabiA013007002.port.T = TC_91_232.port_b.T; CABI0CabiA013007002.port.T = TsCABI0CabiA013007002.port.T; TsCABI0CabiA001007002.port.Q_flow + (TC_229_231.port_b.Q_flow + (TC_79_231.port_b.Q_flow + (CABI0CabiA001007002.port.Q_flow + (TC_231_233.port_a.Q_flow + (TC_231_393.port_a.Q_flow + (TC_231_1418.port_a.Q_flow + TC_231_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001007002.port.T = TC_229_231.port_b.T; CABI0CabiA001007002.port.T = TC_231_0.port_a.T; CABI0CabiA001007002.port.T = TC_231_1418.port_a.T; CABI0CabiA001007002.port.T = TC_231_233.port_a.T; CABI0CabiA001007002.port.T = TC_231_393.port_a.T; CABI0CabiA001007002.port.T = TC_79_231.port_b.T; CABI0CabiA001007002.port.T = TsCABI0CabiA001007002.port.T; TsCABI0CabiA013006002.port.Q_flow + (TC_228_230.port_b.Q_flow + (TC_78_230.port_b.Q_flow + (CABI0CabiA013006002.port.Q_flow + (TC_230_232.port_a.Q_flow + (TC_230_392.port_a.Q_flow + (TC_230_1417.port_a.Q_flow + TC_230_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013006002.port.T = TC_228_230.port_b.T; CABI0CabiA013006002.port.T = TC_230_0.port_a.T; CABI0CabiA013006002.port.T = TC_230_1417.port_a.T; CABI0CabiA013006002.port.T = TC_230_232.port_a.T; CABI0CabiA013006002.port.T = TC_230_392.port_a.T; CABI0CabiA013006002.port.T = TC_78_230.port_b.T; CABI0CabiA013006002.port.T = TsCABI0CabiA013006002.port.T; TsCABI0CabiA001006002.port.Q_flow + (TC_227_229.port_b.Q_flow + (TC_66_229.port_b.Q_flow + (CABI0CabiA001006002.port.Q_flow + (TC_229_231.port_a.Q_flow + (TC_229_391.port_a.Q_flow + (TC_229_1415.port_a.Q_flow + TC_229_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001006002.port.T = TC_227_229.port_b.T; CABI0CabiA001006002.port.T = TC_229_0.port_a.T; CABI0CabiA001006002.port.T = TC_229_1415.port_a.T; CABI0CabiA001006002.port.T = TC_229_231.port_a.T; CABI0CabiA001006002.port.T = TC_229_391.port_a.T; CABI0CabiA001006002.port.T = TC_66_229.port_b.T; CABI0CabiA001006002.port.T = TsCABI0CabiA001006002.port.T; TsCABI0CabiA013005002.port.Q_flow + (TC_226_228.port_b.Q_flow + (TC_65_228.port_b.Q_flow + (CABI0CabiA013005002.port.Q_flow + (TC_228_230.port_a.Q_flow + (TC_228_390.port_a.Q_flow + (TC_228_1414.port_a.Q_flow + TC_228_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013005002.port.T = TC_226_228.port_b.T; CABI0CabiA013005002.port.T = TC_228_0.port_a.T; CABI0CabiA013005002.port.T = TC_228_1414.port_a.T; CABI0CabiA013005002.port.T = TC_228_230.port_a.T; CABI0CabiA013005002.port.T = TC_228_390.port_a.T; CABI0CabiA013005002.port.T = TC_65_228.port_b.T; CABI0CabiA013005002.port.T = TsCABI0CabiA013005002.port.T; TsCABI0CabiA001005002.port.Q_flow + (TC_225_227.port_b.Q_flow + (TC_53_227.port_b.Q_flow + (CABI0CabiA001005002.port.Q_flow + (TC_227_229.port_a.Q_flow + (TC_227_389.port_a.Q_flow + (TC_227_1464.port_a.Q_flow + TC_227_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001005002.port.T = TC_225_227.port_b.T; CABI0CabiA001005002.port.T = TC_227_0.port_a.T; CABI0CabiA001005002.port.T = TC_227_1464.port_a.T; CABI0CabiA001005002.port.T = TC_227_229.port_a.T; CABI0CabiA001005002.port.T = TC_227_389.port_a.T; CABI0CabiA001005002.port.T = TC_53_227.port_b.T; CABI0CabiA001005002.port.T = TsCABI0CabiA001005002.port.T; TsCABI0CabiA013004002.port.Q_flow + (TC_224_226.port_b.Q_flow + (TC_52_226.port_b.Q_flow + (CABI0CabiA013004002.port.Q_flow + (TC_226_228.port_a.Q_flow + (TC_226_388.port_a.Q_flow + (TC_226_1463.port_a.Q_flow + TC_226_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013004002.port.T = TC_224_226.port_b.T; CABI0CabiA013004002.port.T = TC_226_0.port_a.T; CABI0CabiA013004002.port.T = TC_226_1463.port_a.T; CABI0CabiA013004002.port.T = TC_226_228.port_a.T; CABI0CabiA013004002.port.T = TC_226_388.port_a.T; CABI0CabiA013004002.port.T = TC_52_226.port_b.T; CABI0CabiA013004002.port.T = TsCABI0CabiA013004002.port.T; TsCABI0CabiA001004002.port.Q_flow + (TC_223_225.port_b.Q_flow + (TC_40_225.port_b.Q_flow + (CABI0CabiA001004002.port.Q_flow + (TC_225_227.port_a.Q_flow + (TC_225_387.port_a.Q_flow + (TC_225_1461.port_a.Q_flow + TC_225_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001004002.port.T = TC_223_225.port_b.T; CABI0CabiA001004002.port.T = TC_225_0.port_a.T; CABI0CabiA001004002.port.T = TC_225_1461.port_a.T; CABI0CabiA001004002.port.T = TC_225_227.port_a.T; CABI0CabiA001004002.port.T = TC_225_387.port_a.T; CABI0CabiA001004002.port.T = TC_40_225.port_b.T; CABI0CabiA001004002.port.T = TsCABI0CabiA001004002.port.T; TsCABI0CabiA013003002.port.Q_flow + (TC_222_224.port_b.Q_flow + (TC_39_224.port_b.Q_flow + (CABI0CabiA013003002.port.Q_flow + (TC_224_226.port_a.Q_flow + (TC_224_386.port_a.Q_flow + (TC_224_1476.port_a.Q_flow + TC_224_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013003002.port.T = TC_222_224.port_b.T; CABI0CabiA013003002.port.T = TC_224_0.port_a.T; CABI0CabiA013003002.port.T = TC_224_1476.port_a.T; CABI0CabiA013003002.port.T = TC_224_226.port_a.T; CABI0CabiA013003002.port.T = TC_224_386.port_a.T; CABI0CabiA013003002.port.T = TC_39_224.port_b.T; CABI0CabiA013003002.port.T = TsCABI0CabiA013003002.port.T; TsCABI0CabiA001003002.port.Q_flow + (TC_221_223.port_b.Q_flow + (TC_27_223.port_b.Q_flow + (CABI0CabiA001003002.port.Q_flow + (TC_223_225.port_a.Q_flow + (TC_223_385.port_a.Q_flow + (TC_223_1466.port_a.Q_flow + TC_223_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001003002.port.T = TC_221_223.port_b.T; CABI0CabiA001003002.port.T = TC_223_0.port_a.T; CABI0CabiA001003002.port.T = TC_223_1466.port_a.T; CABI0CabiA001003002.port.T = TC_223_225.port_a.T; CABI0CabiA001003002.port.T = TC_223_385.port_a.T; CABI0CabiA001003002.port.T = TC_27_223.port_b.T; CABI0CabiA001003002.port.T = TsCABI0CabiA001003002.port.T; TsCABI0CabiA013002002.port.Q_flow + (TC_220_222.port_b.Q_flow + (TC_26_222.port_b.Q_flow + (CABI0CabiA013002002.port.Q_flow + (TC_222_224.port_a.Q_flow + (TC_222_384.port_a.Q_flow + (TC_222_1487.port_a.Q_flow + TC_222_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA013002002.port.T = TC_220_222.port_b.T; CABI0CabiA013002002.port.T = TC_222_0.port_a.T; CABI0CabiA013002002.port.T = TC_222_1487.port_a.T; CABI0CabiA013002002.port.T = TC_222_224.port_a.T; CABI0CabiA013002002.port.T = TC_222_384.port_a.T; CABI0CabiA013002002.port.T = TC_26_222.port_b.T; CABI0CabiA013002002.port.T = TsCABI0CabiA013002002.port.T; TsCABI0CabiA001002002.port.Q_flow + (TC_14_221.port_b.Q_flow + (CABI0CabiA001002002.port.Q_flow + (TC_221_223.port_a.Q_flow + (TC_221_383.port_a.Q_flow + (TC_221_424.port_a.Q_flow + (TC_221_1477.port_a.Q_flow + TC_221_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA001002002.port.T = TC_14_221.port_b.T; CABI0CabiA001002002.port.T = TC_221_0.port_a.T; CABI0CabiA001002002.port.T = TC_221_1477.port_a.T; CABI0CabiA001002002.port.T = TC_221_223.port_a.T; CABI0CabiA001002002.port.T = TC_221_383.port_a.T; CABI0CabiA001002002.port.T = TC_221_424.port_a.T; CABI0CabiA001002002.port.T = TsCABI0CabiA001002002.port.T; TsCABI0CabiA013001002.port.Q_flow + (TC_219_220.port_b.Q_flow + (TC_13_220.port_b.Q_flow + (CABI0CabiA013001002.port.Q_flow + (TC_220_222.port_a.Q_flow + (TC_220_382.port_a.Q_flow + TC_220_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013001002.port.T = TC_13_220.port_b.T; CABI0CabiA013001002.port.T = TC_219_220.port_b.T; CABI0CabiA013001002.port.T = TC_220_0.port_a.T; CABI0CabiA013001002.port.T = TC_220_222.port_a.T; CABI0CabiA013001002.port.T = TC_220_382.port_a.T; CABI0CabiA013001002.port.T = TsCABI0CabiA013001002.port.T; TsCABI0CabiA012001002.port.Q_flow + (TC_218_219.port_b.Q_flow + (TC_12_219.port_b.Q_flow + (CABI0CabiA012001002.port.Q_flow + (TC_219_220.port_a.Q_flow + (TC_219_381.port_a.Q_flow + (TC_219_1487.port_a.Q_flow + TC_219_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012001002.port.T = TC_12_219.port_b.T; CABI0CabiA012001002.port.T = TC_218_219.port_b.T; CABI0CabiA012001002.port.T = TC_219_0.port_a.T; CABI0CabiA012001002.port.T = TC_219_1487.port_a.T; CABI0CabiA012001002.port.T = TC_219_220.port_a.T; CABI0CabiA012001002.port.T = TC_219_381.port_a.T; CABI0CabiA012001002.port.T = TsCABI0CabiA012001002.port.T; TsCABI0CabiA011001002.port.Q_flow + (TC_217_218.port_b.Q_flow + (TC_11_218.port_b.Q_flow + (CABI0CabiA011001002.port.Q_flow + (TC_218_219.port_a.Q_flow + (TC_218_380.port_a.Q_flow + (TC_218_1486.port_a.Q_flow + TC_218_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011001002.port.T = TC_11_218.port_b.T; CABI0CabiA011001002.port.T = TC_217_218.port_b.T; CABI0CabiA011001002.port.T = TC_218_0.port_a.T; CABI0CabiA011001002.port.T = TC_218_1486.port_a.T; CABI0CabiA011001002.port.T = TC_218_219.port_a.T; CABI0CabiA011001002.port.T = TC_218_380.port_a.T; CABI0CabiA011001002.port.T = TsCABI0CabiA011001002.port.T; TsCABI0CabiA010001002.port.Q_flow + (TC_216_217.port_b.Q_flow + (TC_10_217.port_b.Q_flow + (CABI0CabiA010001002.port.Q_flow + (TC_217_218.port_a.Q_flow + (TC_217_379.port_a.Q_flow + (TC_217_1485.port_a.Q_flow + TC_217_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010001002.port.T = TC_10_217.port_b.T; CABI0CabiA010001002.port.T = TC_216_217.port_b.T; CABI0CabiA010001002.port.T = TC_217_0.port_a.T; CABI0CabiA010001002.port.T = TC_217_1485.port_a.T; CABI0CabiA010001002.port.T = TC_217_218.port_a.T; CABI0CabiA010001002.port.T = TC_217_379.port_a.T; CABI0CabiA010001002.port.T = TsCABI0CabiA010001002.port.T; TsCABI0CabiA009001002.port.Q_flow + (TC_215_216.port_b.Q_flow + (TC_9_216.port_b.Q_flow + (CABI0CabiA009001002.port.Q_flow + (TC_216_217.port_a.Q_flow + (TC_216_378.port_a.Q_flow + (TC_216_1484.port_a.Q_flow + TC_216_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009001002.port.T = TC_215_216.port_b.T; CABI0CabiA009001002.port.T = TC_216_0.port_a.T; CABI0CabiA009001002.port.T = TC_216_1484.port_a.T; CABI0CabiA009001002.port.T = TC_216_217.port_a.T; CABI0CabiA009001002.port.T = TC_216_378.port_a.T; CABI0CabiA009001002.port.T = TC_9_216.port_b.T; CABI0CabiA009001002.port.T = TsCABI0CabiA009001002.port.T; TsCABI0CabiA008001002.port.Q_flow + (TC_214_215.port_b.Q_flow + (TC_8_215.port_b.Q_flow + (CABI0CabiA008001002.port.Q_flow + (TC_215_216.port_a.Q_flow + (TC_215_377.port_a.Q_flow + (TC_215_1483.port_a.Q_flow + TC_215_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008001002.port.T = TC_214_215.port_b.T; CABI0CabiA008001002.port.T = TC_215_0.port_a.T; CABI0CabiA008001002.port.T = TC_215_1483.port_a.T; CABI0CabiA008001002.port.T = TC_215_216.port_a.T; CABI0CabiA008001002.port.T = TC_215_377.port_a.T; CABI0CabiA008001002.port.T = TC_8_215.port_b.T; CABI0CabiA008001002.port.T = TsCABI0CabiA008001002.port.T; TsCABI0CabiA007001002.port.Q_flow + (TC_213_214.port_b.Q_flow + (TC_7_214.port_b.Q_flow + (CABI0CabiA007001002.port.Q_flow + (TC_214_215.port_a.Q_flow + (TC_214_376.port_a.Q_flow + (TC_214_1482.port_a.Q_flow + TC_214_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007001002.port.T = TC_213_214.port_b.T; CABI0CabiA007001002.port.T = TC_214_0.port_a.T; CABI0CabiA007001002.port.T = TC_214_1482.port_a.T; CABI0CabiA007001002.port.T = TC_214_215.port_a.T; CABI0CabiA007001002.port.T = TC_214_376.port_a.T; CABI0CabiA007001002.port.T = TC_7_214.port_b.T; CABI0CabiA007001002.port.T = TsCABI0CabiA007001002.port.T; TsCABI0CabiA006001002.port.Q_flow + (TC_212_213.port_b.Q_flow + (TC_6_213.port_b.Q_flow + (CABI0CabiA006001002.port.Q_flow + (TC_213_214.port_a.Q_flow + (TC_213_375.port_a.Q_flow + (TC_213_1481.port_a.Q_flow + TC_213_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006001002.port.T = TC_212_213.port_b.T; CABI0CabiA006001002.port.T = TC_213_0.port_a.T; CABI0CabiA006001002.port.T = TC_213_1481.port_a.T; CABI0CabiA006001002.port.T = TC_213_214.port_a.T; CABI0CabiA006001002.port.T = TC_213_375.port_a.T; CABI0CabiA006001002.port.T = TC_6_213.port_b.T; CABI0CabiA006001002.port.T = TsCABI0CabiA006001002.port.T; TsCABI0CabiA005001002.port.Q_flow + (TC_211_212.port_b.Q_flow + (TC_5_212.port_b.Q_flow + (CABI0CabiA005001002.port.Q_flow + (TC_212_213.port_a.Q_flow + (TC_212_374.port_a.Q_flow + (TC_212_1480.port_a.Q_flow + TC_212_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005001002.port.T = TC_211_212.port_b.T; CABI0CabiA005001002.port.T = TC_212_0.port_a.T; CABI0CabiA005001002.port.T = TC_212_1480.port_a.T; CABI0CabiA005001002.port.T = TC_212_213.port_a.T; CABI0CabiA005001002.port.T = TC_212_374.port_a.T; CABI0CabiA005001002.port.T = TC_5_212.port_b.T; CABI0CabiA005001002.port.T = TsCABI0CabiA005001002.port.T; TsCABI0CabiA004001002.port.Q_flow + (TC_210_211.port_b.Q_flow + (TC_4_211.port_b.Q_flow + (CABI0CabiA004001002.port.Q_flow + (TC_211_212.port_a.Q_flow + (TC_211_373.port_a.Q_flow + (TC_211_1479.port_a.Q_flow + TC_211_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004001002.port.T = TC_210_211.port_b.T; CABI0CabiA004001002.port.T = TC_211_0.port_a.T; CABI0CabiA004001002.port.T = TC_211_1479.port_a.T; CABI0CabiA004001002.port.T = TC_211_212.port_a.T; CABI0CabiA004001002.port.T = TC_211_373.port_a.T; CABI0CabiA004001002.port.T = TC_4_211.port_b.T; CABI0CabiA004001002.port.T = TsCABI0CabiA004001002.port.T; TsCABI0CabiA003001002.port.Q_flow + (TC_209_210.port_b.Q_flow + (TC_3_210.port_b.Q_flow + (CABI0CabiA003001002.port.Q_flow + (TC_210_211.port_a.Q_flow + (TC_210_372.port_a.Q_flow + (TC_210_1478.port_a.Q_flow + TC_210_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003001002.port.T = TC_209_210.port_b.T; CABI0CabiA003001002.port.T = TC_210_0.port_a.T; CABI0CabiA003001002.port.T = TC_210_1478.port_a.T; CABI0CabiA003001002.port.T = TC_210_211.port_a.T; CABI0CabiA003001002.port.T = TC_210_372.port_a.T; CABI0CabiA003001002.port.T = TC_3_210.port_b.T; CABI0CabiA003001002.port.T = TsCABI0CabiA003001002.port.T; TsCABI0CabiA002001002.port.Q_flow + (TC_2_209.port_b.Q_flow + (CABI0CabiA002001002.port.Q_flow + (TC_209_210.port_a.Q_flow + (TC_209_371.port_a.Q_flow + (TC_209_424.port_a.Q_flow + (TC_209_1477.port_a.Q_flow + TC_209_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002001002.port.T = TC_209_0.port_a.T; CABI0CabiA002001002.port.T = TC_209_1477.port_a.T; CABI0CabiA002001002.port.T = TC_209_210.port_a.T; CABI0CabiA002001002.port.T = TC_209_371.port_a.T; CABI0CabiA002001002.port.T = TC_209_424.port_a.T; CABI0CabiA002001002.port.T = TC_2_209.port_b.T; CABI0CabiA002001002.port.T = TsCABI0CabiA002001002.port.T; TsCABI0CabiA013016001.port.Q_flow + (TC_207_208.port_b.Q_flow + (TC_195_208.port_b.Q_flow + (CABI0CabiA013016001.port.Q_flow + (TC_208_261.port_a.Q_flow + TC_208_0.port_a.Q_flow)))) = 0.0; CABI0CabiA013016001.port.T = TC_195_208.port_b.T; CABI0CabiA013016001.port.T = TC_207_208.port_b.T; CABI0CabiA013016001.port.T = TC_208_0.port_a.T; CABI0CabiA013016001.port.T = TC_208_261.port_a.T; CABI0CabiA013016001.port.T = TsCABI0CabiA013016001.port.T; TsCABI0CabiA012016001.port.Q_flow + (TC_206_207.port_b.Q_flow + (TC_194_207.port_b.Q_flow + (CABI0CabiA012016001.port.Q_flow + (TC_207_208.port_a.Q_flow + (TC_207_260.port_a.Q_flow + TC_207_0.port_a.Q_flow))))) = 0.0; CABI0CabiA012016001.port.T = TC_194_207.port_b.T; CABI0CabiA012016001.port.T = TC_206_207.port_b.T; CABI0CabiA012016001.port.T = TC_207_0.port_a.T; CABI0CabiA012016001.port.T = TC_207_208.port_a.T; CABI0CabiA012016001.port.T = TC_207_260.port_a.T; CABI0CabiA012016001.port.T = TsCABI0CabiA012016001.port.T; TsCABI0CabiA011016001.port.Q_flow + (TC_205_206.port_b.Q_flow + (TC_193_206.port_b.Q_flow + (CABI0CabiA011016001.port.Q_flow + (TC_206_207.port_a.Q_flow + (TC_206_259.port_a.Q_flow + TC_206_0.port_a.Q_flow))))) = 0.0; CABI0CabiA011016001.port.T = TC_193_206.port_b.T; CABI0CabiA011016001.port.T = TC_205_206.port_b.T; CABI0CabiA011016001.port.T = TC_206_0.port_a.T; CABI0CabiA011016001.port.T = TC_206_207.port_a.T; CABI0CabiA011016001.port.T = TC_206_259.port_a.T; CABI0CabiA011016001.port.T = TsCABI0CabiA011016001.port.T; TsCABI0CabiA010016001.port.Q_flow + (TC_204_205.port_b.Q_flow + (TC_192_205.port_b.Q_flow + (CABI0CabiA010016001.port.Q_flow + (TC_205_206.port_a.Q_flow + (TC_205_258.port_a.Q_flow + TC_205_0.port_a.Q_flow))))) = 0.0; CABI0CabiA010016001.port.T = TC_192_205.port_b.T; CABI0CabiA010016001.port.T = TC_204_205.port_b.T; CABI0CabiA010016001.port.T = TC_205_0.port_a.T; CABI0CabiA010016001.port.T = TC_205_206.port_a.T; CABI0CabiA010016001.port.T = TC_205_258.port_a.T; CABI0CabiA010016001.port.T = TsCABI0CabiA010016001.port.T; TsCABI0CabiA009016001.port.Q_flow + (TC_203_204.port_b.Q_flow + (TC_191_204.port_b.Q_flow + (CABI0CabiA009016001.port.Q_flow + (TC_204_205.port_a.Q_flow + (TC_204_257.port_a.Q_flow + TC_204_0.port_a.Q_flow))))) = 0.0; CABI0CabiA009016001.port.T = TC_191_204.port_b.T; CABI0CabiA009016001.port.T = TC_203_204.port_b.T; CABI0CabiA009016001.port.T = TC_204_0.port_a.T; CABI0CabiA009016001.port.T = TC_204_205.port_a.T; CABI0CabiA009016001.port.T = TC_204_257.port_a.T; CABI0CabiA009016001.port.T = TsCABI0CabiA009016001.port.T; TsCABI0CabiA008016001.port.Q_flow + (TC_202_203.port_b.Q_flow + (TC_190_203.port_b.Q_flow + (CABI0CabiA008016001.port.Q_flow + (TC_203_204.port_a.Q_flow + (TC_203_256.port_a.Q_flow + TC_203_0.port_a.Q_flow))))) = 0.0; CABI0CabiA008016001.port.T = TC_190_203.port_b.T; CABI0CabiA008016001.port.T = TC_202_203.port_b.T; CABI0CabiA008016001.port.T = TC_203_0.port_a.T; CABI0CabiA008016001.port.T = TC_203_204.port_a.T; CABI0CabiA008016001.port.T = TC_203_256.port_a.T; CABI0CabiA008016001.port.T = TsCABI0CabiA008016001.port.T; TsCABI0CabiA007016001.port.Q_flow + (TC_201_202.port_b.Q_flow + (TC_189_202.port_b.Q_flow + (CABI0CabiA007016001.port.Q_flow + (TC_202_203.port_a.Q_flow + (TC_202_255.port_a.Q_flow + TC_202_0.port_a.Q_flow))))) = 0.0; CABI0CabiA007016001.port.T = TC_189_202.port_b.T; CABI0CabiA007016001.port.T = TC_201_202.port_b.T; CABI0CabiA007016001.port.T = TC_202_0.port_a.T; CABI0CabiA007016001.port.T = TC_202_203.port_a.T; CABI0CabiA007016001.port.T = TC_202_255.port_a.T; CABI0CabiA007016001.port.T = TsCABI0CabiA007016001.port.T; TsCABI0CabiA006016001.port.Q_flow + (TC_200_201.port_b.Q_flow + (TC_188_201.port_b.Q_flow + (CABI0CabiA006016001.port.Q_flow + (TC_201_202.port_a.Q_flow + (TC_201_254.port_a.Q_flow + TC_201_0.port_a.Q_flow))))) = 0.0; CABI0CabiA006016001.port.T = TC_188_201.port_b.T; CABI0CabiA006016001.port.T = TC_200_201.port_b.T; CABI0CabiA006016001.port.T = TC_201_0.port_a.T; CABI0CabiA006016001.port.T = TC_201_202.port_a.T; CABI0CabiA006016001.port.T = TC_201_254.port_a.T; CABI0CabiA006016001.port.T = TsCABI0CabiA006016001.port.T; TsCABI0CabiA005016001.port.Q_flow + (TC_199_200.port_b.Q_flow + (TC_187_200.port_b.Q_flow + (CABI0CabiA005016001.port.Q_flow + (TC_200_201.port_a.Q_flow + (TC_200_253.port_a.Q_flow + TC_200_0.port_a.Q_flow))))) = 0.0; CABI0CabiA005016001.port.T = TC_187_200.port_b.T; CABI0CabiA005016001.port.T = TC_199_200.port_b.T; CABI0CabiA005016001.port.T = TC_200_0.port_a.T; CABI0CabiA005016001.port.T = TC_200_201.port_a.T; CABI0CabiA005016001.port.T = TC_200_253.port_a.T; CABI0CabiA005016001.port.T = TsCABI0CabiA005016001.port.T; TsCABI0CabiA004016001.port.Q_flow + (TC_198_199.port_b.Q_flow + (TC_186_199.port_b.Q_flow + (CABI0CabiA004016001.port.Q_flow + (TC_199_200.port_a.Q_flow + (TC_199_252.port_a.Q_flow + TC_199_0.port_a.Q_flow))))) = 0.0; CABI0CabiA004016001.port.T = TC_186_199.port_b.T; CABI0CabiA004016001.port.T = TC_198_199.port_b.T; CABI0CabiA004016001.port.T = TC_199_0.port_a.T; CABI0CabiA004016001.port.T = TC_199_200.port_a.T; CABI0CabiA004016001.port.T = TC_199_252.port_a.T; CABI0CabiA004016001.port.T = TsCABI0CabiA004016001.port.T; TsCABI0CabiA003016001.port.Q_flow + (TC_197_198.port_b.Q_flow + (TC_185_198.port_b.Q_flow + (CABI0CabiA003016001.port.Q_flow + (TC_198_199.port_a.Q_flow + (TC_198_251.port_a.Q_flow + TC_198_0.port_a.Q_flow))))) = 0.0; CABI0CabiA003016001.port.T = TC_185_198.port_b.T; CABI0CabiA003016001.port.T = TC_197_198.port_b.T; CABI0CabiA003016001.port.T = TC_198_0.port_a.T; CABI0CabiA003016001.port.T = TC_198_199.port_a.T; CABI0CabiA003016001.port.T = TC_198_251.port_a.T; CABI0CabiA003016001.port.T = TsCABI0CabiA003016001.port.T; TsCABI0CabiA002016001.port.Q_flow + (TC_196_197.port_b.Q_flow + (TC_184_197.port_b.Q_flow + (CABI0CabiA002016001.port.Q_flow + (TC_197_198.port_a.Q_flow + (TC_197_250.port_a.Q_flow + TC_197_0.port_a.Q_flow))))) = 0.0; CABI0CabiA002016001.port.T = TC_184_197.port_b.T; CABI0CabiA002016001.port.T = TC_196_197.port_b.T; CABI0CabiA002016001.port.T = TC_197_0.port_a.T; CABI0CabiA002016001.port.T = TC_197_198.port_a.T; CABI0CabiA002016001.port.T = TC_197_250.port_a.T; CABI0CabiA002016001.port.T = TsCABI0CabiA002016001.port.T; TsCABI0CabiA001016001.port.Q_flow + (TC_183_196.port_b.Q_flow + (CABI0CabiA001016001.port.Q_flow + (TC_196_197.port_a.Q_flow + (TC_196_249.port_a.Q_flow + TC_196_0.port_a.Q_flow)))) = 0.0; CABI0CabiA001016001.port.T = TC_183_196.port_b.T; CABI0CabiA001016001.port.T = TC_196_0.port_a.T; CABI0CabiA001016001.port.T = TC_196_197.port_a.T; CABI0CabiA001016001.port.T = TC_196_249.port_a.T; CABI0CabiA001016001.port.T = TsCABI0CabiA001016001.port.T; TsCABI0CabiA013015001.port.Q_flow + (TC_194_195.port_b.Q_flow + (TC_182_195.port_b.Q_flow + (CABI0CabiA013015001.port.Q_flow + (TC_195_208.port_a.Q_flow + (TC_195_248.port_a.Q_flow + TC_195_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013015001.port.T = TC_182_195.port_b.T; CABI0CabiA013015001.port.T = TC_194_195.port_b.T; CABI0CabiA013015001.port.T = TC_195_0.port_a.T; CABI0CabiA013015001.port.T = TC_195_208.port_a.T; CABI0CabiA013015001.port.T = TC_195_248.port_a.T; CABI0CabiA013015001.port.T = TsCABI0CabiA013015001.port.T; TsCABI0CabiA012015001.port.Q_flow + (TC_193_194.port_b.Q_flow + (TC_181_194.port_b.Q_flow + (CABI0CabiA012015001.port.Q_flow + (TC_194_195.port_a.Q_flow + (TC_194_207.port_a.Q_flow + (TC_194_1460.port_a.Q_flow + TC_194_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012015001.port.T = TC_181_194.port_b.T; CABI0CabiA012015001.port.T = TC_193_194.port_b.T; CABI0CabiA012015001.port.T = TC_194_0.port_a.T; CABI0CabiA012015001.port.T = TC_194_1460.port_a.T; CABI0CabiA012015001.port.T = TC_194_195.port_a.T; CABI0CabiA012015001.port.T = TC_194_207.port_a.T; CABI0CabiA012015001.port.T = TsCABI0CabiA012015001.port.T; TsCABI0CabiA011015001.port.Q_flow + (TC_192_193.port_b.Q_flow + (TC_180_193.port_b.Q_flow + (CABI0CabiA011015001.port.Q_flow + (TC_193_194.port_a.Q_flow + (TC_193_206.port_a.Q_flow + (TC_193_1459.port_a.Q_flow + TC_193_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011015001.port.T = TC_180_193.port_b.T; CABI0CabiA011015001.port.T = TC_192_193.port_b.T; CABI0CabiA011015001.port.T = TC_193_0.port_a.T; CABI0CabiA011015001.port.T = TC_193_1459.port_a.T; CABI0CabiA011015001.port.T = TC_193_194.port_a.T; CABI0CabiA011015001.port.T = TC_193_206.port_a.T; CABI0CabiA011015001.port.T = TsCABI0CabiA011015001.port.T; TsCABI0CabiA010015001.port.Q_flow + (TC_191_192.port_b.Q_flow + (TC_179_192.port_b.Q_flow + (CABI0CabiA010015001.port.Q_flow + (TC_192_193.port_a.Q_flow + (TC_192_205.port_a.Q_flow + (TC_192_1458.port_a.Q_flow + TC_192_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010015001.port.T = TC_179_192.port_b.T; CABI0CabiA010015001.port.T = TC_191_192.port_b.T; CABI0CabiA010015001.port.T = TC_192_0.port_a.T; CABI0CabiA010015001.port.T = TC_192_1458.port_a.T; CABI0CabiA010015001.port.T = TC_192_193.port_a.T; CABI0CabiA010015001.port.T = TC_192_205.port_a.T; CABI0CabiA010015001.port.T = TsCABI0CabiA010015001.port.T; TsCABI0CabiA009015001.port.Q_flow + (TC_190_191.port_b.Q_flow + (TC_178_191.port_b.Q_flow + (CABI0CabiA009015001.port.Q_flow + (TC_191_192.port_a.Q_flow + (TC_191_204.port_a.Q_flow + (TC_191_1457.port_a.Q_flow + TC_191_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009015001.port.T = TC_178_191.port_b.T; CABI0CabiA009015001.port.T = TC_190_191.port_b.T; CABI0CabiA009015001.port.T = TC_191_0.port_a.T; CABI0CabiA009015001.port.T = TC_191_1457.port_a.T; CABI0CabiA009015001.port.T = TC_191_192.port_a.T; CABI0CabiA009015001.port.T = TC_191_204.port_a.T; CABI0CabiA009015001.port.T = TsCABI0CabiA009015001.port.T; TsCABI0CabiA008015001.port.Q_flow + (TC_189_190.port_b.Q_flow + (TC_177_190.port_b.Q_flow + (CABI0CabiA008015001.port.Q_flow + (TC_190_191.port_a.Q_flow + (TC_190_203.port_a.Q_flow + (TC_190_1456.port_a.Q_flow + TC_190_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008015001.port.T = TC_177_190.port_b.T; CABI0CabiA008015001.port.T = TC_189_190.port_b.T; CABI0CabiA008015001.port.T = TC_190_0.port_a.T; CABI0CabiA008015001.port.T = TC_190_1456.port_a.T; CABI0CabiA008015001.port.T = TC_190_191.port_a.T; CABI0CabiA008015001.port.T = TC_190_203.port_a.T; CABI0CabiA008015001.port.T = TsCABI0CabiA008015001.port.T; TsCABI0CabiA007015001.port.Q_flow + (TC_188_189.port_b.Q_flow + (TC_176_189.port_b.Q_flow + (CABI0CabiA007015001.port.Q_flow + (TC_189_190.port_a.Q_flow + (TC_189_202.port_a.Q_flow + (TC_189_1455.port_a.Q_flow + TC_189_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007015001.port.T = TC_176_189.port_b.T; CABI0CabiA007015001.port.T = TC_188_189.port_b.T; CABI0CabiA007015001.port.T = TC_189_0.port_a.T; CABI0CabiA007015001.port.T = TC_189_1455.port_a.T; CABI0CabiA007015001.port.T = TC_189_190.port_a.T; CABI0CabiA007015001.port.T = TC_189_202.port_a.T; CABI0CabiA007015001.port.T = TsCABI0CabiA007015001.port.T; TsCABI0CabiA006015001.port.Q_flow + (TC_187_188.port_b.Q_flow + (TC_175_188.port_b.Q_flow + (CABI0CabiA006015001.port.Q_flow + (TC_188_189.port_a.Q_flow + (TC_188_201.port_a.Q_flow + (TC_188_1454.port_a.Q_flow + TC_188_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006015001.port.T = TC_175_188.port_b.T; CABI0CabiA006015001.port.T = TC_187_188.port_b.T; CABI0CabiA006015001.port.T = TC_188_0.port_a.T; CABI0CabiA006015001.port.T = TC_188_1454.port_a.T; CABI0CabiA006015001.port.T = TC_188_189.port_a.T; CABI0CabiA006015001.port.T = TC_188_201.port_a.T; CABI0CabiA006015001.port.T = TsCABI0CabiA006015001.port.T; TsCABI0CabiA005015001.port.Q_flow + (TC_186_187.port_b.Q_flow + (TC_174_187.port_b.Q_flow + (CABI0CabiA005015001.port.Q_flow + (TC_187_188.port_a.Q_flow + (TC_187_200.port_a.Q_flow + (TC_187_1453.port_a.Q_flow + TC_187_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005015001.port.T = TC_174_187.port_b.T; CABI0CabiA005015001.port.T = TC_186_187.port_b.T; CABI0CabiA005015001.port.T = TC_187_0.port_a.T; CABI0CabiA005015001.port.T = TC_187_1453.port_a.T; CABI0CabiA005015001.port.T = TC_187_188.port_a.T; CABI0CabiA005015001.port.T = TC_187_200.port_a.T; CABI0CabiA005015001.port.T = TsCABI0CabiA005015001.port.T; TsCABI0CabiA004015001.port.Q_flow + (TC_185_186.port_b.Q_flow + (TC_173_186.port_b.Q_flow + (CABI0CabiA004015001.port.Q_flow + (TC_186_187.port_a.Q_flow + (TC_186_199.port_a.Q_flow + (TC_186_1452.port_a.Q_flow + TC_186_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004015001.port.T = TC_173_186.port_b.T; CABI0CabiA004015001.port.T = TC_185_186.port_b.T; CABI0CabiA004015001.port.T = TC_186_0.port_a.T; CABI0CabiA004015001.port.T = TC_186_1452.port_a.T; CABI0CabiA004015001.port.T = TC_186_187.port_a.T; CABI0CabiA004015001.port.T = TC_186_199.port_a.T; CABI0CabiA004015001.port.T = TsCABI0CabiA004015001.port.T; TsCABI0CabiA003015001.port.Q_flow + (TC_184_185.port_b.Q_flow + (TC_172_185.port_b.Q_flow + (CABI0CabiA003015001.port.Q_flow + (TC_185_186.port_a.Q_flow + (TC_185_198.port_a.Q_flow + (TC_185_1451.port_a.Q_flow + TC_185_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003015001.port.T = TC_172_185.port_b.T; CABI0CabiA003015001.port.T = TC_184_185.port_b.T; CABI0CabiA003015001.port.T = TC_185_0.port_a.T; CABI0CabiA003015001.port.T = TC_185_1451.port_a.T; CABI0CabiA003015001.port.T = TC_185_186.port_a.T; CABI0CabiA003015001.port.T = TC_185_198.port_a.T; CABI0CabiA003015001.port.T = TsCABI0CabiA003015001.port.T; TsCABI0CabiA002015001.port.Q_flow + (TC_183_184.port_b.Q_flow + (TC_171_184.port_b.Q_flow + (CABI0CabiA002015001.port.Q_flow + (TC_184_185.port_a.Q_flow + (TC_184_197.port_a.Q_flow + (TC_184_1450.port_a.Q_flow + TC_184_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002015001.port.T = TC_171_184.port_b.T; CABI0CabiA002015001.port.T = TC_183_184.port_b.T; CABI0CabiA002015001.port.T = TC_184_0.port_a.T; CABI0CabiA002015001.port.T = TC_184_1450.port_a.T; CABI0CabiA002015001.port.T = TC_184_185.port_a.T; CABI0CabiA002015001.port.T = TC_184_197.port_a.T; CABI0CabiA002015001.port.T = TsCABI0CabiA002015001.port.T; TsCABI0CabiA001015001.port.Q_flow + (TC_170_183.port_b.Q_flow + (CABI0CabiA001015001.port.Q_flow + (TC_183_184.port_a.Q_flow + (TC_183_196.port_a.Q_flow + (TC_183_247.port_a.Q_flow + TC_183_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001015001.port.T = TC_170_183.port_b.T; CABI0CabiA001015001.port.T = TC_183_0.port_a.T; CABI0CabiA001015001.port.T = TC_183_184.port_a.T; CABI0CabiA001015001.port.T = TC_183_196.port_a.T; CABI0CabiA001015001.port.T = TC_183_247.port_a.T; CABI0CabiA001015001.port.T = TsCABI0CabiA001015001.port.T; TsCABI0CabiA013014001.port.Q_flow + (TC_181_182.port_b.Q_flow + (TC_169_182.port_b.Q_flow + (CABI0CabiA013014001.port.Q_flow + (TC_182_195.port_a.Q_flow + (TC_182_246.port_a.Q_flow + TC_182_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013014001.port.T = TC_169_182.port_b.T; CABI0CabiA013014001.port.T = TC_181_182.port_b.T; CABI0CabiA013014001.port.T = TC_182_0.port_a.T; CABI0CabiA013014001.port.T = TC_182_195.port_a.T; CABI0CabiA013014001.port.T = TC_182_246.port_a.T; CABI0CabiA013014001.port.T = TsCABI0CabiA013014001.port.T; TsCABI0CabiA012014001.port.Q_flow + (TC_180_181.port_b.Q_flow + (TC_168_181.port_b.Q_flow + (CABI0CabiA012014001.port.Q_flow + (TC_181_182.port_a.Q_flow + (TC_181_194.port_a.Q_flow + (TC_181_1449.port_a.Q_flow + TC_181_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012014001.port.T = TC_168_181.port_b.T; CABI0CabiA012014001.port.T = TC_180_181.port_b.T; CABI0CabiA012014001.port.T = TC_181_0.port_a.T; CABI0CabiA012014001.port.T = TC_181_1449.port_a.T; CABI0CabiA012014001.port.T = TC_181_182.port_a.T; CABI0CabiA012014001.port.T = TC_181_194.port_a.T; CABI0CabiA012014001.port.T = TsCABI0CabiA012014001.port.T; TsCABI0CabiA011014001.port.Q_flow + (TC_179_180.port_b.Q_flow + (TC_167_180.port_b.Q_flow + (CABI0CabiA011014001.port.Q_flow + (TC_180_181.port_a.Q_flow + (TC_180_193.port_a.Q_flow + (TC_180_1448.port_a.Q_flow + TC_180_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011014001.port.T = TC_167_180.port_b.T; CABI0CabiA011014001.port.T = TC_179_180.port_b.T; CABI0CabiA011014001.port.T = TC_180_0.port_a.T; CABI0CabiA011014001.port.T = TC_180_1448.port_a.T; CABI0CabiA011014001.port.T = TC_180_181.port_a.T; CABI0CabiA011014001.port.T = TC_180_193.port_a.T; CABI0CabiA011014001.port.T = TsCABI0CabiA011014001.port.T; TsCABI0CabiA010014001.port.Q_flow + (TC_178_179.port_b.Q_flow + (TC_166_179.port_b.Q_flow + (CABI0CabiA010014001.port.Q_flow + (TC_179_180.port_a.Q_flow + (TC_179_192.port_a.Q_flow + (TC_179_1447.port_a.Q_flow + TC_179_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010014001.port.T = TC_166_179.port_b.T; CABI0CabiA010014001.port.T = TC_178_179.port_b.T; CABI0CabiA010014001.port.T = TC_179_0.port_a.T; CABI0CabiA010014001.port.T = TC_179_1447.port_a.T; CABI0CabiA010014001.port.T = TC_179_180.port_a.T; CABI0CabiA010014001.port.T = TC_179_192.port_a.T; CABI0CabiA010014001.port.T = TsCABI0CabiA010014001.port.T; TsCABI0CabiA009014001.port.Q_flow + (TC_177_178.port_b.Q_flow + (TC_165_178.port_b.Q_flow + (CABI0CabiA009014001.port.Q_flow + (TC_178_179.port_a.Q_flow + (TC_178_191.port_a.Q_flow + (TC_178_1446.port_a.Q_flow + TC_178_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009014001.port.T = TC_165_178.port_b.T; CABI0CabiA009014001.port.T = TC_177_178.port_b.T; CABI0CabiA009014001.port.T = TC_178_0.port_a.T; CABI0CabiA009014001.port.T = TC_178_1446.port_a.T; CABI0CabiA009014001.port.T = TC_178_179.port_a.T; CABI0CabiA009014001.port.T = TC_178_191.port_a.T; CABI0CabiA009014001.port.T = TsCABI0CabiA009014001.port.T; TsCABI0CabiA008014001.port.Q_flow + (TC_176_177.port_b.Q_flow + (TC_164_177.port_b.Q_flow + (CABI0CabiA008014001.port.Q_flow + (TC_177_178.port_a.Q_flow + (TC_177_190.port_a.Q_flow + (TC_177_1445.port_a.Q_flow + TC_177_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008014001.port.T = TC_164_177.port_b.T; CABI0CabiA008014001.port.T = TC_176_177.port_b.T; CABI0CabiA008014001.port.T = TC_177_0.port_a.T; CABI0CabiA008014001.port.T = TC_177_1445.port_a.T; CABI0CabiA008014001.port.T = TC_177_178.port_a.T; CABI0CabiA008014001.port.T = TC_177_190.port_a.T; CABI0CabiA008014001.port.T = TsCABI0CabiA008014001.port.T; TsCABI0CabiA007014001.port.Q_flow + (TC_175_176.port_b.Q_flow + (TC_163_176.port_b.Q_flow + (CABI0CabiA007014001.port.Q_flow + (TC_176_177.port_a.Q_flow + (TC_176_189.port_a.Q_flow + (TC_176_1444.port_a.Q_flow + TC_176_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007014001.port.T = TC_163_176.port_b.T; CABI0CabiA007014001.port.T = TC_175_176.port_b.T; CABI0CabiA007014001.port.T = TC_176_0.port_a.T; CABI0CabiA007014001.port.T = TC_176_1444.port_a.T; CABI0CabiA007014001.port.T = TC_176_177.port_a.T; CABI0CabiA007014001.port.T = TC_176_189.port_a.T; CABI0CabiA007014001.port.T = TsCABI0CabiA007014001.port.T; TsCABI0CabiA006014001.port.Q_flow + (TC_174_175.port_b.Q_flow + (TC_162_175.port_b.Q_flow + (CABI0CabiA006014001.port.Q_flow + (TC_175_176.port_a.Q_flow + (TC_175_188.port_a.Q_flow + (TC_175_1443.port_a.Q_flow + TC_175_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006014001.port.T = TC_162_175.port_b.T; CABI0CabiA006014001.port.T = TC_174_175.port_b.T; CABI0CabiA006014001.port.T = TC_175_0.port_a.T; CABI0CabiA006014001.port.T = TC_175_1443.port_a.T; CABI0CabiA006014001.port.T = TC_175_176.port_a.T; CABI0CabiA006014001.port.T = TC_175_188.port_a.T; CABI0CabiA006014001.port.T = TsCABI0CabiA006014001.port.T; TsCABI0CabiA005014001.port.Q_flow + (TC_173_174.port_b.Q_flow + (TC_161_174.port_b.Q_flow + (CABI0CabiA005014001.port.Q_flow + (TC_174_175.port_a.Q_flow + (TC_174_187.port_a.Q_flow + (TC_174_1442.port_a.Q_flow + TC_174_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005014001.port.T = TC_161_174.port_b.T; CABI0CabiA005014001.port.T = TC_173_174.port_b.T; CABI0CabiA005014001.port.T = TC_174_0.port_a.T; CABI0CabiA005014001.port.T = TC_174_1442.port_a.T; CABI0CabiA005014001.port.T = TC_174_175.port_a.T; CABI0CabiA005014001.port.T = TC_174_187.port_a.T; CABI0CabiA005014001.port.T = TsCABI0CabiA005014001.port.T; TsCABI0CabiA004014001.port.Q_flow + (TC_172_173.port_b.Q_flow + (TC_160_173.port_b.Q_flow + (CABI0CabiA004014001.port.Q_flow + (TC_173_174.port_a.Q_flow + (TC_173_186.port_a.Q_flow + (TC_173_1441.port_a.Q_flow + TC_173_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004014001.port.T = TC_160_173.port_b.T; CABI0CabiA004014001.port.T = TC_172_173.port_b.T; CABI0CabiA004014001.port.T = TC_173_0.port_a.T; CABI0CabiA004014001.port.T = TC_173_1441.port_a.T; CABI0CabiA004014001.port.T = TC_173_174.port_a.T; CABI0CabiA004014001.port.T = TC_173_186.port_a.T; CABI0CabiA004014001.port.T = TsCABI0CabiA004014001.port.T; TsCABI0CabiA003014001.port.Q_flow + (TC_171_172.port_b.Q_flow + (TC_159_172.port_b.Q_flow + (CABI0CabiA003014001.port.Q_flow + (TC_172_173.port_a.Q_flow + (TC_172_185.port_a.Q_flow + (TC_172_1440.port_a.Q_flow + TC_172_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003014001.port.T = TC_159_172.port_b.T; CABI0CabiA003014001.port.T = TC_171_172.port_b.T; CABI0CabiA003014001.port.T = TC_172_0.port_a.T; CABI0CabiA003014001.port.T = TC_172_1440.port_a.T; CABI0CabiA003014001.port.T = TC_172_173.port_a.T; CABI0CabiA003014001.port.T = TC_172_185.port_a.T; CABI0CabiA003014001.port.T = TsCABI0CabiA003014001.port.T; TsCABI0CabiA002014001.port.Q_flow + (TC_170_171.port_b.Q_flow + (TC_158_171.port_b.Q_flow + (CABI0CabiA002014001.port.Q_flow + (TC_171_172.port_a.Q_flow + (TC_171_184.port_a.Q_flow + (TC_171_1439.port_a.Q_flow + TC_171_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002014001.port.T = TC_158_171.port_b.T; CABI0CabiA002014001.port.T = TC_170_171.port_b.T; CABI0CabiA002014001.port.T = TC_171_0.port_a.T; CABI0CabiA002014001.port.T = TC_171_1439.port_a.T; CABI0CabiA002014001.port.T = TC_171_172.port_a.T; CABI0CabiA002014001.port.T = TC_171_184.port_a.T; CABI0CabiA002014001.port.T = TsCABI0CabiA002014001.port.T; TsCABI0CabiA001014001.port.Q_flow + (TC_157_170.port_b.Q_flow + (CABI0CabiA001014001.port.Q_flow + (TC_170_171.port_a.Q_flow + (TC_170_183.port_a.Q_flow + (TC_170_245.port_a.Q_flow + TC_170_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001014001.port.T = TC_157_170.port_b.T; CABI0CabiA001014001.port.T = TC_170_0.port_a.T; CABI0CabiA001014001.port.T = TC_170_171.port_a.T; CABI0CabiA001014001.port.T = TC_170_183.port_a.T; CABI0CabiA001014001.port.T = TC_170_245.port_a.T; CABI0CabiA001014001.port.T = TsCABI0CabiA001014001.port.T; TsCABI0CabiA013013001.port.Q_flow + (TC_168_169.port_b.Q_flow + (TC_156_169.port_b.Q_flow + (CABI0CabiA013013001.port.Q_flow + (TC_169_182.port_a.Q_flow + (TC_169_244.port_a.Q_flow + TC_169_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013013001.port.T = TC_156_169.port_b.T; CABI0CabiA013013001.port.T = TC_168_169.port_b.T; CABI0CabiA013013001.port.T = TC_169_0.port_a.T; CABI0CabiA013013001.port.T = TC_169_182.port_a.T; CABI0CabiA013013001.port.T = TC_169_244.port_a.T; CABI0CabiA013013001.port.T = TsCABI0CabiA013013001.port.T; TsCABI0CabiA012013001.port.Q_flow + (TC_167_168.port_b.Q_flow + (TC_155_168.port_b.Q_flow + (CABI0CabiA012013001.port.Q_flow + (TC_168_169.port_a.Q_flow + (TC_168_181.port_a.Q_flow + (TC_168_1438.port_a.Q_flow + TC_168_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012013001.port.T = TC_155_168.port_b.T; CABI0CabiA012013001.port.T = TC_167_168.port_b.T; CABI0CabiA012013001.port.T = TC_168_0.port_a.T; CABI0CabiA012013001.port.T = TC_168_1438.port_a.T; CABI0CabiA012013001.port.T = TC_168_169.port_a.T; CABI0CabiA012013001.port.T = TC_168_181.port_a.T; CABI0CabiA012013001.port.T = TsCABI0CabiA012013001.port.T; TsCABI0CabiA011013001.port.Q_flow + (TC_166_167.port_b.Q_flow + (TC_154_167.port_b.Q_flow + (CABI0CabiA011013001.port.Q_flow + (TC_167_168.port_a.Q_flow + (TC_167_180.port_a.Q_flow + (TC_167_812.port_a.Q_flow + TC_167_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011013001.port.T = TC_154_167.port_b.T; CABI0CabiA011013001.port.T = TC_166_167.port_b.T; CABI0CabiA011013001.port.T = TC_167_0.port_a.T; CABI0CabiA011013001.port.T = TC_167_168.port_a.T; CABI0CabiA011013001.port.T = TC_167_180.port_a.T; CABI0CabiA011013001.port.T = TC_167_812.port_a.T; CABI0CabiA011013001.port.T = TsCABI0CabiA011013001.port.T; TsCABI0CabiA010013001.port.Q_flow + (TC_165_166.port_b.Q_flow + (TC_153_166.port_b.Q_flow + (CABI0CabiA010013001.port.Q_flow + (TC_166_167.port_a.Q_flow + (TC_166_179.port_a.Q_flow + (TC_166_811.port_a.Q_flow + TC_166_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010013001.port.T = TC_153_166.port_b.T; CABI0CabiA010013001.port.T = TC_165_166.port_b.T; CABI0CabiA010013001.port.T = TC_166_0.port_a.T; CABI0CabiA010013001.port.T = TC_166_167.port_a.T; CABI0CabiA010013001.port.T = TC_166_179.port_a.T; CABI0CabiA010013001.port.T = TC_166_811.port_a.T; CABI0CabiA010013001.port.T = TsCABI0CabiA010013001.port.T; TsCABI0CabiA009013001.port.Q_flow + (TC_164_165.port_b.Q_flow + (TC_152_165.port_b.Q_flow + (CABI0CabiA009013001.port.Q_flow + (TC_165_166.port_a.Q_flow + (TC_165_178.port_a.Q_flow + (TC_165_810.port_a.Q_flow + TC_165_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009013001.port.T = TC_152_165.port_b.T; CABI0CabiA009013001.port.T = TC_164_165.port_b.T; CABI0CabiA009013001.port.T = TC_165_0.port_a.T; CABI0CabiA009013001.port.T = TC_165_166.port_a.T; CABI0CabiA009013001.port.T = TC_165_178.port_a.T; CABI0CabiA009013001.port.T = TC_165_810.port_a.T; CABI0CabiA009013001.port.T = TsCABI0CabiA009013001.port.T; TsCABI0CabiA008013001.port.Q_flow + (TC_163_164.port_b.Q_flow + (TC_151_164.port_b.Q_flow + (CABI0CabiA008013001.port.Q_flow + (TC_164_165.port_a.Q_flow + (TC_164_177.port_a.Q_flow + (TC_164_809.port_a.Q_flow + TC_164_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008013001.port.T = TC_151_164.port_b.T; CABI0CabiA008013001.port.T = TC_163_164.port_b.T; CABI0CabiA008013001.port.T = TC_164_0.port_a.T; CABI0CabiA008013001.port.T = TC_164_165.port_a.T; CABI0CabiA008013001.port.T = TC_164_177.port_a.T; CABI0CabiA008013001.port.T = TC_164_809.port_a.T; CABI0CabiA008013001.port.T = TsCABI0CabiA008013001.port.T; TsCABI0CabiA007013001.port.Q_flow + (TC_162_163.port_b.Q_flow + (TC_150_163.port_b.Q_flow + (CABI0CabiA007013001.port.Q_flow + (TC_163_164.port_a.Q_flow + (TC_163_176.port_a.Q_flow + (TC_163_808.port_a.Q_flow + TC_163_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007013001.port.T = TC_150_163.port_b.T; CABI0CabiA007013001.port.T = TC_162_163.port_b.T; CABI0CabiA007013001.port.T = TC_163_0.port_a.T; CABI0CabiA007013001.port.T = TC_163_164.port_a.T; CABI0CabiA007013001.port.T = TC_163_176.port_a.T; CABI0CabiA007013001.port.T = TC_163_808.port_a.T; CABI0CabiA007013001.port.T = TsCABI0CabiA007013001.port.T; TsCABI0CabiA006013001.port.Q_flow + (TC_161_162.port_b.Q_flow + (TC_149_162.port_b.Q_flow + (CABI0CabiA006013001.port.Q_flow + (TC_162_163.port_a.Q_flow + (TC_162_175.port_a.Q_flow + (TC_162_807.port_a.Q_flow + TC_162_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006013001.port.T = TC_149_162.port_b.T; CABI0CabiA006013001.port.T = TC_161_162.port_b.T; CABI0CabiA006013001.port.T = TC_162_0.port_a.T; CABI0CabiA006013001.port.T = TC_162_163.port_a.T; CABI0CabiA006013001.port.T = TC_162_175.port_a.T; CABI0CabiA006013001.port.T = TC_162_807.port_a.T; CABI0CabiA006013001.port.T = TsCABI0CabiA006013001.port.T; TsCABI0CabiA005013001.port.Q_flow + (TC_160_161.port_b.Q_flow + (TC_148_161.port_b.Q_flow + (CABI0CabiA005013001.port.Q_flow + (TC_161_162.port_a.Q_flow + (TC_161_174.port_a.Q_flow + (TC_161_806.port_a.Q_flow + TC_161_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005013001.port.T = TC_148_161.port_b.T; CABI0CabiA005013001.port.T = TC_160_161.port_b.T; CABI0CabiA005013001.port.T = TC_161_0.port_a.T; CABI0CabiA005013001.port.T = TC_161_162.port_a.T; CABI0CabiA005013001.port.T = TC_161_174.port_a.T; CABI0CabiA005013001.port.T = TC_161_806.port_a.T; CABI0CabiA005013001.port.T = TsCABI0CabiA005013001.port.T; TsCABI0CabiA004013001.port.Q_flow + (TC_159_160.port_b.Q_flow + (TC_147_160.port_b.Q_flow + (CABI0CabiA004013001.port.Q_flow + (TC_160_161.port_a.Q_flow + (TC_160_173.port_a.Q_flow + (TC_160_805.port_a.Q_flow + TC_160_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004013001.port.T = TC_147_160.port_b.T; CABI0CabiA004013001.port.T = TC_159_160.port_b.T; CABI0CabiA004013001.port.T = TC_160_0.port_a.T; CABI0CabiA004013001.port.T = TC_160_161.port_a.T; CABI0CabiA004013001.port.T = TC_160_173.port_a.T; CABI0CabiA004013001.port.T = TC_160_805.port_a.T; CABI0CabiA004013001.port.T = TsCABI0CabiA004013001.port.T; TsCABI0CabiA003013001.port.Q_flow + (TC_158_159.port_b.Q_flow + (TC_146_159.port_b.Q_flow + (CABI0CabiA003013001.port.Q_flow + (TC_159_160.port_a.Q_flow + (TC_159_172.port_a.Q_flow + (TC_159_1437.port_a.Q_flow + TC_159_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003013001.port.T = TC_146_159.port_b.T; CABI0CabiA003013001.port.T = TC_158_159.port_b.T; CABI0CabiA003013001.port.T = TC_159_0.port_a.T; CABI0CabiA003013001.port.T = TC_159_1437.port_a.T; CABI0CabiA003013001.port.T = TC_159_160.port_a.T; CABI0CabiA003013001.port.T = TC_159_172.port_a.T; CABI0CabiA003013001.port.T = TsCABI0CabiA003013001.port.T; TsCABI0CabiA002013001.port.Q_flow + (TC_157_158.port_b.Q_flow + (TC_145_158.port_b.Q_flow + (CABI0CabiA002013001.port.Q_flow + (TC_158_159.port_a.Q_flow + (TC_158_171.port_a.Q_flow + (TC_158_1436.port_a.Q_flow + TC_158_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002013001.port.T = TC_145_158.port_b.T; CABI0CabiA002013001.port.T = TC_157_158.port_b.T; CABI0CabiA002013001.port.T = TC_158_0.port_a.T; CABI0CabiA002013001.port.T = TC_158_1436.port_a.T; CABI0CabiA002013001.port.T = TC_158_159.port_a.T; CABI0CabiA002013001.port.T = TC_158_171.port_a.T; CABI0CabiA002013001.port.T = TsCABI0CabiA002013001.port.T; TsCABI0CabiA001013001.port.Q_flow + (TC_144_157.port_b.Q_flow + (CABI0CabiA001013001.port.Q_flow + (TC_157_158.port_a.Q_flow + (TC_157_170.port_a.Q_flow + (TC_157_243.port_a.Q_flow + TC_157_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001013001.port.T = TC_144_157.port_b.T; CABI0CabiA001013001.port.T = TC_157_0.port_a.T; CABI0CabiA001013001.port.T = TC_157_158.port_a.T; CABI0CabiA001013001.port.T = TC_157_170.port_a.T; CABI0CabiA001013001.port.T = TC_157_243.port_a.T; CABI0CabiA001013001.port.T = TsCABI0CabiA001013001.port.T; TsCABI0CabiA013012001.port.Q_flow + (TC_155_156.port_b.Q_flow + (TC_143_156.port_b.Q_flow + (CABI0CabiA013012001.port.Q_flow + (TC_156_169.port_a.Q_flow + (TC_156_242.port_a.Q_flow + TC_156_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013012001.port.T = TC_143_156.port_b.T; CABI0CabiA013012001.port.T = TC_155_156.port_b.T; CABI0CabiA013012001.port.T = TC_156_0.port_a.T; CABI0CabiA013012001.port.T = TC_156_169.port_a.T; CABI0CabiA013012001.port.T = TC_156_242.port_a.T; CABI0CabiA013012001.port.T = TsCABI0CabiA013012001.port.T; TsCABI0CabiA012012001.port.Q_flow + (TC_154_155.port_b.Q_flow + (TC_142_155.port_b.Q_flow + (CABI0CabiA012012001.port.Q_flow + (TC_155_156.port_a.Q_flow + (TC_155_168.port_a.Q_flow + (TC_155_1435.port_a.Q_flow + TC_155_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012012001.port.T = TC_142_155.port_b.T; CABI0CabiA012012001.port.T = TC_154_155.port_b.T; CABI0CabiA012012001.port.T = TC_155_0.port_a.T; CABI0CabiA012012001.port.T = TC_155_1435.port_a.T; CABI0CabiA012012001.port.T = TC_155_156.port_a.T; CABI0CabiA012012001.port.T = TC_155_168.port_a.T; CABI0CabiA012012001.port.T = TsCABI0CabiA012012001.port.T; TsCABI0CabiA011012001.port.Q_flow + (TC_153_154.port_b.Q_flow + (TC_141_154.port_b.Q_flow + (CABI0CabiA011012001.port.Q_flow + (TC_154_155.port_a.Q_flow + (TC_154_167.port_a.Q_flow + (TC_154_804.port_a.Q_flow + TC_154_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011012001.port.T = TC_141_154.port_b.T; CABI0CabiA011012001.port.T = TC_153_154.port_b.T; CABI0CabiA011012001.port.T = TC_154_0.port_a.T; CABI0CabiA011012001.port.T = TC_154_155.port_a.T; CABI0CabiA011012001.port.T = TC_154_167.port_a.T; CABI0CabiA011012001.port.T = TC_154_804.port_a.T; CABI0CabiA011012001.port.T = TsCABI0CabiA011012001.port.T; TsCABI0CabiA010012001.port.Q_flow + (TC_152_153.port_b.Q_flow + (TC_140_153.port_b.Q_flow + (CABI0CabiA010012001.port.Q_flow + (TC_153_154.port_a.Q_flow + (TC_153_166.port_a.Q_flow + (TC_153_803.port_a.Q_flow + TC_153_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010012001.port.T = TC_140_153.port_b.T; CABI0CabiA010012001.port.T = TC_152_153.port_b.T; CABI0CabiA010012001.port.T = TC_153_0.port_a.T; CABI0CabiA010012001.port.T = TC_153_154.port_a.T; CABI0CabiA010012001.port.T = TC_153_166.port_a.T; CABI0CabiA010012001.port.T = TC_153_803.port_a.T; CABI0CabiA010012001.port.T = TsCABI0CabiA010012001.port.T; TsCABI0CabiA009012001.port.Q_flow + (TC_151_152.port_b.Q_flow + (TC_139_152.port_b.Q_flow + (CABI0CabiA009012001.port.Q_flow + (TC_152_153.port_a.Q_flow + (TC_152_165.port_a.Q_flow + (TC_152_802.port_a.Q_flow + TC_152_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009012001.port.T = TC_139_152.port_b.T; CABI0CabiA009012001.port.T = TC_151_152.port_b.T; CABI0CabiA009012001.port.T = TC_152_0.port_a.T; CABI0CabiA009012001.port.T = TC_152_153.port_a.T; CABI0CabiA009012001.port.T = TC_152_165.port_a.T; CABI0CabiA009012001.port.T = TC_152_802.port_a.T; CABI0CabiA009012001.port.T = TsCABI0CabiA009012001.port.T; TsCABI0CabiA008012001.port.Q_flow + (TC_150_151.port_b.Q_flow + (TC_138_151.port_b.Q_flow + (CABI0CabiA008012001.port.Q_flow + (TC_151_152.port_a.Q_flow + (TC_151_164.port_a.Q_flow + (TC_151_801.port_a.Q_flow + TC_151_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008012001.port.T = TC_138_151.port_b.T; CABI0CabiA008012001.port.T = TC_150_151.port_b.T; CABI0CabiA008012001.port.T = TC_151_0.port_a.T; CABI0CabiA008012001.port.T = TC_151_152.port_a.T; CABI0CabiA008012001.port.T = TC_151_164.port_a.T; CABI0CabiA008012001.port.T = TC_151_801.port_a.T; CABI0CabiA008012001.port.T = TsCABI0CabiA008012001.port.T; TsCABI0CabiA007012001.port.Q_flow + (TC_149_150.port_b.Q_flow + (TC_137_150.port_b.Q_flow + (CABI0CabiA007012001.port.Q_flow + (TC_150_151.port_a.Q_flow + (TC_150_163.port_a.Q_flow + (TC_150_800.port_a.Q_flow + TC_150_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007012001.port.T = TC_137_150.port_b.T; CABI0CabiA007012001.port.T = TC_149_150.port_b.T; CABI0CabiA007012001.port.T = TC_150_0.port_a.T; CABI0CabiA007012001.port.T = TC_150_151.port_a.T; CABI0CabiA007012001.port.T = TC_150_163.port_a.T; CABI0CabiA007012001.port.T = TC_150_800.port_a.T; CABI0CabiA007012001.port.T = TsCABI0CabiA007012001.port.T; TsCABI0CabiA006012001.port.Q_flow + (TC_148_149.port_b.Q_flow + (TC_136_149.port_b.Q_flow + (CABI0CabiA006012001.port.Q_flow + (TC_149_150.port_a.Q_flow + (TC_149_162.port_a.Q_flow + (TC_149_799.port_a.Q_flow + TC_149_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006012001.port.T = TC_136_149.port_b.T; CABI0CabiA006012001.port.T = TC_148_149.port_b.T; CABI0CabiA006012001.port.T = TC_149_0.port_a.T; CABI0CabiA006012001.port.T = TC_149_150.port_a.T; CABI0CabiA006012001.port.T = TC_149_162.port_a.T; CABI0CabiA006012001.port.T = TC_149_799.port_a.T; CABI0CabiA006012001.port.T = TsCABI0CabiA006012001.port.T; TsCABI0CabiA005012001.port.Q_flow + (TC_147_148.port_b.Q_flow + (TC_135_148.port_b.Q_flow + (CABI0CabiA005012001.port.Q_flow + (TC_148_149.port_a.Q_flow + (TC_148_161.port_a.Q_flow + (TC_148_798.port_a.Q_flow + TC_148_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005012001.port.T = TC_135_148.port_b.T; CABI0CabiA005012001.port.T = TC_147_148.port_b.T; CABI0CabiA005012001.port.T = TC_148_0.port_a.T; CABI0CabiA005012001.port.T = TC_148_149.port_a.T; CABI0CabiA005012001.port.T = TC_148_161.port_a.T; CABI0CabiA005012001.port.T = TC_148_798.port_a.T; CABI0CabiA005012001.port.T = TsCABI0CabiA005012001.port.T; TsCABI0CabiA004012001.port.Q_flow + (TC_146_147.port_b.Q_flow + (TC_134_147.port_b.Q_flow + (CABI0CabiA004012001.port.Q_flow + (TC_147_148.port_a.Q_flow + (TC_147_160.port_a.Q_flow + (TC_147_797.port_a.Q_flow + TC_147_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004012001.port.T = TC_134_147.port_b.T; CABI0CabiA004012001.port.T = TC_146_147.port_b.T; CABI0CabiA004012001.port.T = TC_147_0.port_a.T; CABI0CabiA004012001.port.T = TC_147_148.port_a.T; CABI0CabiA004012001.port.T = TC_147_160.port_a.T; CABI0CabiA004012001.port.T = TC_147_797.port_a.T; CABI0CabiA004012001.port.T = TsCABI0CabiA004012001.port.T; TsCABI0CabiA003012001.port.Q_flow + (TC_145_146.port_b.Q_flow + (TC_133_146.port_b.Q_flow + (CABI0CabiA003012001.port.Q_flow + (TC_146_147.port_a.Q_flow + (TC_146_159.port_a.Q_flow + (TC_146_1434.port_a.Q_flow + TC_146_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003012001.port.T = TC_133_146.port_b.T; CABI0CabiA003012001.port.T = TC_145_146.port_b.T; CABI0CabiA003012001.port.T = TC_146_0.port_a.T; CABI0CabiA003012001.port.T = TC_146_1434.port_a.T; CABI0CabiA003012001.port.T = TC_146_147.port_a.T; CABI0CabiA003012001.port.T = TC_146_159.port_a.T; CABI0CabiA003012001.port.T = TsCABI0CabiA003012001.port.T; TsCABI0CabiA002012001.port.Q_flow + (TC_144_145.port_b.Q_flow + (TC_132_145.port_b.Q_flow + (CABI0CabiA002012001.port.Q_flow + (TC_145_146.port_a.Q_flow + (TC_145_158.port_a.Q_flow + (TC_145_1433.port_a.Q_flow + TC_145_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002012001.port.T = TC_132_145.port_b.T; CABI0CabiA002012001.port.T = TC_144_145.port_b.T; CABI0CabiA002012001.port.T = TC_145_0.port_a.T; CABI0CabiA002012001.port.T = TC_145_1433.port_a.T; CABI0CabiA002012001.port.T = TC_145_146.port_a.T; CABI0CabiA002012001.port.T = TC_145_158.port_a.T; CABI0CabiA002012001.port.T = TsCABI0CabiA002012001.port.T; TsCABI0CabiA001012001.port.Q_flow + (TC_131_144.port_b.Q_flow + (CABI0CabiA001012001.port.Q_flow + (TC_144_145.port_a.Q_flow + (TC_144_157.port_a.Q_flow + (TC_144_241.port_a.Q_flow + TC_144_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001012001.port.T = TC_131_144.port_b.T; CABI0CabiA001012001.port.T = TC_144_0.port_a.T; CABI0CabiA001012001.port.T = TC_144_145.port_a.T; CABI0CabiA001012001.port.T = TC_144_157.port_a.T; CABI0CabiA001012001.port.T = TC_144_241.port_a.T; CABI0CabiA001012001.port.T = TsCABI0CabiA001012001.port.T; TsCABI0CabiA013011001.port.Q_flow + (TC_142_143.port_b.Q_flow + (TC_130_143.port_b.Q_flow + (CABI0CabiA013011001.port.Q_flow + (TC_143_156.port_a.Q_flow + (TC_143_240.port_a.Q_flow + TC_143_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013011001.port.T = TC_130_143.port_b.T; CABI0CabiA013011001.port.T = TC_142_143.port_b.T; CABI0CabiA013011001.port.T = TC_143_0.port_a.T; CABI0CabiA013011001.port.T = TC_143_156.port_a.T; CABI0CabiA013011001.port.T = TC_143_240.port_a.T; CABI0CabiA013011001.port.T = TsCABI0CabiA013011001.port.T; TsCABI0CabiA012011001.port.Q_flow + (TC_141_142.port_b.Q_flow + (TC_129_142.port_b.Q_flow + (CABI0CabiA012011001.port.Q_flow + (TC_142_143.port_a.Q_flow + (TC_142_155.port_a.Q_flow + (TC_142_1432.port_a.Q_flow + TC_142_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012011001.port.T = TC_129_142.port_b.T; CABI0CabiA012011001.port.T = TC_141_142.port_b.T; CABI0CabiA012011001.port.T = TC_142_0.port_a.T; CABI0CabiA012011001.port.T = TC_142_143.port_a.T; CABI0CabiA012011001.port.T = TC_142_1432.port_a.T; CABI0CabiA012011001.port.T = TC_142_155.port_a.T; CABI0CabiA012011001.port.T = TsCABI0CabiA012011001.port.T; TsCABI0CabiA011011001.port.Q_flow + (TC_140_141.port_b.Q_flow + (TC_128_141.port_b.Q_flow + (CABI0CabiA011011001.port.Q_flow + (TC_141_142.port_a.Q_flow + (TC_141_154.port_a.Q_flow + (TC_141_796.port_a.Q_flow + TC_141_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011011001.port.T = TC_128_141.port_b.T; CABI0CabiA011011001.port.T = TC_140_141.port_b.T; CABI0CabiA011011001.port.T = TC_141_0.port_a.T; CABI0CabiA011011001.port.T = TC_141_142.port_a.T; CABI0CabiA011011001.port.T = TC_141_154.port_a.T; CABI0CabiA011011001.port.T = TC_141_796.port_a.T; CABI0CabiA011011001.port.T = TsCABI0CabiA011011001.port.T; TsCABI0CabiA010011001.port.Q_flow + (TC_139_140.port_b.Q_flow + (TC_127_140.port_b.Q_flow + (CABI0CabiA010011001.port.Q_flow + (TC_140_141.port_a.Q_flow + (TC_140_153.port_a.Q_flow + (TC_140_795.port_a.Q_flow + TC_140_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010011001.port.T = TC_127_140.port_b.T; CABI0CabiA010011001.port.T = TC_139_140.port_b.T; CABI0CabiA010011001.port.T = TC_140_0.port_a.T; CABI0CabiA010011001.port.T = TC_140_141.port_a.T; CABI0CabiA010011001.port.T = TC_140_153.port_a.T; CABI0CabiA010011001.port.T = TC_140_795.port_a.T; CABI0CabiA010011001.port.T = TsCABI0CabiA010011001.port.T; TsCABI0CabiA009011001.port.Q_flow + (TC_138_139.port_b.Q_flow + (TC_126_139.port_b.Q_flow + (CABI0CabiA009011001.port.Q_flow + (TC_139_140.port_a.Q_flow + (TC_139_152.port_a.Q_flow + (TC_139_794.port_a.Q_flow + TC_139_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009011001.port.T = TC_126_139.port_b.T; CABI0CabiA009011001.port.T = TC_138_139.port_b.T; CABI0CabiA009011001.port.T = TC_139_0.port_a.T; CABI0CabiA009011001.port.T = TC_139_140.port_a.T; CABI0CabiA009011001.port.T = TC_139_152.port_a.T; CABI0CabiA009011001.port.T = TC_139_794.port_a.T; CABI0CabiA009011001.port.T = TsCABI0CabiA009011001.port.T; TsCABI0CabiA008011001.port.Q_flow + (TC_137_138.port_b.Q_flow + (TC_125_138.port_b.Q_flow + (CABI0CabiA008011001.port.Q_flow + (TC_138_139.port_a.Q_flow + (TC_138_151.port_a.Q_flow + (TC_138_793.port_a.Q_flow + TC_138_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008011001.port.T = TC_125_138.port_b.T; CABI0CabiA008011001.port.T = TC_137_138.port_b.T; CABI0CabiA008011001.port.T = TC_138_0.port_a.T; CABI0CabiA008011001.port.T = TC_138_139.port_a.T; CABI0CabiA008011001.port.T = TC_138_151.port_a.T; CABI0CabiA008011001.port.T = TC_138_793.port_a.T; CABI0CabiA008011001.port.T = TsCABI0CabiA008011001.port.T; TsCABI0CabiA007011001.port.Q_flow + (TC_136_137.port_b.Q_flow + (TC_124_137.port_b.Q_flow + (CABI0CabiA007011001.port.Q_flow + (TC_137_138.port_a.Q_flow + (TC_137_150.port_a.Q_flow + (TC_137_792.port_a.Q_flow + TC_137_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007011001.port.T = TC_124_137.port_b.T; CABI0CabiA007011001.port.T = TC_136_137.port_b.T; CABI0CabiA007011001.port.T = TC_137_0.port_a.T; CABI0CabiA007011001.port.T = TC_137_138.port_a.T; CABI0CabiA007011001.port.T = TC_137_150.port_a.T; CABI0CabiA007011001.port.T = TC_137_792.port_a.T; CABI0CabiA007011001.port.T = TsCABI0CabiA007011001.port.T; TsCABI0CabiA006011001.port.Q_flow + (TC_135_136.port_b.Q_flow + (TC_123_136.port_b.Q_flow + (CABI0CabiA006011001.port.Q_flow + (TC_136_137.port_a.Q_flow + (TC_136_149.port_a.Q_flow + (TC_136_791.port_a.Q_flow + TC_136_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006011001.port.T = TC_123_136.port_b.T; CABI0CabiA006011001.port.T = TC_135_136.port_b.T; CABI0CabiA006011001.port.T = TC_136_0.port_a.T; CABI0CabiA006011001.port.T = TC_136_137.port_a.T; CABI0CabiA006011001.port.T = TC_136_149.port_a.T; CABI0CabiA006011001.port.T = TC_136_791.port_a.T; CABI0CabiA006011001.port.T = TsCABI0CabiA006011001.port.T; TsCABI0CabiA005011001.port.Q_flow + (TC_134_135.port_b.Q_flow + (TC_122_135.port_b.Q_flow + (CABI0CabiA005011001.port.Q_flow + (TC_135_136.port_a.Q_flow + (TC_135_148.port_a.Q_flow + (TC_135_790.port_a.Q_flow + TC_135_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005011001.port.T = TC_122_135.port_b.T; CABI0CabiA005011001.port.T = TC_134_135.port_b.T; CABI0CabiA005011001.port.T = TC_135_0.port_a.T; CABI0CabiA005011001.port.T = TC_135_136.port_a.T; CABI0CabiA005011001.port.T = TC_135_148.port_a.T; CABI0CabiA005011001.port.T = TC_135_790.port_a.T; CABI0CabiA005011001.port.T = TsCABI0CabiA005011001.port.T; TsCABI0CabiA004011001.port.Q_flow + (TC_133_134.port_b.Q_flow + (TC_121_134.port_b.Q_flow + (CABI0CabiA004011001.port.Q_flow + (TC_134_135.port_a.Q_flow + (TC_134_147.port_a.Q_flow + (TC_134_789.port_a.Q_flow + TC_134_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004011001.port.T = TC_121_134.port_b.T; CABI0CabiA004011001.port.T = TC_133_134.port_b.T; CABI0CabiA004011001.port.T = TC_134_0.port_a.T; CABI0CabiA004011001.port.T = TC_134_135.port_a.T; CABI0CabiA004011001.port.T = TC_134_147.port_a.T; CABI0CabiA004011001.port.T = TC_134_789.port_a.T; CABI0CabiA004011001.port.T = TsCABI0CabiA004011001.port.T; TsCABI0CabiA003011001.port.Q_flow + (TC_132_133.port_b.Q_flow + (TC_120_133.port_b.Q_flow + (CABI0CabiA003011001.port.Q_flow + (TC_133_134.port_a.Q_flow + (TC_133_146.port_a.Q_flow + (TC_133_1431.port_a.Q_flow + TC_133_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003011001.port.T = TC_120_133.port_b.T; CABI0CabiA003011001.port.T = TC_132_133.port_b.T; CABI0CabiA003011001.port.T = TC_133_0.port_a.T; CABI0CabiA003011001.port.T = TC_133_134.port_a.T; CABI0CabiA003011001.port.T = TC_133_1431.port_a.T; CABI0CabiA003011001.port.T = TC_133_146.port_a.T; CABI0CabiA003011001.port.T = TsCABI0CabiA003011001.port.T; TsCABI0CabiA002011001.port.Q_flow + (TC_131_132.port_b.Q_flow + (TC_119_132.port_b.Q_flow + (CABI0CabiA002011001.port.Q_flow + (TC_132_133.port_a.Q_flow + (TC_132_145.port_a.Q_flow + (TC_132_1430.port_a.Q_flow + TC_132_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002011001.port.T = TC_119_132.port_b.T; CABI0CabiA002011001.port.T = TC_131_132.port_b.T; CABI0CabiA002011001.port.T = TC_132_0.port_a.T; CABI0CabiA002011001.port.T = TC_132_133.port_a.T; CABI0CabiA002011001.port.T = TC_132_1430.port_a.T; CABI0CabiA002011001.port.T = TC_132_145.port_a.T; CABI0CabiA002011001.port.T = TsCABI0CabiA002011001.port.T; TsCABI0CabiA001011001.port.Q_flow + (TC_118_131.port_b.Q_flow + (CABI0CabiA001011001.port.Q_flow + (TC_131_132.port_a.Q_flow + (TC_131_144.port_a.Q_flow + (TC_131_239.port_a.Q_flow + TC_131_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001011001.port.T = TC_118_131.port_b.T; CABI0CabiA001011001.port.T = TC_131_0.port_a.T; CABI0CabiA001011001.port.T = TC_131_132.port_a.T; CABI0CabiA001011001.port.T = TC_131_144.port_a.T; CABI0CabiA001011001.port.T = TC_131_239.port_a.T; CABI0CabiA001011001.port.T = TsCABI0CabiA001011001.port.T; TsCABI0CabiA013010001.port.Q_flow + (TC_129_130.port_b.Q_flow + (TC_117_130.port_b.Q_flow + (CABI0CabiA013010001.port.Q_flow + (TC_130_143.port_a.Q_flow + (TC_130_238.port_a.Q_flow + TC_130_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013010001.port.T = TC_117_130.port_b.T; CABI0CabiA013010001.port.T = TC_129_130.port_b.T; CABI0CabiA013010001.port.T = TC_130_0.port_a.T; CABI0CabiA013010001.port.T = TC_130_143.port_a.T; CABI0CabiA013010001.port.T = TC_130_238.port_a.T; CABI0CabiA013010001.port.T = TsCABI0CabiA013010001.port.T; TsCABI0CabiA012010001.port.Q_flow + (TC_128_129.port_b.Q_flow + (TC_116_129.port_b.Q_flow + (CABI0CabiA012010001.port.Q_flow + (TC_129_130.port_a.Q_flow + (TC_129_142.port_a.Q_flow + (TC_129_1429.port_a.Q_flow + TC_129_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012010001.port.T = TC_116_129.port_b.T; CABI0CabiA012010001.port.T = TC_128_129.port_b.T; CABI0CabiA012010001.port.T = TC_129_0.port_a.T; CABI0CabiA012010001.port.T = TC_129_130.port_a.T; CABI0CabiA012010001.port.T = TC_129_142.port_a.T; CABI0CabiA012010001.port.T = TC_129_1429.port_a.T; CABI0CabiA012010001.port.T = TsCABI0CabiA012010001.port.T; TsCABI0CabiA011010001.port.Q_flow + (TC_127_128.port_b.Q_flow + (TC_115_128.port_b.Q_flow + (CABI0CabiA011010001.port.Q_flow + (TC_128_129.port_a.Q_flow + (TC_128_141.port_a.Q_flow + (TC_128_788.port_a.Q_flow + TC_128_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011010001.port.T = TC_115_128.port_b.T; CABI0CabiA011010001.port.T = TC_127_128.port_b.T; CABI0CabiA011010001.port.T = TC_128_0.port_a.T; CABI0CabiA011010001.port.T = TC_128_129.port_a.T; CABI0CabiA011010001.port.T = TC_128_141.port_a.T; CABI0CabiA011010001.port.T = TC_128_788.port_a.T; CABI0CabiA011010001.port.T = TsCABI0CabiA011010001.port.T; TsCABI0CabiA010010001.port.Q_flow + (TC_126_127.port_b.Q_flow + (TC_114_127.port_b.Q_flow + (CABI0CabiA010010001.port.Q_flow + (TC_127_128.port_a.Q_flow + (TC_127_140.port_a.Q_flow + (TC_127_787.port_a.Q_flow + TC_127_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010010001.port.T = TC_114_127.port_b.T; CABI0CabiA010010001.port.T = TC_126_127.port_b.T; CABI0CabiA010010001.port.T = TC_127_0.port_a.T; CABI0CabiA010010001.port.T = TC_127_128.port_a.T; CABI0CabiA010010001.port.T = TC_127_140.port_a.T; CABI0CabiA010010001.port.T = TC_127_787.port_a.T; CABI0CabiA010010001.port.T = TsCABI0CabiA010010001.port.T; TsCABI0CabiA009010001.port.Q_flow + (TC_125_126.port_b.Q_flow + (TC_113_126.port_b.Q_flow + (CABI0CabiA009010001.port.Q_flow + (TC_126_127.port_a.Q_flow + (TC_126_139.port_a.Q_flow + (TC_126_786.port_a.Q_flow + TC_126_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009010001.port.T = TC_113_126.port_b.T; CABI0CabiA009010001.port.T = TC_125_126.port_b.T; CABI0CabiA009010001.port.T = TC_126_0.port_a.T; CABI0CabiA009010001.port.T = TC_126_127.port_a.T; CABI0CabiA009010001.port.T = TC_126_139.port_a.T; CABI0CabiA009010001.port.T = TC_126_786.port_a.T; CABI0CabiA009010001.port.T = TsCABI0CabiA009010001.port.T; TsCABI0CabiA008010001.port.Q_flow + (TC_124_125.port_b.Q_flow + (TC_112_125.port_b.Q_flow + (CABI0CabiA008010001.port.Q_flow + (TC_125_126.port_a.Q_flow + (TC_125_138.port_a.Q_flow + (TC_125_785.port_a.Q_flow + TC_125_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008010001.port.T = TC_112_125.port_b.T; CABI0CabiA008010001.port.T = TC_124_125.port_b.T; CABI0CabiA008010001.port.T = TC_125_0.port_a.T; CABI0CabiA008010001.port.T = TC_125_126.port_a.T; CABI0CabiA008010001.port.T = TC_125_138.port_a.T; CABI0CabiA008010001.port.T = TC_125_785.port_a.T; CABI0CabiA008010001.port.T = TsCABI0CabiA008010001.port.T; TsCABI0CabiA007010001.port.Q_flow + (TC_123_124.port_b.Q_flow + (TC_111_124.port_b.Q_flow + (CABI0CabiA007010001.port.Q_flow + (TC_124_125.port_a.Q_flow + (TC_124_137.port_a.Q_flow + (TC_124_784.port_a.Q_flow + TC_124_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007010001.port.T = TC_111_124.port_b.T; CABI0CabiA007010001.port.T = TC_123_124.port_b.T; CABI0CabiA007010001.port.T = TC_124_0.port_a.T; CABI0CabiA007010001.port.T = TC_124_125.port_a.T; CABI0CabiA007010001.port.T = TC_124_137.port_a.T; CABI0CabiA007010001.port.T = TC_124_784.port_a.T; CABI0CabiA007010001.port.T = TsCABI0CabiA007010001.port.T; TsCABI0CabiA006010001.port.Q_flow + (TC_122_123.port_b.Q_flow + (TC_110_123.port_b.Q_flow + (CABI0CabiA006010001.port.Q_flow + (TC_123_124.port_a.Q_flow + (TC_123_136.port_a.Q_flow + (TC_123_783.port_a.Q_flow + TC_123_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006010001.port.T = TC_110_123.port_b.T; CABI0CabiA006010001.port.T = TC_122_123.port_b.T; CABI0CabiA006010001.port.T = TC_123_0.port_a.T; CABI0CabiA006010001.port.T = TC_123_124.port_a.T; CABI0CabiA006010001.port.T = TC_123_136.port_a.T; CABI0CabiA006010001.port.T = TC_123_783.port_a.T; CABI0CabiA006010001.port.T = TsCABI0CabiA006010001.port.T; TsCABI0CabiA005010001.port.Q_flow + (TC_121_122.port_b.Q_flow + (TC_109_122.port_b.Q_flow + (CABI0CabiA005010001.port.Q_flow + (TC_122_123.port_a.Q_flow + (TC_122_135.port_a.Q_flow + (TC_122_782.port_a.Q_flow + TC_122_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005010001.port.T = TC_109_122.port_b.T; CABI0CabiA005010001.port.T = TC_121_122.port_b.T; CABI0CabiA005010001.port.T = TC_122_0.port_a.T; CABI0CabiA005010001.port.T = TC_122_123.port_a.T; CABI0CabiA005010001.port.T = TC_122_135.port_a.T; CABI0CabiA005010001.port.T = TC_122_782.port_a.T; CABI0CabiA005010001.port.T = TsCABI0CabiA005010001.port.T; TsCABI0CabiA004010001.port.Q_flow + (TC_120_121.port_b.Q_flow + (TC_108_121.port_b.Q_flow + (CABI0CabiA004010001.port.Q_flow + (TC_121_122.port_a.Q_flow + (TC_121_134.port_a.Q_flow + (TC_121_781.port_a.Q_flow + TC_121_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004010001.port.T = TC_108_121.port_b.T; CABI0CabiA004010001.port.T = TC_120_121.port_b.T; CABI0CabiA004010001.port.T = TC_121_0.port_a.T; CABI0CabiA004010001.port.T = TC_121_122.port_a.T; CABI0CabiA004010001.port.T = TC_121_134.port_a.T; CABI0CabiA004010001.port.T = TC_121_781.port_a.T; CABI0CabiA004010001.port.T = TsCABI0CabiA004010001.port.T; TsCABI0CabiA003010001.port.Q_flow + (TC_119_120.port_b.Q_flow + (TC_107_120.port_b.Q_flow + (CABI0CabiA003010001.port.Q_flow + (TC_120_121.port_a.Q_flow + (TC_120_133.port_a.Q_flow + (TC_120_1428.port_a.Q_flow + TC_120_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003010001.port.T = TC_107_120.port_b.T; CABI0CabiA003010001.port.T = TC_119_120.port_b.T; CABI0CabiA003010001.port.T = TC_120_0.port_a.T; CABI0CabiA003010001.port.T = TC_120_121.port_a.T; CABI0CabiA003010001.port.T = TC_120_133.port_a.T; CABI0CabiA003010001.port.T = TC_120_1428.port_a.T; CABI0CabiA003010001.port.T = TsCABI0CabiA003010001.port.T; TsCABI0CabiA002010001.port.Q_flow + (TC_118_119.port_b.Q_flow + (TC_106_119.port_b.Q_flow + (CABI0CabiA002010001.port.Q_flow + (TC_119_120.port_a.Q_flow + (TC_119_132.port_a.Q_flow + (TC_119_1427.port_a.Q_flow + TC_119_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002010001.port.T = TC_106_119.port_b.T; CABI0CabiA002010001.port.T = TC_118_119.port_b.T; CABI0CabiA002010001.port.T = TC_119_0.port_a.T; CABI0CabiA002010001.port.T = TC_119_120.port_a.T; CABI0CabiA002010001.port.T = TC_119_132.port_a.T; CABI0CabiA002010001.port.T = TC_119_1427.port_a.T; CABI0CabiA002010001.port.T = TsCABI0CabiA002010001.port.T; TsCABI0CabiA001010001.port.Q_flow + (TC_105_118.port_b.Q_flow + (CABI0CabiA001010001.port.Q_flow + (TC_118_119.port_a.Q_flow + (TC_118_131.port_a.Q_flow + (TC_118_237.port_a.Q_flow + TC_118_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001010001.port.T = TC_105_118.port_b.T; CABI0CabiA001010001.port.T = TC_118_0.port_a.T; CABI0CabiA001010001.port.T = TC_118_119.port_a.T; CABI0CabiA001010001.port.T = TC_118_131.port_a.T; CABI0CabiA001010001.port.T = TC_118_237.port_a.T; CABI0CabiA001010001.port.T = TsCABI0CabiA001010001.port.T; TsCABI0CabiA013009001.port.Q_flow + (TC_116_117.port_b.Q_flow + (TC_104_117.port_b.Q_flow + (CABI0CabiA013009001.port.Q_flow + (TC_117_130.port_a.Q_flow + (TC_117_236.port_a.Q_flow + TC_117_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013009001.port.T = TC_104_117.port_b.T; CABI0CabiA013009001.port.T = TC_116_117.port_b.T; CABI0CabiA013009001.port.T = TC_117_0.port_a.T; CABI0CabiA013009001.port.T = TC_117_130.port_a.T; CABI0CabiA013009001.port.T = TC_117_236.port_a.T; CABI0CabiA013009001.port.T = TsCABI0CabiA013009001.port.T; TsCABI0CabiA012009001.port.Q_flow + (TC_115_116.port_b.Q_flow + (TC_103_116.port_b.Q_flow + (CABI0CabiA012009001.port.Q_flow + (TC_116_117.port_a.Q_flow + (TC_116_129.port_a.Q_flow + (TC_116_1426.port_a.Q_flow + TC_116_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012009001.port.T = TC_103_116.port_b.T; CABI0CabiA012009001.port.T = TC_115_116.port_b.T; CABI0CabiA012009001.port.T = TC_116_0.port_a.T; CABI0CabiA012009001.port.T = TC_116_117.port_a.T; CABI0CabiA012009001.port.T = TC_116_129.port_a.T; CABI0CabiA012009001.port.T = TC_116_1426.port_a.T; CABI0CabiA012009001.port.T = TsCABI0CabiA012009001.port.T; TsCABI0CabiA011009001.port.Q_flow + (TC_114_115.port_b.Q_flow + (TC_102_115.port_b.Q_flow + (CABI0CabiA011009001.port.Q_flow + (TC_115_116.port_a.Q_flow + (TC_115_128.port_a.Q_flow + (TC_115_780.port_a.Q_flow + TC_115_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011009001.port.T = TC_102_115.port_b.T; CABI0CabiA011009001.port.T = TC_114_115.port_b.T; CABI0CabiA011009001.port.T = TC_115_0.port_a.T; CABI0CabiA011009001.port.T = TC_115_116.port_a.T; CABI0CabiA011009001.port.T = TC_115_128.port_a.T; CABI0CabiA011009001.port.T = TC_115_780.port_a.T; CABI0CabiA011009001.port.T = TsCABI0CabiA011009001.port.T; TsCABI0CabiA010009001.port.Q_flow + (TC_113_114.port_b.Q_flow + (TC_101_114.port_b.Q_flow + (CABI0CabiA010009001.port.Q_flow + (TC_114_115.port_a.Q_flow + (TC_114_127.port_a.Q_flow + (TC_114_779.port_a.Q_flow + TC_114_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010009001.port.T = TC_101_114.port_b.T; CABI0CabiA010009001.port.T = TC_113_114.port_b.T; CABI0CabiA010009001.port.T = TC_114_0.port_a.T; CABI0CabiA010009001.port.T = TC_114_115.port_a.T; CABI0CabiA010009001.port.T = TC_114_127.port_a.T; CABI0CabiA010009001.port.T = TC_114_779.port_a.T; CABI0CabiA010009001.port.T = TsCABI0CabiA010009001.port.T; TsCABI0CabiA009009001.port.Q_flow + (TC_112_113.port_b.Q_flow + (TC_100_113.port_b.Q_flow + (CABI0CabiA009009001.port.Q_flow + (TC_113_114.port_a.Q_flow + (TC_113_126.port_a.Q_flow + (TC_113_778.port_a.Q_flow + TC_113_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009009001.port.T = TC_100_113.port_b.T; CABI0CabiA009009001.port.T = TC_112_113.port_b.T; CABI0CabiA009009001.port.T = TC_113_0.port_a.T; CABI0CabiA009009001.port.T = TC_113_114.port_a.T; CABI0CabiA009009001.port.T = TC_113_126.port_a.T; CABI0CabiA009009001.port.T = TC_113_778.port_a.T; CABI0CabiA009009001.port.T = TsCABI0CabiA009009001.port.T; TsCABI0CabiA008009001.port.Q_flow + (TC_111_112.port_b.Q_flow + (TC_99_112.port_b.Q_flow + (CABI0CabiA008009001.port.Q_flow + (TC_112_113.port_a.Q_flow + (TC_112_125.port_a.Q_flow + (TC_112_777.port_a.Q_flow + TC_112_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008009001.port.T = TC_111_112.port_b.T; CABI0CabiA008009001.port.T = TC_112_0.port_a.T; CABI0CabiA008009001.port.T = TC_112_113.port_a.T; CABI0CabiA008009001.port.T = TC_112_125.port_a.T; CABI0CabiA008009001.port.T = TC_112_777.port_a.T; CABI0CabiA008009001.port.T = TC_99_112.port_b.T; CABI0CabiA008009001.port.T = TsCABI0CabiA008009001.port.T; TsCABI0CabiA007009001.port.Q_flow + (TC_110_111.port_b.Q_flow + (TC_98_111.port_b.Q_flow + (CABI0CabiA007009001.port.Q_flow + (TC_111_112.port_a.Q_flow + (TC_111_124.port_a.Q_flow + (TC_111_776.port_a.Q_flow + TC_111_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007009001.port.T = TC_110_111.port_b.T; CABI0CabiA007009001.port.T = TC_111_0.port_a.T; CABI0CabiA007009001.port.T = TC_111_112.port_a.T; CABI0CabiA007009001.port.T = TC_111_124.port_a.T; CABI0CabiA007009001.port.T = TC_111_776.port_a.T; CABI0CabiA007009001.port.T = TC_98_111.port_b.T; CABI0CabiA007009001.port.T = TsCABI0CabiA007009001.port.T; TsCABI0CabiA006009001.port.Q_flow + (TC_109_110.port_b.Q_flow + (TC_97_110.port_b.Q_flow + (CABI0CabiA006009001.port.Q_flow + (TC_110_111.port_a.Q_flow + (TC_110_123.port_a.Q_flow + (TC_110_775.port_a.Q_flow + TC_110_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006009001.port.T = TC_109_110.port_b.T; CABI0CabiA006009001.port.T = TC_110_0.port_a.T; CABI0CabiA006009001.port.T = TC_110_111.port_a.T; CABI0CabiA006009001.port.T = TC_110_123.port_a.T; CABI0CabiA006009001.port.T = TC_110_775.port_a.T; CABI0CabiA006009001.port.T = TC_97_110.port_b.T; CABI0CabiA006009001.port.T = TsCABI0CabiA006009001.port.T; TsCABI0CabiA005009001.port.Q_flow + (TC_108_109.port_b.Q_flow + (TC_96_109.port_b.Q_flow + (CABI0CabiA005009001.port.Q_flow + (TC_109_110.port_a.Q_flow + (TC_109_122.port_a.Q_flow + (TC_109_774.port_a.Q_flow + TC_109_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005009001.port.T = TC_108_109.port_b.T; CABI0CabiA005009001.port.T = TC_109_0.port_a.T; CABI0CabiA005009001.port.T = TC_109_110.port_a.T; CABI0CabiA005009001.port.T = TC_109_122.port_a.T; CABI0CabiA005009001.port.T = TC_109_774.port_a.T; CABI0CabiA005009001.port.T = TC_96_109.port_b.T; CABI0CabiA005009001.port.T = TsCABI0CabiA005009001.port.T; TsCABI0CabiA004009001.port.Q_flow + (TC_107_108.port_b.Q_flow + (TC_95_108.port_b.Q_flow + (CABI0CabiA004009001.port.Q_flow + (TC_108_109.port_a.Q_flow + (TC_108_121.port_a.Q_flow + (TC_108_773.port_a.Q_flow + TC_108_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004009001.port.T = TC_107_108.port_b.T; CABI0CabiA004009001.port.T = TC_108_0.port_a.T; CABI0CabiA004009001.port.T = TC_108_109.port_a.T; CABI0CabiA004009001.port.T = TC_108_121.port_a.T; CABI0CabiA004009001.port.T = TC_108_773.port_a.T; CABI0CabiA004009001.port.T = TC_95_108.port_b.T; CABI0CabiA004009001.port.T = TsCABI0CabiA004009001.port.T; TsCABI0CabiA003009001.port.Q_flow + (TC_106_107.port_b.Q_flow + (TC_94_107.port_b.Q_flow + (CABI0CabiA003009001.port.Q_flow + (TC_107_108.port_a.Q_flow + (TC_107_120.port_a.Q_flow + (TC_107_1425.port_a.Q_flow + TC_107_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003009001.port.T = TC_106_107.port_b.T; CABI0CabiA003009001.port.T = TC_107_0.port_a.T; CABI0CabiA003009001.port.T = TC_107_108.port_a.T; CABI0CabiA003009001.port.T = TC_107_120.port_a.T; CABI0CabiA003009001.port.T = TC_107_1425.port_a.T; CABI0CabiA003009001.port.T = TC_94_107.port_b.T; CABI0CabiA003009001.port.T = TsCABI0CabiA003009001.port.T; TsCABI0CabiA002009001.port.Q_flow + (TC_105_106.port_b.Q_flow + (TC_93_106.port_b.Q_flow + (CABI0CabiA002009001.port.Q_flow + (TC_106_107.port_a.Q_flow + (TC_106_119.port_a.Q_flow + (TC_106_1424.port_a.Q_flow + TC_106_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002009001.port.T = TC_105_106.port_b.T; CABI0CabiA002009001.port.T = TC_106_0.port_a.T; CABI0CabiA002009001.port.T = TC_106_107.port_a.T; CABI0CabiA002009001.port.T = TC_106_119.port_a.T; CABI0CabiA002009001.port.T = TC_106_1424.port_a.T; CABI0CabiA002009001.port.T = TC_93_106.port_b.T; CABI0CabiA002009001.port.T = TsCABI0CabiA002009001.port.T; TsCABI0CabiA001009001.port.Q_flow + (TC_92_105.port_b.Q_flow + (CABI0CabiA001009001.port.Q_flow + (TC_105_106.port_a.Q_flow + (TC_105_118.port_a.Q_flow + (TC_105_235.port_a.Q_flow + TC_105_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001009001.port.T = TC_105_0.port_a.T; CABI0CabiA001009001.port.T = TC_105_106.port_a.T; CABI0CabiA001009001.port.T = TC_105_118.port_a.T; CABI0CabiA001009001.port.T = TC_105_235.port_a.T; CABI0CabiA001009001.port.T = TC_92_105.port_b.T; CABI0CabiA001009001.port.T = TsCABI0CabiA001009001.port.T; TsCABI0CabiA013008001.port.Q_flow + (TC_103_104.port_b.Q_flow + (TC_91_104.port_b.Q_flow + (CABI0CabiA013008001.port.Q_flow + (TC_104_117.port_a.Q_flow + (TC_104_234.port_a.Q_flow + TC_104_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013008001.port.T = TC_103_104.port_b.T; CABI0CabiA013008001.port.T = TC_104_0.port_a.T; CABI0CabiA013008001.port.T = TC_104_117.port_a.T; CABI0CabiA013008001.port.T = TC_104_234.port_a.T; CABI0CabiA013008001.port.T = TC_91_104.port_b.T; CABI0CabiA013008001.port.T = TsCABI0CabiA013008001.port.T; TsCABI0CabiA012008001.port.Q_flow + (TC_102_103.port_b.Q_flow + (TC_90_103.port_b.Q_flow + (CABI0CabiA012008001.port.Q_flow + (TC_103_104.port_a.Q_flow + (TC_103_116.port_a.Q_flow + (TC_103_1423.port_a.Q_flow + TC_103_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012008001.port.T = TC_102_103.port_b.T; CABI0CabiA012008001.port.T = TC_103_0.port_a.T; CABI0CabiA012008001.port.T = TC_103_104.port_a.T; CABI0CabiA012008001.port.T = TC_103_116.port_a.T; CABI0CabiA012008001.port.T = TC_103_1423.port_a.T; CABI0CabiA012008001.port.T = TC_90_103.port_b.T; CABI0CabiA012008001.port.T = TsCABI0CabiA012008001.port.T; TsCABI0CabiA011008001.port.Q_flow + (TC_101_102.port_b.Q_flow + (TC_89_102.port_b.Q_flow + (CABI0CabiA011008001.port.Q_flow + (TC_102_103.port_a.Q_flow + (TC_102_115.port_a.Q_flow + (TC_102_772.port_a.Q_flow + TC_102_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011008001.port.T = TC_101_102.port_b.T; CABI0CabiA011008001.port.T = TC_102_0.port_a.T; CABI0CabiA011008001.port.T = TC_102_103.port_a.T; CABI0CabiA011008001.port.T = TC_102_115.port_a.T; CABI0CabiA011008001.port.T = TC_102_772.port_a.T; CABI0CabiA011008001.port.T = TC_89_102.port_b.T; CABI0CabiA011008001.port.T = TsCABI0CabiA011008001.port.T; TsCABI0CabiA010008001.port.Q_flow + (TC_100_101.port_b.Q_flow + (TC_88_101.port_b.Q_flow + (CABI0CabiA010008001.port.Q_flow + (TC_101_102.port_a.Q_flow + (TC_101_114.port_a.Q_flow + (TC_101_771.port_a.Q_flow + TC_101_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010008001.port.T = TC_100_101.port_b.T; CABI0CabiA010008001.port.T = TC_101_0.port_a.T; CABI0CabiA010008001.port.T = TC_101_102.port_a.T; CABI0CabiA010008001.port.T = TC_101_114.port_a.T; CABI0CabiA010008001.port.T = TC_101_771.port_a.T; CABI0CabiA010008001.port.T = TC_88_101.port_b.T; CABI0CabiA010008001.port.T = TsCABI0CabiA010008001.port.T; TsCABI0CabiA009008001.port.Q_flow + (TC_99_100.port_b.Q_flow + (TC_87_100.port_b.Q_flow + (CABI0CabiA009008001.port.Q_flow + (TC_100_101.port_a.Q_flow + (TC_100_113.port_a.Q_flow + (TC_100_770.port_a.Q_flow + TC_100_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009008001.port.T = TC_100_0.port_a.T; CABI0CabiA009008001.port.T = TC_100_101.port_a.T; CABI0CabiA009008001.port.T = TC_100_113.port_a.T; CABI0CabiA009008001.port.T = TC_100_770.port_a.T; CABI0CabiA009008001.port.T = TC_87_100.port_b.T; CABI0CabiA009008001.port.T = TC_99_100.port_b.T; CABI0CabiA009008001.port.T = TsCABI0CabiA009008001.port.T; TsCABI0CabiA008008001.port.Q_flow + (TC_98_99.port_b.Q_flow + (TC_86_99.port_b.Q_flow + (CABI0CabiA008008001.port.Q_flow + (TC_99_100.port_a.Q_flow + (TC_99_112.port_a.Q_flow + (TC_99_769.port_a.Q_flow + TC_99_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008008001.port.T = TC_86_99.port_b.T; CABI0CabiA008008001.port.T = TC_98_99.port_b.T; CABI0CabiA008008001.port.T = TC_99_0.port_a.T; CABI0CabiA008008001.port.T = TC_99_100.port_a.T; CABI0CabiA008008001.port.T = TC_99_112.port_a.T; CABI0CabiA008008001.port.T = TC_99_769.port_a.T; CABI0CabiA008008001.port.T = TsCABI0CabiA008008001.port.T; TsCABI0CabiA007008001.port.Q_flow + (TC_97_98.port_b.Q_flow + (TC_85_98.port_b.Q_flow + (CABI0CabiA007008001.port.Q_flow + (TC_98_99.port_a.Q_flow + (TC_98_111.port_a.Q_flow + (TC_98_768.port_a.Q_flow + TC_98_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007008001.port.T = TC_85_98.port_b.T; CABI0CabiA007008001.port.T = TC_97_98.port_b.T; CABI0CabiA007008001.port.T = TC_98_0.port_a.T; CABI0CabiA007008001.port.T = TC_98_111.port_a.T; CABI0CabiA007008001.port.T = TC_98_768.port_a.T; CABI0CabiA007008001.port.T = TC_98_99.port_a.T; CABI0CabiA007008001.port.T = TsCABI0CabiA007008001.port.T; TsCABI0CabiA006008001.port.Q_flow + (TC_96_97.port_b.Q_flow + (TC_84_97.port_b.Q_flow + (CABI0CabiA006008001.port.Q_flow + (TC_97_98.port_a.Q_flow + (TC_97_110.port_a.Q_flow + (TC_97_767.port_a.Q_flow + TC_97_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006008001.port.T = TC_84_97.port_b.T; CABI0CabiA006008001.port.T = TC_96_97.port_b.T; CABI0CabiA006008001.port.T = TC_97_0.port_a.T; CABI0CabiA006008001.port.T = TC_97_110.port_a.T; CABI0CabiA006008001.port.T = TC_97_767.port_a.T; CABI0CabiA006008001.port.T = TC_97_98.port_a.T; CABI0CabiA006008001.port.T = TsCABI0CabiA006008001.port.T; TsCABI0CabiA005008001.port.Q_flow + (TC_95_96.port_b.Q_flow + (TC_83_96.port_b.Q_flow + (CABI0CabiA005008001.port.Q_flow + (TC_96_97.port_a.Q_flow + (TC_96_109.port_a.Q_flow + (TC_96_766.port_a.Q_flow + TC_96_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005008001.port.T = TC_83_96.port_b.T; CABI0CabiA005008001.port.T = TC_95_96.port_b.T; CABI0CabiA005008001.port.T = TC_96_0.port_a.T; CABI0CabiA005008001.port.T = TC_96_109.port_a.T; CABI0CabiA005008001.port.T = TC_96_766.port_a.T; CABI0CabiA005008001.port.T = TC_96_97.port_a.T; CABI0CabiA005008001.port.T = TsCABI0CabiA005008001.port.T; TsCABI0CabiA004008001.port.Q_flow + (TC_94_95.port_b.Q_flow + (TC_82_95.port_b.Q_flow + (CABI0CabiA004008001.port.Q_flow + (TC_95_96.port_a.Q_flow + (TC_95_108.port_a.Q_flow + (TC_95_765.port_a.Q_flow + TC_95_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004008001.port.T = TC_82_95.port_b.T; CABI0CabiA004008001.port.T = TC_94_95.port_b.T; CABI0CabiA004008001.port.T = TC_95_0.port_a.T; CABI0CabiA004008001.port.T = TC_95_108.port_a.T; CABI0CabiA004008001.port.T = TC_95_765.port_a.T; CABI0CabiA004008001.port.T = TC_95_96.port_a.T; CABI0CabiA004008001.port.T = TsCABI0CabiA004008001.port.T; TsCABI0CabiA003008001.port.Q_flow + (TC_93_94.port_b.Q_flow + (TC_81_94.port_b.Q_flow + (CABI0CabiA003008001.port.Q_flow + (TC_94_95.port_a.Q_flow + (TC_94_107.port_a.Q_flow + (TC_94_1422.port_a.Q_flow + TC_94_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003008001.port.T = TC_81_94.port_b.T; CABI0CabiA003008001.port.T = TC_93_94.port_b.T; CABI0CabiA003008001.port.T = TC_94_0.port_a.T; CABI0CabiA003008001.port.T = TC_94_107.port_a.T; CABI0CabiA003008001.port.T = TC_94_1422.port_a.T; CABI0CabiA003008001.port.T = TC_94_95.port_a.T; CABI0CabiA003008001.port.T = TsCABI0CabiA003008001.port.T; TsCABI0CabiA002008001.port.Q_flow + (TC_92_93.port_b.Q_flow + (TC_80_93.port_b.Q_flow + (CABI0CabiA002008001.port.Q_flow + (TC_93_94.port_a.Q_flow + (TC_93_106.port_a.Q_flow + (TC_93_1421.port_a.Q_flow + TC_93_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002008001.port.T = TC_80_93.port_b.T; CABI0CabiA002008001.port.T = TC_92_93.port_b.T; CABI0CabiA002008001.port.T = TC_93_0.port_a.T; CABI0CabiA002008001.port.T = TC_93_106.port_a.T; CABI0CabiA002008001.port.T = TC_93_1421.port_a.T; CABI0CabiA002008001.port.T = TC_93_94.port_a.T; CABI0CabiA002008001.port.T = TsCABI0CabiA002008001.port.T; TsCABI0CabiA001008001.port.Q_flow + (TC_79_92.port_b.Q_flow + (CABI0CabiA001008001.port.Q_flow + (TC_92_93.port_a.Q_flow + (TC_92_105.port_a.Q_flow + (TC_92_233.port_a.Q_flow + TC_92_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001008001.port.T = TC_79_92.port_b.T; CABI0CabiA001008001.port.T = TC_92_0.port_a.T; CABI0CabiA001008001.port.T = TC_92_105.port_a.T; CABI0CabiA001008001.port.T = TC_92_233.port_a.T; CABI0CabiA001008001.port.T = TC_92_93.port_a.T; CABI0CabiA001008001.port.T = TsCABI0CabiA001008001.port.T; TsCABI0CabiA013007001.port.Q_flow + (TC_90_91.port_b.Q_flow + (TC_78_91.port_b.Q_flow + (CABI0CabiA013007001.port.Q_flow + (TC_91_104.port_a.Q_flow + (TC_91_232.port_a.Q_flow + TC_91_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013007001.port.T = TC_78_91.port_b.T; CABI0CabiA013007001.port.T = TC_90_91.port_b.T; CABI0CabiA013007001.port.T = TC_91_0.port_a.T; CABI0CabiA013007001.port.T = TC_91_104.port_a.T; CABI0CabiA013007001.port.T = TC_91_232.port_a.T; CABI0CabiA013007001.port.T = TsCABI0CabiA013007001.port.T; TsCABI0CabiA012007001.port.Q_flow + (TC_89_90.port_b.Q_flow + (TC_77_90.port_b.Q_flow + (CABI0CabiA012007001.port.Q_flow + (TC_90_91.port_a.Q_flow + (TC_90_103.port_a.Q_flow + (TC_90_1420.port_a.Q_flow + TC_90_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012007001.port.T = TC_77_90.port_b.T; CABI0CabiA012007001.port.T = TC_89_90.port_b.T; CABI0CabiA012007001.port.T = TC_90_0.port_a.T; CABI0CabiA012007001.port.T = TC_90_103.port_a.T; CABI0CabiA012007001.port.T = TC_90_1420.port_a.T; CABI0CabiA012007001.port.T = TC_90_91.port_a.T; CABI0CabiA012007001.port.T = TsCABI0CabiA012007001.port.T; TsCABI0CabiA011007001.port.Q_flow + (TC_88_89.port_b.Q_flow + (TC_76_89.port_b.Q_flow + (CABI0CabiA011007001.port.Q_flow + (TC_89_90.port_a.Q_flow + (TC_89_102.port_a.Q_flow + (TC_89_764.port_a.Q_flow + TC_89_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011007001.port.T = TC_76_89.port_b.T; CABI0CabiA011007001.port.T = TC_88_89.port_b.T; CABI0CabiA011007001.port.T = TC_89_0.port_a.T; CABI0CabiA011007001.port.T = TC_89_102.port_a.T; CABI0CabiA011007001.port.T = TC_89_764.port_a.T; CABI0CabiA011007001.port.T = TC_89_90.port_a.T; CABI0CabiA011007001.port.T = TsCABI0CabiA011007001.port.T; TsCABI0CabiA010007001.port.Q_flow + (TC_87_88.port_b.Q_flow + (TC_75_88.port_b.Q_flow + (CABI0CabiA010007001.port.Q_flow + (TC_88_89.port_a.Q_flow + (TC_88_101.port_a.Q_flow + (TC_88_763.port_a.Q_flow + TC_88_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010007001.port.T = TC_75_88.port_b.T; CABI0CabiA010007001.port.T = TC_87_88.port_b.T; CABI0CabiA010007001.port.T = TC_88_0.port_a.T; CABI0CabiA010007001.port.T = TC_88_101.port_a.T; CABI0CabiA010007001.port.T = TC_88_763.port_a.T; CABI0CabiA010007001.port.T = TC_88_89.port_a.T; CABI0CabiA010007001.port.T = TsCABI0CabiA010007001.port.T; TsCABI0CabiA009007001.port.Q_flow + (TC_86_87.port_b.Q_flow + (TC_74_87.port_b.Q_flow + (CABI0CabiA009007001.port.Q_flow + (TC_87_88.port_a.Q_flow + (TC_87_100.port_a.Q_flow + (TC_87_762.port_a.Q_flow + TC_87_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009007001.port.T = TC_74_87.port_b.T; CABI0CabiA009007001.port.T = TC_86_87.port_b.T; CABI0CabiA009007001.port.T = TC_87_0.port_a.T; CABI0CabiA009007001.port.T = TC_87_100.port_a.T; CABI0CabiA009007001.port.T = TC_87_762.port_a.T; CABI0CabiA009007001.port.T = TC_87_88.port_a.T; CABI0CabiA009007001.port.T = TsCABI0CabiA009007001.port.T; TsCABI0CabiA008007001.port.Q_flow + (TC_85_86.port_b.Q_flow + (TC_73_86.port_b.Q_flow + (CABI0CabiA008007001.port.Q_flow + (TC_86_87.port_a.Q_flow + (TC_86_99.port_a.Q_flow + (TC_86_761.port_a.Q_flow + TC_86_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008007001.port.T = TC_73_86.port_b.T; CABI0CabiA008007001.port.T = TC_85_86.port_b.T; CABI0CabiA008007001.port.T = TC_86_0.port_a.T; CABI0CabiA008007001.port.T = TC_86_761.port_a.T; CABI0CabiA008007001.port.T = TC_86_87.port_a.T; CABI0CabiA008007001.port.T = TC_86_99.port_a.T; CABI0CabiA008007001.port.T = TsCABI0CabiA008007001.port.T; TsCABI0CabiA007007001.port.Q_flow + (TC_84_85.port_b.Q_flow + (TC_72_85.port_b.Q_flow + (CABI0CabiA007007001.port.Q_flow + (TC_85_86.port_a.Q_flow + (TC_85_98.port_a.Q_flow + (TC_85_760.port_a.Q_flow + TC_85_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007007001.port.T = TC_72_85.port_b.T; CABI0CabiA007007001.port.T = TC_84_85.port_b.T; CABI0CabiA007007001.port.T = TC_85_0.port_a.T; CABI0CabiA007007001.port.T = TC_85_760.port_a.T; CABI0CabiA007007001.port.T = TC_85_86.port_a.T; CABI0CabiA007007001.port.T = TC_85_98.port_a.T; CABI0CabiA007007001.port.T = TsCABI0CabiA007007001.port.T; TsCABI0CabiA006007001.port.Q_flow + (TC_83_84.port_b.Q_flow + (TC_71_84.port_b.Q_flow + (CABI0CabiA006007001.port.Q_flow + (TC_84_85.port_a.Q_flow + (TC_84_97.port_a.Q_flow + (TC_84_759.port_a.Q_flow + TC_84_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006007001.port.T = TC_71_84.port_b.T; CABI0CabiA006007001.port.T = TC_83_84.port_b.T; CABI0CabiA006007001.port.T = TC_84_0.port_a.T; CABI0CabiA006007001.port.T = TC_84_759.port_a.T; CABI0CabiA006007001.port.T = TC_84_85.port_a.T; CABI0CabiA006007001.port.T = TC_84_97.port_a.T; CABI0CabiA006007001.port.T = TsCABI0CabiA006007001.port.T; TsCABI0CabiA005007001.port.Q_flow + (TC_82_83.port_b.Q_flow + (TC_70_83.port_b.Q_flow + (CABI0CabiA005007001.port.Q_flow + (TC_83_84.port_a.Q_flow + (TC_83_96.port_a.Q_flow + (TC_83_758.port_a.Q_flow + TC_83_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005007001.port.T = TC_70_83.port_b.T; CABI0CabiA005007001.port.T = TC_82_83.port_b.T; CABI0CabiA005007001.port.T = TC_83_0.port_a.T; CABI0CabiA005007001.port.T = TC_83_758.port_a.T; CABI0CabiA005007001.port.T = TC_83_84.port_a.T; CABI0CabiA005007001.port.T = TC_83_96.port_a.T; CABI0CabiA005007001.port.T = TsCABI0CabiA005007001.port.T; TsCABI0CabiA004007001.port.Q_flow + (TC_81_82.port_b.Q_flow + (TC_69_82.port_b.Q_flow + (CABI0CabiA004007001.port.Q_flow + (TC_82_83.port_a.Q_flow + (TC_82_95.port_a.Q_flow + (TC_82_757.port_a.Q_flow + TC_82_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004007001.port.T = TC_69_82.port_b.T; CABI0CabiA004007001.port.T = TC_81_82.port_b.T; CABI0CabiA004007001.port.T = TC_82_0.port_a.T; CABI0CabiA004007001.port.T = TC_82_757.port_a.T; CABI0CabiA004007001.port.T = TC_82_83.port_a.T; CABI0CabiA004007001.port.T = TC_82_95.port_a.T; CABI0CabiA004007001.port.T = TsCABI0CabiA004007001.port.T; TsCABI0CabiA003007001.port.Q_flow + (TC_80_81.port_b.Q_flow + (TC_68_81.port_b.Q_flow + (CABI0CabiA003007001.port.Q_flow + (TC_81_82.port_a.Q_flow + (TC_81_94.port_a.Q_flow + (TC_81_1419.port_a.Q_flow + TC_81_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003007001.port.T = TC_68_81.port_b.T; CABI0CabiA003007001.port.T = TC_80_81.port_b.T; CABI0CabiA003007001.port.T = TC_81_0.port_a.T; CABI0CabiA003007001.port.T = TC_81_1419.port_a.T; CABI0CabiA003007001.port.T = TC_81_82.port_a.T; CABI0CabiA003007001.port.T = TC_81_94.port_a.T; CABI0CabiA003007001.port.T = TsCABI0CabiA003007001.port.T; TsCABI0CabiA002007001.port.Q_flow + (TC_79_80.port_b.Q_flow + (TC_67_80.port_b.Q_flow + (CABI0CabiA002007001.port.Q_flow + (TC_80_81.port_a.Q_flow + (TC_80_93.port_a.Q_flow + (TC_80_1418.port_a.Q_flow + TC_80_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002007001.port.T = TC_67_80.port_b.T; CABI0CabiA002007001.port.T = TC_79_80.port_b.T; CABI0CabiA002007001.port.T = TC_80_0.port_a.T; CABI0CabiA002007001.port.T = TC_80_1418.port_a.T; CABI0CabiA002007001.port.T = TC_80_81.port_a.T; CABI0CabiA002007001.port.T = TC_80_93.port_a.T; CABI0CabiA002007001.port.T = TsCABI0CabiA002007001.port.T; TsCABI0CabiA001007001.port.Q_flow + (TC_66_79.port_b.Q_flow + (CABI0CabiA001007001.port.Q_flow + (TC_79_80.port_a.Q_flow + (TC_79_92.port_a.Q_flow + (TC_79_231.port_a.Q_flow + TC_79_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001007001.port.T = TC_66_79.port_b.T; CABI0CabiA001007001.port.T = TC_79_0.port_a.T; CABI0CabiA001007001.port.T = TC_79_231.port_a.T; CABI0CabiA001007001.port.T = TC_79_80.port_a.T; CABI0CabiA001007001.port.T = TC_79_92.port_a.T; CABI0CabiA001007001.port.T = TsCABI0CabiA001007001.port.T; TsCABI0CabiA013006001.port.Q_flow + (TC_77_78.port_b.Q_flow + (TC_65_78.port_b.Q_flow + (CABI0CabiA013006001.port.Q_flow + (TC_78_91.port_a.Q_flow + (TC_78_230.port_a.Q_flow + TC_78_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013006001.port.T = TC_65_78.port_b.T; CABI0CabiA013006001.port.T = TC_77_78.port_b.T; CABI0CabiA013006001.port.T = TC_78_0.port_a.T; CABI0CabiA013006001.port.T = TC_78_230.port_a.T; CABI0CabiA013006001.port.T = TC_78_91.port_a.T; CABI0CabiA013006001.port.T = TsCABI0CabiA013006001.port.T; TsCABI0CabiA012006001.port.Q_flow + (TC_76_77.port_b.Q_flow + (TC_64_77.port_b.Q_flow + (CABI0CabiA012006001.port.Q_flow + (TC_77_78.port_a.Q_flow + (TC_77_90.port_a.Q_flow + (TC_77_1417.port_a.Q_flow + TC_77_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012006001.port.T = TC_64_77.port_b.T; CABI0CabiA012006001.port.T = TC_76_77.port_b.T; CABI0CabiA012006001.port.T = TC_77_0.port_a.T; CABI0CabiA012006001.port.T = TC_77_1417.port_a.T; CABI0CabiA012006001.port.T = TC_77_78.port_a.T; CABI0CabiA012006001.port.T = TC_77_90.port_a.T; CABI0CabiA012006001.port.T = TsCABI0CabiA012006001.port.T; TsCABI0CabiA011006001.port.Q_flow + (TC_75_76.port_b.Q_flow + (TC_63_76.port_b.Q_flow + (CABI0CabiA011006001.port.Q_flow + (TC_76_77.port_a.Q_flow + (TC_76_89.port_a.Q_flow + (TC_76_756.port_a.Q_flow + TC_76_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011006001.port.T = TC_63_76.port_b.T; CABI0CabiA011006001.port.T = TC_75_76.port_b.T; CABI0CabiA011006001.port.T = TC_76_0.port_a.T; CABI0CabiA011006001.port.T = TC_76_756.port_a.T; CABI0CabiA011006001.port.T = TC_76_77.port_a.T; CABI0CabiA011006001.port.T = TC_76_89.port_a.T; CABI0CabiA011006001.port.T = TsCABI0CabiA011006001.port.T; TsCABI0CabiA010006001.port.Q_flow + (TC_74_75.port_b.Q_flow + (TC_62_75.port_b.Q_flow + (CABI0CabiA010006001.port.Q_flow + (TC_75_76.port_a.Q_flow + (TC_75_88.port_a.Q_flow + (TC_75_755.port_a.Q_flow + TC_75_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010006001.port.T = TC_62_75.port_b.T; CABI0CabiA010006001.port.T = TC_74_75.port_b.T; CABI0CabiA010006001.port.T = TC_75_0.port_a.T; CABI0CabiA010006001.port.T = TC_75_755.port_a.T; CABI0CabiA010006001.port.T = TC_75_76.port_a.T; CABI0CabiA010006001.port.T = TC_75_88.port_a.T; CABI0CabiA010006001.port.T = TsCABI0CabiA010006001.port.T; TsCABI0CabiA009006001.port.Q_flow + (TC_73_74.port_b.Q_flow + (TC_61_74.port_b.Q_flow + (CABI0CabiA009006001.port.Q_flow + (TC_74_75.port_a.Q_flow + (TC_74_87.port_a.Q_flow + (TC_74_754.port_a.Q_flow + TC_74_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009006001.port.T = TC_61_74.port_b.T; CABI0CabiA009006001.port.T = TC_73_74.port_b.T; CABI0CabiA009006001.port.T = TC_74_0.port_a.T; CABI0CabiA009006001.port.T = TC_74_75.port_a.T; CABI0CabiA009006001.port.T = TC_74_754.port_a.T; CABI0CabiA009006001.port.T = TC_74_87.port_a.T; CABI0CabiA009006001.port.T = TsCABI0CabiA009006001.port.T; TsCABI0CabiA008006001.port.Q_flow + (TC_72_73.port_b.Q_flow + (TC_60_73.port_b.Q_flow + (CABI0CabiA008006001.port.Q_flow + (TC_73_74.port_a.Q_flow + (TC_73_86.port_a.Q_flow + (TC_73_753.port_a.Q_flow + TC_73_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008006001.port.T = TC_60_73.port_b.T; CABI0CabiA008006001.port.T = TC_72_73.port_b.T; CABI0CabiA008006001.port.T = TC_73_0.port_a.T; CABI0CabiA008006001.port.T = TC_73_74.port_a.T; CABI0CabiA008006001.port.T = TC_73_753.port_a.T; CABI0CabiA008006001.port.T = TC_73_86.port_a.T; CABI0CabiA008006001.port.T = TsCABI0CabiA008006001.port.T; TsCABI0CabiA007006001.port.Q_flow + (TC_71_72.port_b.Q_flow + (TC_59_72.port_b.Q_flow + (CABI0CabiA007006001.port.Q_flow + (TC_72_73.port_a.Q_flow + (TC_72_85.port_a.Q_flow + (TC_72_752.port_a.Q_flow + TC_72_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007006001.port.T = TC_59_72.port_b.T; CABI0CabiA007006001.port.T = TC_71_72.port_b.T; CABI0CabiA007006001.port.T = TC_72_0.port_a.T; CABI0CabiA007006001.port.T = TC_72_73.port_a.T; CABI0CabiA007006001.port.T = TC_72_752.port_a.T; CABI0CabiA007006001.port.T = TC_72_85.port_a.T; CABI0CabiA007006001.port.T = TsCABI0CabiA007006001.port.T; TsCABI0CabiA006006001.port.Q_flow + (TC_70_71.port_b.Q_flow + (TC_58_71.port_b.Q_flow + (CABI0CabiA006006001.port.Q_flow + (TC_71_72.port_a.Q_flow + (TC_71_84.port_a.Q_flow + (TC_71_751.port_a.Q_flow + TC_71_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006006001.port.T = TC_58_71.port_b.T; CABI0CabiA006006001.port.T = TC_70_71.port_b.T; CABI0CabiA006006001.port.T = TC_71_0.port_a.T; CABI0CabiA006006001.port.T = TC_71_72.port_a.T; CABI0CabiA006006001.port.T = TC_71_751.port_a.T; CABI0CabiA006006001.port.T = TC_71_84.port_a.T; CABI0CabiA006006001.port.T = TsCABI0CabiA006006001.port.T; TsCABI0CabiA005006001.port.Q_flow + (TC_69_70.port_b.Q_flow + (TC_57_70.port_b.Q_flow + (CABI0CabiA005006001.port.Q_flow + (TC_70_71.port_a.Q_flow + (TC_70_83.port_a.Q_flow + (TC_70_750.port_a.Q_flow + TC_70_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005006001.port.T = TC_57_70.port_b.T; CABI0CabiA005006001.port.T = TC_69_70.port_b.T; CABI0CabiA005006001.port.T = TC_70_0.port_a.T; CABI0CabiA005006001.port.T = TC_70_71.port_a.T; CABI0CabiA005006001.port.T = TC_70_750.port_a.T; CABI0CabiA005006001.port.T = TC_70_83.port_a.T; CABI0CabiA005006001.port.T = TsCABI0CabiA005006001.port.T; TsCABI0CabiA004006001.port.Q_flow + (TC_68_69.port_b.Q_flow + (TC_56_69.port_b.Q_flow + (CABI0CabiA004006001.port.Q_flow + (TC_69_70.port_a.Q_flow + (TC_69_82.port_a.Q_flow + (TC_69_749.port_a.Q_flow + TC_69_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004006001.port.T = TC_56_69.port_b.T; CABI0CabiA004006001.port.T = TC_68_69.port_b.T; CABI0CabiA004006001.port.T = TC_69_0.port_a.T; CABI0CabiA004006001.port.T = TC_69_70.port_a.T; CABI0CabiA004006001.port.T = TC_69_749.port_a.T; CABI0CabiA004006001.port.T = TC_69_82.port_a.T; CABI0CabiA004006001.port.T = TsCABI0CabiA004006001.port.T; TsCABI0CabiA003006001.port.Q_flow + (TC_67_68.port_b.Q_flow + (TC_55_68.port_b.Q_flow + (CABI0CabiA003006001.port.Q_flow + (TC_68_69.port_a.Q_flow + (TC_68_81.port_a.Q_flow + (TC_68_1416.port_a.Q_flow + TC_68_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003006001.port.T = TC_55_68.port_b.T; CABI0CabiA003006001.port.T = TC_67_68.port_b.T; CABI0CabiA003006001.port.T = TC_68_0.port_a.T; CABI0CabiA003006001.port.T = TC_68_1416.port_a.T; CABI0CabiA003006001.port.T = TC_68_69.port_a.T; CABI0CabiA003006001.port.T = TC_68_81.port_a.T; CABI0CabiA003006001.port.T = TsCABI0CabiA003006001.port.T; TsCABI0CabiA002006001.port.Q_flow + (TC_66_67.port_b.Q_flow + (TC_54_67.port_b.Q_flow + (CABI0CabiA002006001.port.Q_flow + (TC_67_68.port_a.Q_flow + (TC_67_80.port_a.Q_flow + (TC_67_1415.port_a.Q_flow + TC_67_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002006001.port.T = TC_54_67.port_b.T; CABI0CabiA002006001.port.T = TC_66_67.port_b.T; CABI0CabiA002006001.port.T = TC_67_0.port_a.T; CABI0CabiA002006001.port.T = TC_67_1415.port_a.T; CABI0CabiA002006001.port.T = TC_67_68.port_a.T; CABI0CabiA002006001.port.T = TC_67_80.port_a.T; CABI0CabiA002006001.port.T = TsCABI0CabiA002006001.port.T; TsCABI0CabiA001006001.port.Q_flow + (TC_53_66.port_b.Q_flow + (CABI0CabiA001006001.port.Q_flow + (TC_66_67.port_a.Q_flow + (TC_66_79.port_a.Q_flow + (TC_66_229.port_a.Q_flow + TC_66_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001006001.port.T = TC_53_66.port_b.T; CABI0CabiA001006001.port.T = TC_66_0.port_a.T; CABI0CabiA001006001.port.T = TC_66_229.port_a.T; CABI0CabiA001006001.port.T = TC_66_67.port_a.T; CABI0CabiA001006001.port.T = TC_66_79.port_a.T; CABI0CabiA001006001.port.T = TsCABI0CabiA001006001.port.T; TsCABI0CabiA013005001.port.Q_flow + (TC_64_65.port_b.Q_flow + (TC_52_65.port_b.Q_flow + (CABI0CabiA013005001.port.Q_flow + (TC_65_78.port_a.Q_flow + (TC_65_228.port_a.Q_flow + TC_65_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013005001.port.T = TC_52_65.port_b.T; CABI0CabiA013005001.port.T = TC_64_65.port_b.T; CABI0CabiA013005001.port.T = TC_65_0.port_a.T; CABI0CabiA013005001.port.T = TC_65_228.port_a.T; CABI0CabiA013005001.port.T = TC_65_78.port_a.T; CABI0CabiA013005001.port.T = TsCABI0CabiA013005001.port.T; TsCABI0CabiA012005001.port.Q_flow + (TC_63_64.port_b.Q_flow + (TC_51_64.port_b.Q_flow + (CABI0CabiA012005001.port.Q_flow + (TC_64_65.port_a.Q_flow + (TC_64_77.port_a.Q_flow + (TC_64_1414.port_a.Q_flow + TC_64_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012005001.port.T = TC_51_64.port_b.T; CABI0CabiA012005001.port.T = TC_63_64.port_b.T; CABI0CabiA012005001.port.T = TC_64_0.port_a.T; CABI0CabiA012005001.port.T = TC_64_1414.port_a.T; CABI0CabiA012005001.port.T = TC_64_65.port_a.T; CABI0CabiA012005001.port.T = TC_64_77.port_a.T; CABI0CabiA012005001.port.T = TsCABI0CabiA012005001.port.T; TsCABI0CabiA011005001.port.Q_flow + (TC_62_63.port_b.Q_flow + (TC_50_63.port_b.Q_flow + (CABI0CabiA011005001.port.Q_flow + (TC_63_64.port_a.Q_flow + (TC_63_76.port_a.Q_flow + (TC_63_748.port_a.Q_flow + TC_63_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011005001.port.T = TC_50_63.port_b.T; CABI0CabiA011005001.port.T = TC_62_63.port_b.T; CABI0CabiA011005001.port.T = TC_63_0.port_a.T; CABI0CabiA011005001.port.T = TC_63_64.port_a.T; CABI0CabiA011005001.port.T = TC_63_748.port_a.T; CABI0CabiA011005001.port.T = TC_63_76.port_a.T; CABI0CabiA011005001.port.T = TsCABI0CabiA011005001.port.T; TsCABI0CabiA010005001.port.Q_flow + (TC_61_62.port_b.Q_flow + (TC_49_62.port_b.Q_flow + (CABI0CabiA010005001.port.Q_flow + (TC_62_63.port_a.Q_flow + (TC_62_75.port_a.Q_flow + (TC_62_747.port_a.Q_flow + TC_62_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010005001.port.T = TC_49_62.port_b.T; CABI0CabiA010005001.port.T = TC_61_62.port_b.T; CABI0CabiA010005001.port.T = TC_62_0.port_a.T; CABI0CabiA010005001.port.T = TC_62_63.port_a.T; CABI0CabiA010005001.port.T = TC_62_747.port_a.T; CABI0CabiA010005001.port.T = TC_62_75.port_a.T; CABI0CabiA010005001.port.T = TsCABI0CabiA010005001.port.T; TsCABI0CabiA009005001.port.Q_flow + (TC_60_61.port_b.Q_flow + (TC_48_61.port_b.Q_flow + (CABI0CabiA009005001.port.Q_flow + (TC_61_62.port_a.Q_flow + (TC_61_74.port_a.Q_flow + (TC_61_746.port_a.Q_flow + TC_61_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009005001.port.T = TC_48_61.port_b.T; CABI0CabiA009005001.port.T = TC_60_61.port_b.T; CABI0CabiA009005001.port.T = TC_61_0.port_a.T; CABI0CabiA009005001.port.T = TC_61_62.port_a.T; CABI0CabiA009005001.port.T = TC_61_74.port_a.T; CABI0CabiA009005001.port.T = TC_61_746.port_a.T; CABI0CabiA009005001.port.T = TsCABI0CabiA009005001.port.T; TsCABI0CabiA008005001.port.Q_flow + (TC_59_60.port_b.Q_flow + (TC_47_60.port_b.Q_flow + (CABI0CabiA008005001.port.Q_flow + (TC_60_61.port_a.Q_flow + (TC_60_73.port_a.Q_flow + (TC_60_745.port_a.Q_flow + TC_60_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008005001.port.T = TC_47_60.port_b.T; CABI0CabiA008005001.port.T = TC_59_60.port_b.T; CABI0CabiA008005001.port.T = TC_60_0.port_a.T; CABI0CabiA008005001.port.T = TC_60_61.port_a.T; CABI0CabiA008005001.port.T = TC_60_73.port_a.T; CABI0CabiA008005001.port.T = TC_60_745.port_a.T; CABI0CabiA008005001.port.T = TsCABI0CabiA008005001.port.T; TsCABI0CabiA007005001.port.Q_flow + (TC_58_59.port_b.Q_flow + (TC_46_59.port_b.Q_flow + (CABI0CabiA007005001.port.Q_flow + (TC_59_60.port_a.Q_flow + (TC_59_72.port_a.Q_flow + (TC_59_744.port_a.Q_flow + TC_59_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007005001.port.T = TC_46_59.port_b.T; CABI0CabiA007005001.port.T = TC_58_59.port_b.T; CABI0CabiA007005001.port.T = TC_59_0.port_a.T; CABI0CabiA007005001.port.T = TC_59_60.port_a.T; CABI0CabiA007005001.port.T = TC_59_72.port_a.T; CABI0CabiA007005001.port.T = TC_59_744.port_a.T; CABI0CabiA007005001.port.T = TsCABI0CabiA007005001.port.T; TsCABI0CabiA006005001.port.Q_flow + (TC_57_58.port_b.Q_flow + (TC_45_58.port_b.Q_flow + (CABI0CabiA006005001.port.Q_flow + (TC_58_59.port_a.Q_flow + (TC_58_71.port_a.Q_flow + (TC_58_743.port_a.Q_flow + TC_58_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006005001.port.T = TC_45_58.port_b.T; CABI0CabiA006005001.port.T = TC_57_58.port_b.T; CABI0CabiA006005001.port.T = TC_58_0.port_a.T; CABI0CabiA006005001.port.T = TC_58_59.port_a.T; CABI0CabiA006005001.port.T = TC_58_71.port_a.T; CABI0CabiA006005001.port.T = TC_58_743.port_a.T; CABI0CabiA006005001.port.T = TsCABI0CabiA006005001.port.T; TsCABI0CabiA005005001.port.Q_flow + (TC_56_57.port_b.Q_flow + (TC_44_57.port_b.Q_flow + (CABI0CabiA005005001.port.Q_flow + (TC_57_58.port_a.Q_flow + (TC_57_70.port_a.Q_flow + (TC_57_742.port_a.Q_flow + TC_57_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005005001.port.T = TC_44_57.port_b.T; CABI0CabiA005005001.port.T = TC_56_57.port_b.T; CABI0CabiA005005001.port.T = TC_57_0.port_a.T; CABI0CabiA005005001.port.T = TC_57_58.port_a.T; CABI0CabiA005005001.port.T = TC_57_70.port_a.T; CABI0CabiA005005001.port.T = TC_57_742.port_a.T; CABI0CabiA005005001.port.T = TsCABI0CabiA005005001.port.T; TsCABI0CabiA004005001.port.Q_flow + (TC_55_56.port_b.Q_flow + (TC_43_56.port_b.Q_flow + (CABI0CabiA004005001.port.Q_flow + (TC_56_57.port_a.Q_flow + (TC_56_69.port_a.Q_flow + (TC_56_741.port_a.Q_flow + TC_56_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004005001.port.T = TC_43_56.port_b.T; CABI0CabiA004005001.port.T = TC_55_56.port_b.T; CABI0CabiA004005001.port.T = TC_56_0.port_a.T; CABI0CabiA004005001.port.T = TC_56_57.port_a.T; CABI0CabiA004005001.port.T = TC_56_69.port_a.T; CABI0CabiA004005001.port.T = TC_56_741.port_a.T; CABI0CabiA004005001.port.T = TsCABI0CabiA004005001.port.T; TsCABI0CabiA003005001.port.Q_flow + (TC_54_55.port_b.Q_flow + (TC_42_55.port_b.Q_flow + (CABI0CabiA003005001.port.Q_flow + (TC_55_56.port_a.Q_flow + (TC_55_68.port_a.Q_flow + (TC_55_1465.port_a.Q_flow + TC_55_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003005001.port.T = TC_42_55.port_b.T; CABI0CabiA003005001.port.T = TC_54_55.port_b.T; CABI0CabiA003005001.port.T = TC_55_0.port_a.T; CABI0CabiA003005001.port.T = TC_55_1465.port_a.T; CABI0CabiA003005001.port.T = TC_55_56.port_a.T; CABI0CabiA003005001.port.T = TC_55_68.port_a.T; CABI0CabiA003005001.port.T = TsCABI0CabiA003005001.port.T; TsCABI0CabiA002005001.port.Q_flow + (TC_53_54.port_b.Q_flow + (TC_41_54.port_b.Q_flow + (CABI0CabiA002005001.port.Q_flow + (TC_54_55.port_a.Q_flow + (TC_54_67.port_a.Q_flow + (TC_54_1464.port_a.Q_flow + TC_54_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002005001.port.T = TC_41_54.port_b.T; CABI0CabiA002005001.port.T = TC_53_54.port_b.T; CABI0CabiA002005001.port.T = TC_54_0.port_a.T; CABI0CabiA002005001.port.T = TC_54_1464.port_a.T; CABI0CabiA002005001.port.T = TC_54_55.port_a.T; CABI0CabiA002005001.port.T = TC_54_67.port_a.T; CABI0CabiA002005001.port.T = TsCABI0CabiA002005001.port.T; TsCABI0CabiA001005001.port.Q_flow + (TC_40_53.port_b.Q_flow + (CABI0CabiA001005001.port.Q_flow + (TC_53_54.port_a.Q_flow + (TC_53_66.port_a.Q_flow + (TC_53_227.port_a.Q_flow + TC_53_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001005001.port.T = TC_40_53.port_b.T; CABI0CabiA001005001.port.T = TC_53_0.port_a.T; CABI0CabiA001005001.port.T = TC_53_227.port_a.T; CABI0CabiA001005001.port.T = TC_53_54.port_a.T; CABI0CabiA001005001.port.T = TC_53_66.port_a.T; CABI0CabiA001005001.port.T = TsCABI0CabiA001005001.port.T; TsCABI0CabiA013004001.port.Q_flow + (TC_51_52.port_b.Q_flow + (TC_39_52.port_b.Q_flow + (CABI0CabiA013004001.port.Q_flow + (TC_52_65.port_a.Q_flow + (TC_52_226.port_a.Q_flow + TC_52_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013004001.port.T = TC_39_52.port_b.T; CABI0CabiA013004001.port.T = TC_51_52.port_b.T; CABI0CabiA013004001.port.T = TC_52_0.port_a.T; CABI0CabiA013004001.port.T = TC_52_226.port_a.T; CABI0CabiA013004001.port.T = TC_52_65.port_a.T; CABI0CabiA013004001.port.T = TsCABI0CabiA013004001.port.T; TsCABI0CabiA012004001.port.Q_flow + (TC_50_51.port_b.Q_flow + (TC_38_51.port_b.Q_flow + (CABI0CabiA012004001.port.Q_flow + (TC_51_52.port_a.Q_flow + (TC_51_64.port_a.Q_flow + (TC_51_1463.port_a.Q_flow + TC_51_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012004001.port.T = TC_38_51.port_b.T; CABI0CabiA012004001.port.T = TC_50_51.port_b.T; CABI0CabiA012004001.port.T = TC_51_0.port_a.T; CABI0CabiA012004001.port.T = TC_51_1463.port_a.T; CABI0CabiA012004001.port.T = TC_51_52.port_a.T; CABI0CabiA012004001.port.T = TC_51_64.port_a.T; CABI0CabiA012004001.port.T = TsCABI0CabiA012004001.port.T; TsCABI0CabiA011004001.port.Q_flow + (TC_49_50.port_b.Q_flow + (TC_37_50.port_b.Q_flow + (CABI0CabiA011004001.port.Q_flow + (TC_50_51.port_a.Q_flow + (TC_50_63.port_a.Q_flow + (TC_50_820.port_a.Q_flow + TC_50_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011004001.port.T = TC_37_50.port_b.T; CABI0CabiA011004001.port.T = TC_49_50.port_b.T; CABI0CabiA011004001.port.T = TC_50_0.port_a.T; CABI0CabiA011004001.port.T = TC_50_51.port_a.T; CABI0CabiA011004001.port.T = TC_50_63.port_a.T; CABI0CabiA011004001.port.T = TC_50_820.port_a.T; CABI0CabiA011004001.port.T = TsCABI0CabiA011004001.port.T; TsCABI0CabiA010004001.port.Q_flow + (TC_48_49.port_b.Q_flow + (TC_36_49.port_b.Q_flow + (CABI0CabiA010004001.port.Q_flow + (TC_49_50.port_a.Q_flow + (TC_49_62.port_a.Q_flow + (TC_49_819.port_a.Q_flow + TC_49_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010004001.port.T = TC_36_49.port_b.T; CABI0CabiA010004001.port.T = TC_48_49.port_b.T; CABI0CabiA010004001.port.T = TC_49_0.port_a.T; CABI0CabiA010004001.port.T = TC_49_50.port_a.T; CABI0CabiA010004001.port.T = TC_49_62.port_a.T; CABI0CabiA010004001.port.T = TC_49_819.port_a.T; CABI0CabiA010004001.port.T = TsCABI0CabiA010004001.port.T; TsCABI0CabiA009004001.port.Q_flow + (TC_47_48.port_b.Q_flow + (TC_35_48.port_b.Q_flow + (CABI0CabiA009004001.port.Q_flow + (TC_48_49.port_a.Q_flow + (TC_48_61.port_a.Q_flow + (TC_48_818.port_a.Q_flow + TC_48_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009004001.port.T = TC_35_48.port_b.T; CABI0CabiA009004001.port.T = TC_47_48.port_b.T; CABI0CabiA009004001.port.T = TC_48_0.port_a.T; CABI0CabiA009004001.port.T = TC_48_49.port_a.T; CABI0CabiA009004001.port.T = TC_48_61.port_a.T; CABI0CabiA009004001.port.T = TC_48_818.port_a.T; CABI0CabiA009004001.port.T = TsCABI0CabiA009004001.port.T; TsCABI0CabiA008004001.port.Q_flow + (TC_46_47.port_b.Q_flow + (TC_34_47.port_b.Q_flow + (CABI0CabiA008004001.port.Q_flow + (TC_47_48.port_a.Q_flow + (TC_47_60.port_a.Q_flow + (TC_47_817.port_a.Q_flow + TC_47_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008004001.port.T = TC_34_47.port_b.T; CABI0CabiA008004001.port.T = TC_46_47.port_b.T; CABI0CabiA008004001.port.T = TC_47_0.port_a.T; CABI0CabiA008004001.port.T = TC_47_48.port_a.T; CABI0CabiA008004001.port.T = TC_47_60.port_a.T; CABI0CabiA008004001.port.T = TC_47_817.port_a.T; CABI0CabiA008004001.port.T = TsCABI0CabiA008004001.port.T; TsCABI0CabiA007004001.port.Q_flow + (TC_45_46.port_b.Q_flow + (TC_33_46.port_b.Q_flow + (CABI0CabiA007004001.port.Q_flow + (TC_46_47.port_a.Q_flow + (TC_46_59.port_a.Q_flow + (TC_46_816.port_a.Q_flow + TC_46_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007004001.port.T = TC_33_46.port_b.T; CABI0CabiA007004001.port.T = TC_45_46.port_b.T; CABI0CabiA007004001.port.T = TC_46_0.port_a.T; CABI0CabiA007004001.port.T = TC_46_47.port_a.T; CABI0CabiA007004001.port.T = TC_46_59.port_a.T; CABI0CabiA007004001.port.T = TC_46_816.port_a.T; CABI0CabiA007004001.port.T = TsCABI0CabiA007004001.port.T; TsCABI0CabiA006004001.port.Q_flow + (TC_44_45.port_b.Q_flow + (TC_32_45.port_b.Q_flow + (CABI0CabiA006004001.port.Q_flow + (TC_45_46.port_a.Q_flow + (TC_45_58.port_a.Q_flow + (TC_45_815.port_a.Q_flow + TC_45_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006004001.port.T = TC_32_45.port_b.T; CABI0CabiA006004001.port.T = TC_44_45.port_b.T; CABI0CabiA006004001.port.T = TC_45_0.port_a.T; CABI0CabiA006004001.port.T = TC_45_46.port_a.T; CABI0CabiA006004001.port.T = TC_45_58.port_a.T; CABI0CabiA006004001.port.T = TC_45_815.port_a.T; CABI0CabiA006004001.port.T = TsCABI0CabiA006004001.port.T; TsCABI0CabiA005004001.port.Q_flow + (TC_43_44.port_b.Q_flow + (TC_31_44.port_b.Q_flow + (CABI0CabiA005004001.port.Q_flow + (TC_44_45.port_a.Q_flow + (TC_44_57.port_a.Q_flow + (TC_44_814.port_a.Q_flow + TC_44_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005004001.port.T = TC_31_44.port_b.T; CABI0CabiA005004001.port.T = TC_43_44.port_b.T; CABI0CabiA005004001.port.T = TC_44_0.port_a.T; CABI0CabiA005004001.port.T = TC_44_45.port_a.T; CABI0CabiA005004001.port.T = TC_44_57.port_a.T; CABI0CabiA005004001.port.T = TC_44_814.port_a.T; CABI0CabiA005004001.port.T = TsCABI0CabiA005004001.port.T; TsCABI0CabiA004004001.port.Q_flow + (TC_42_43.port_b.Q_flow + (TC_30_43.port_b.Q_flow + (CABI0CabiA004004001.port.Q_flow + (TC_43_44.port_a.Q_flow + (TC_43_56.port_a.Q_flow + (TC_43_813.port_a.Q_flow + TC_43_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004004001.port.T = TC_30_43.port_b.T; CABI0CabiA004004001.port.T = TC_42_43.port_b.T; CABI0CabiA004004001.port.T = TC_43_0.port_a.T; CABI0CabiA004004001.port.T = TC_43_44.port_a.T; CABI0CabiA004004001.port.T = TC_43_56.port_a.T; CABI0CabiA004004001.port.T = TC_43_813.port_a.T; CABI0CabiA004004001.port.T = TsCABI0CabiA004004001.port.T; TsCABI0CabiA003004001.port.Q_flow + (TC_41_42.port_b.Q_flow + (TC_29_42.port_b.Q_flow + (CABI0CabiA003004001.port.Q_flow + (TC_42_43.port_a.Q_flow + (TC_42_55.port_a.Q_flow + (TC_42_1462.port_a.Q_flow + TC_42_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003004001.port.T = TC_29_42.port_b.T; CABI0CabiA003004001.port.T = TC_41_42.port_b.T; CABI0CabiA003004001.port.T = TC_42_0.port_a.T; CABI0CabiA003004001.port.T = TC_42_1462.port_a.T; CABI0CabiA003004001.port.T = TC_42_43.port_a.T; CABI0CabiA003004001.port.T = TC_42_55.port_a.T; CABI0CabiA003004001.port.T = TsCABI0CabiA003004001.port.T; TsCABI0CabiA002004001.port.Q_flow + (TC_40_41.port_b.Q_flow + (TC_28_41.port_b.Q_flow + (CABI0CabiA002004001.port.Q_flow + (TC_41_42.port_a.Q_flow + (TC_41_54.port_a.Q_flow + (TC_41_1461.port_a.Q_flow + TC_41_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002004001.port.T = TC_28_41.port_b.T; CABI0CabiA002004001.port.T = TC_40_41.port_b.T; CABI0CabiA002004001.port.T = TC_41_0.port_a.T; CABI0CabiA002004001.port.T = TC_41_1461.port_a.T; CABI0CabiA002004001.port.T = TC_41_42.port_a.T; CABI0CabiA002004001.port.T = TC_41_54.port_a.T; CABI0CabiA002004001.port.T = TsCABI0CabiA002004001.port.T; TsCABI0CabiA001004001.port.Q_flow + (TC_27_40.port_b.Q_flow + (CABI0CabiA001004001.port.Q_flow + (TC_40_41.port_a.Q_flow + (TC_40_53.port_a.Q_flow + (TC_40_225.port_a.Q_flow + TC_40_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001004001.port.T = TC_27_40.port_b.T; CABI0CabiA001004001.port.T = TC_40_0.port_a.T; CABI0CabiA001004001.port.T = TC_40_225.port_a.T; CABI0CabiA001004001.port.T = TC_40_41.port_a.T; CABI0CabiA001004001.port.T = TC_40_53.port_a.T; CABI0CabiA001004001.port.T = TsCABI0CabiA001004001.port.T; TsCABI0CabiA013003001.port.Q_flow + (TC_38_39.port_b.Q_flow + (TC_26_39.port_b.Q_flow + (CABI0CabiA013003001.port.Q_flow + (TC_39_52.port_a.Q_flow + (TC_39_224.port_a.Q_flow + TC_39_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013003001.port.T = TC_26_39.port_b.T; CABI0CabiA013003001.port.T = TC_38_39.port_b.T; CABI0CabiA013003001.port.T = TC_39_0.port_a.T; CABI0CabiA013003001.port.T = TC_39_224.port_a.T; CABI0CabiA013003001.port.T = TC_39_52.port_a.T; CABI0CabiA013003001.port.T = TsCABI0CabiA013003001.port.T; TsCABI0CabiA012003001.port.Q_flow + (TC_37_38.port_b.Q_flow + (TC_25_38.port_b.Q_flow + (CABI0CabiA012003001.port.Q_flow + (TC_38_39.port_a.Q_flow + (TC_38_51.port_a.Q_flow + (TC_38_1476.port_a.Q_flow + TC_38_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012003001.port.T = TC_25_38.port_b.T; CABI0CabiA012003001.port.T = TC_37_38.port_b.T; CABI0CabiA012003001.port.T = TC_38_0.port_a.T; CABI0CabiA012003001.port.T = TC_38_1476.port_a.T; CABI0CabiA012003001.port.T = TC_38_39.port_a.T; CABI0CabiA012003001.port.T = TC_38_51.port_a.T; CABI0CabiA012003001.port.T = TsCABI0CabiA012003001.port.T; TsCABI0CabiA011003001.port.Q_flow + (TC_36_37.port_b.Q_flow + (TC_24_37.port_b.Q_flow + (CABI0CabiA011003001.port.Q_flow + (TC_37_38.port_a.Q_flow + (TC_37_50.port_a.Q_flow + (TC_37_1475.port_a.Q_flow + TC_37_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011003001.port.T = TC_24_37.port_b.T; CABI0CabiA011003001.port.T = TC_36_37.port_b.T; CABI0CabiA011003001.port.T = TC_37_0.port_a.T; CABI0CabiA011003001.port.T = TC_37_1475.port_a.T; CABI0CabiA011003001.port.T = TC_37_38.port_a.T; CABI0CabiA011003001.port.T = TC_37_50.port_a.T; CABI0CabiA011003001.port.T = TsCABI0CabiA011003001.port.T; TsCABI0CabiA010003001.port.Q_flow + (TC_35_36.port_b.Q_flow + (TC_23_36.port_b.Q_flow + (CABI0CabiA010003001.port.Q_flow + (TC_36_37.port_a.Q_flow + (TC_36_49.port_a.Q_flow + (TC_36_1474.port_a.Q_flow + TC_36_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010003001.port.T = TC_23_36.port_b.T; CABI0CabiA010003001.port.T = TC_35_36.port_b.T; CABI0CabiA010003001.port.T = TC_36_0.port_a.T; CABI0CabiA010003001.port.T = TC_36_1474.port_a.T; CABI0CabiA010003001.port.T = TC_36_37.port_a.T; CABI0CabiA010003001.port.T = TC_36_49.port_a.T; CABI0CabiA010003001.port.T = TsCABI0CabiA010003001.port.T; TsCABI0CabiA009003001.port.Q_flow + (TC_34_35.port_b.Q_flow + (TC_22_35.port_b.Q_flow + (CABI0CabiA009003001.port.Q_flow + (TC_35_36.port_a.Q_flow + (TC_35_48.port_a.Q_flow + (TC_35_1473.port_a.Q_flow + TC_35_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009003001.port.T = TC_22_35.port_b.T; CABI0CabiA009003001.port.T = TC_34_35.port_b.T; CABI0CabiA009003001.port.T = TC_35_0.port_a.T; CABI0CabiA009003001.port.T = TC_35_1473.port_a.T; CABI0CabiA009003001.port.T = TC_35_36.port_a.T; CABI0CabiA009003001.port.T = TC_35_48.port_a.T; CABI0CabiA009003001.port.T = TsCABI0CabiA009003001.port.T; TsCABI0CabiA008003001.port.Q_flow + (TC_33_34.port_b.Q_flow + (TC_21_34.port_b.Q_flow + (CABI0CabiA008003001.port.Q_flow + (TC_34_35.port_a.Q_flow + (TC_34_47.port_a.Q_flow + (TC_34_1472.port_a.Q_flow + TC_34_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008003001.port.T = TC_21_34.port_b.T; CABI0CabiA008003001.port.T = TC_33_34.port_b.T; CABI0CabiA008003001.port.T = TC_34_0.port_a.T; CABI0CabiA008003001.port.T = TC_34_1472.port_a.T; CABI0CabiA008003001.port.T = TC_34_35.port_a.T; CABI0CabiA008003001.port.T = TC_34_47.port_a.T; CABI0CabiA008003001.port.T = TsCABI0CabiA008003001.port.T; TsCABI0CabiA007003001.port.Q_flow + (TC_32_33.port_b.Q_flow + (TC_20_33.port_b.Q_flow + (CABI0CabiA007003001.port.Q_flow + (TC_33_34.port_a.Q_flow + (TC_33_46.port_a.Q_flow + (TC_33_1471.port_a.Q_flow + TC_33_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007003001.port.T = TC_20_33.port_b.T; CABI0CabiA007003001.port.T = TC_32_33.port_b.T; CABI0CabiA007003001.port.T = TC_33_0.port_a.T; CABI0CabiA007003001.port.T = TC_33_1471.port_a.T; CABI0CabiA007003001.port.T = TC_33_34.port_a.T; CABI0CabiA007003001.port.T = TC_33_46.port_a.T; CABI0CabiA007003001.port.T = TsCABI0CabiA007003001.port.T; TsCABI0CabiA006003001.port.Q_flow + (TC_31_32.port_b.Q_flow + (TC_19_32.port_b.Q_flow + (CABI0CabiA006003001.port.Q_flow + (TC_32_33.port_a.Q_flow + (TC_32_45.port_a.Q_flow + (TC_32_1470.port_a.Q_flow + TC_32_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006003001.port.T = TC_19_32.port_b.T; CABI0CabiA006003001.port.T = TC_31_32.port_b.T; CABI0CabiA006003001.port.T = TC_32_0.port_a.T; CABI0CabiA006003001.port.T = TC_32_1470.port_a.T; CABI0CabiA006003001.port.T = TC_32_33.port_a.T; CABI0CabiA006003001.port.T = TC_32_45.port_a.T; CABI0CabiA006003001.port.T = TsCABI0CabiA006003001.port.T; TsCABI0CabiA005003001.port.Q_flow + (TC_30_31.port_b.Q_flow + (TC_18_31.port_b.Q_flow + (CABI0CabiA005003001.port.Q_flow + (TC_31_32.port_a.Q_flow + (TC_31_44.port_a.Q_flow + (TC_31_1469.port_a.Q_flow + TC_31_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005003001.port.T = TC_18_31.port_b.T; CABI0CabiA005003001.port.T = TC_30_31.port_b.T; CABI0CabiA005003001.port.T = TC_31_0.port_a.T; CABI0CabiA005003001.port.T = TC_31_1469.port_a.T; CABI0CabiA005003001.port.T = TC_31_32.port_a.T; CABI0CabiA005003001.port.T = TC_31_44.port_a.T; CABI0CabiA005003001.port.T = TsCABI0CabiA005003001.port.T; TsCABI0CabiA004003001.port.Q_flow + (TC_29_30.port_b.Q_flow + (TC_17_30.port_b.Q_flow + (CABI0CabiA004003001.port.Q_flow + (TC_30_31.port_a.Q_flow + (TC_30_43.port_a.Q_flow + (TC_30_1468.port_a.Q_flow + TC_30_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004003001.port.T = TC_17_30.port_b.T; CABI0CabiA004003001.port.T = TC_29_30.port_b.T; CABI0CabiA004003001.port.T = TC_30_0.port_a.T; CABI0CabiA004003001.port.T = TC_30_1468.port_a.T; CABI0CabiA004003001.port.T = TC_30_31.port_a.T; CABI0CabiA004003001.port.T = TC_30_43.port_a.T; CABI0CabiA004003001.port.T = TsCABI0CabiA004003001.port.T; TsCABI0CabiA003003001.port.Q_flow + (TC_28_29.port_b.Q_flow + (TC_16_29.port_b.Q_flow + (CABI0CabiA003003001.port.Q_flow + (TC_29_30.port_a.Q_flow + (TC_29_42.port_a.Q_flow + (TC_29_1467.port_a.Q_flow + TC_29_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003003001.port.T = TC_16_29.port_b.T; CABI0CabiA003003001.port.T = TC_28_29.port_b.T; CABI0CabiA003003001.port.T = TC_29_0.port_a.T; CABI0CabiA003003001.port.T = TC_29_1467.port_a.T; CABI0CabiA003003001.port.T = TC_29_30.port_a.T; CABI0CabiA003003001.port.T = TC_29_42.port_a.T; CABI0CabiA003003001.port.T = TsCABI0CabiA003003001.port.T; TsCABI0CabiA002003001.port.Q_flow + (TC_27_28.port_b.Q_flow + (TC_15_28.port_b.Q_flow + (CABI0CabiA002003001.port.Q_flow + (TC_28_29.port_a.Q_flow + (TC_28_41.port_a.Q_flow + (TC_28_1466.port_a.Q_flow + TC_28_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002003001.port.T = TC_15_28.port_b.T; CABI0CabiA002003001.port.T = TC_27_28.port_b.T; CABI0CabiA002003001.port.T = TC_28_0.port_a.T; CABI0CabiA002003001.port.T = TC_28_1466.port_a.T; CABI0CabiA002003001.port.T = TC_28_29.port_a.T; CABI0CabiA002003001.port.T = TC_28_41.port_a.T; CABI0CabiA002003001.port.T = TsCABI0CabiA002003001.port.T; TsCABI0CabiA001003001.port.Q_flow + (TC_14_27.port_b.Q_flow + (CABI0CabiA001003001.port.Q_flow + (TC_27_28.port_a.Q_flow + (TC_27_40.port_a.Q_flow + (TC_27_223.port_a.Q_flow + TC_27_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001003001.port.T = TC_14_27.port_b.T; CABI0CabiA001003001.port.T = TC_27_0.port_a.T; CABI0CabiA001003001.port.T = TC_27_223.port_a.T; CABI0CabiA001003001.port.T = TC_27_28.port_a.T; CABI0CabiA001003001.port.T = TC_27_40.port_a.T; CABI0CabiA001003001.port.T = TsCABI0CabiA001003001.port.T; TsCABI0CabiA013002001.port.Q_flow + (TC_25_26.port_b.Q_flow + (TC_13_26.port_b.Q_flow + (CABI0CabiA013002001.port.Q_flow + (TC_26_39.port_a.Q_flow + (TC_26_222.port_a.Q_flow + TC_26_0.port_a.Q_flow))))) = 0.0; CABI0CabiA013002001.port.T = TC_13_26.port_b.T; CABI0CabiA013002001.port.T = TC_25_26.port_b.T; CABI0CabiA013002001.port.T = TC_26_0.port_a.T; CABI0CabiA013002001.port.T = TC_26_222.port_a.T; CABI0CabiA013002001.port.T = TC_26_39.port_a.T; CABI0CabiA013002001.port.T = TsCABI0CabiA013002001.port.T; TsCABI0CabiA012002001.port.Q_flow + (TC_24_25.port_b.Q_flow + (TC_12_25.port_b.Q_flow + (CABI0CabiA012002001.port.Q_flow + (TC_25_26.port_a.Q_flow + (TC_25_38.port_a.Q_flow + (TC_25_1487.port_a.Q_flow + TC_25_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA012002001.port.T = TC_12_25.port_b.T; CABI0CabiA012002001.port.T = TC_24_25.port_b.T; CABI0CabiA012002001.port.T = TC_25_0.port_a.T; CABI0CabiA012002001.port.T = TC_25_1487.port_a.T; CABI0CabiA012002001.port.T = TC_25_26.port_a.T; CABI0CabiA012002001.port.T = TC_25_38.port_a.T; CABI0CabiA012002001.port.T = TsCABI0CabiA012002001.port.T; TsCABI0CabiA011002001.port.Q_flow + (TC_23_24.port_b.Q_flow + (TC_11_24.port_b.Q_flow + (CABI0CabiA011002001.port.Q_flow + (TC_24_25.port_a.Q_flow + (TC_24_37.port_a.Q_flow + (TC_24_1486.port_a.Q_flow + TC_24_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA011002001.port.T = TC_11_24.port_b.T; CABI0CabiA011002001.port.T = TC_23_24.port_b.T; CABI0CabiA011002001.port.T = TC_24_0.port_a.T; CABI0CabiA011002001.port.T = TC_24_1486.port_a.T; CABI0CabiA011002001.port.T = TC_24_25.port_a.T; CABI0CabiA011002001.port.T = TC_24_37.port_a.T; CABI0CabiA011002001.port.T = TsCABI0CabiA011002001.port.T; TsCABI0CabiA010002001.port.Q_flow + (TC_22_23.port_b.Q_flow + (TC_10_23.port_b.Q_flow + (CABI0CabiA010002001.port.Q_flow + (TC_23_24.port_a.Q_flow + (TC_23_36.port_a.Q_flow + (TC_23_1485.port_a.Q_flow + TC_23_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA010002001.port.T = TC_10_23.port_b.T; CABI0CabiA010002001.port.T = TC_22_23.port_b.T; CABI0CabiA010002001.port.T = TC_23_0.port_a.T; CABI0CabiA010002001.port.T = TC_23_1485.port_a.T; CABI0CabiA010002001.port.T = TC_23_24.port_a.T; CABI0CabiA010002001.port.T = TC_23_36.port_a.T; CABI0CabiA010002001.port.T = TsCABI0CabiA010002001.port.T; TsCABI0CabiA009002001.port.Q_flow + (TC_21_22.port_b.Q_flow + (TC_9_22.port_b.Q_flow + (CABI0CabiA009002001.port.Q_flow + (TC_22_23.port_a.Q_flow + (TC_22_35.port_a.Q_flow + (TC_22_1484.port_a.Q_flow + TC_22_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA009002001.port.T = TC_21_22.port_b.T; CABI0CabiA009002001.port.T = TC_22_0.port_a.T; CABI0CabiA009002001.port.T = TC_22_1484.port_a.T; CABI0CabiA009002001.port.T = TC_22_23.port_a.T; CABI0CabiA009002001.port.T = TC_22_35.port_a.T; CABI0CabiA009002001.port.T = TC_9_22.port_b.T; CABI0CabiA009002001.port.T = TsCABI0CabiA009002001.port.T; TsCABI0CabiA008002001.port.Q_flow + (TC_20_21.port_b.Q_flow + (TC_8_21.port_b.Q_flow + (CABI0CabiA008002001.port.Q_flow + (TC_21_22.port_a.Q_flow + (TC_21_34.port_a.Q_flow + (TC_21_1483.port_a.Q_flow + TC_21_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA008002001.port.T = TC_20_21.port_b.T; CABI0CabiA008002001.port.T = TC_21_0.port_a.T; CABI0CabiA008002001.port.T = TC_21_1483.port_a.T; CABI0CabiA008002001.port.T = TC_21_22.port_a.T; CABI0CabiA008002001.port.T = TC_21_34.port_a.T; CABI0CabiA008002001.port.T = TC_8_21.port_b.T; CABI0CabiA008002001.port.T = TsCABI0CabiA008002001.port.T; TsCABI0CabiA007002001.port.Q_flow + (TC_19_20.port_b.Q_flow + (TC_7_20.port_b.Q_flow + (CABI0CabiA007002001.port.Q_flow + (TC_20_21.port_a.Q_flow + (TC_20_33.port_a.Q_flow + (TC_20_1482.port_a.Q_flow + TC_20_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA007002001.port.T = TC_19_20.port_b.T; CABI0CabiA007002001.port.T = TC_20_0.port_a.T; CABI0CabiA007002001.port.T = TC_20_1482.port_a.T; CABI0CabiA007002001.port.T = TC_20_21.port_a.T; CABI0CabiA007002001.port.T = TC_20_33.port_a.T; CABI0CabiA007002001.port.T = TC_7_20.port_b.T; CABI0CabiA007002001.port.T = TsCABI0CabiA007002001.port.T; TsCABI0CabiA006002001.port.Q_flow + (TC_18_19.port_b.Q_flow + (TC_6_19.port_b.Q_flow + (CABI0CabiA006002001.port.Q_flow + (TC_19_20.port_a.Q_flow + (TC_19_32.port_a.Q_flow + (TC_19_1481.port_a.Q_flow + TC_19_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA006002001.port.T = TC_18_19.port_b.T; CABI0CabiA006002001.port.T = TC_19_0.port_a.T; CABI0CabiA006002001.port.T = TC_19_1481.port_a.T; CABI0CabiA006002001.port.T = TC_19_20.port_a.T; CABI0CabiA006002001.port.T = TC_19_32.port_a.T; CABI0CabiA006002001.port.T = TC_6_19.port_b.T; CABI0CabiA006002001.port.T = TsCABI0CabiA006002001.port.T; TsCABI0CabiA005002001.port.Q_flow + (TC_17_18.port_b.Q_flow + (TC_5_18.port_b.Q_flow + (CABI0CabiA005002001.port.Q_flow + (TC_18_19.port_a.Q_flow + (TC_18_31.port_a.Q_flow + (TC_18_1480.port_a.Q_flow + TC_18_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA005002001.port.T = TC_17_18.port_b.T; CABI0CabiA005002001.port.T = TC_18_0.port_a.T; CABI0CabiA005002001.port.T = TC_18_1480.port_a.T; CABI0CabiA005002001.port.T = TC_18_19.port_a.T; CABI0CabiA005002001.port.T = TC_18_31.port_a.T; CABI0CabiA005002001.port.T = TC_5_18.port_b.T; CABI0CabiA005002001.port.T = TsCABI0CabiA005002001.port.T; TsCABI0CabiA004002001.port.Q_flow + (TC_16_17.port_b.Q_flow + (TC_4_17.port_b.Q_flow + (CABI0CabiA004002001.port.Q_flow + (TC_17_18.port_a.Q_flow + (TC_17_30.port_a.Q_flow + (TC_17_1479.port_a.Q_flow + TC_17_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA004002001.port.T = TC_16_17.port_b.T; CABI0CabiA004002001.port.T = TC_17_0.port_a.T; CABI0CabiA004002001.port.T = TC_17_1479.port_a.T; CABI0CabiA004002001.port.T = TC_17_18.port_a.T; CABI0CabiA004002001.port.T = TC_17_30.port_a.T; CABI0CabiA004002001.port.T = TC_4_17.port_b.T; CABI0CabiA004002001.port.T = TsCABI0CabiA004002001.port.T; TsCABI0CabiA003002001.port.Q_flow + (TC_15_16.port_b.Q_flow + (TC_3_16.port_b.Q_flow + (CABI0CabiA003002001.port.Q_flow + (TC_16_17.port_a.Q_flow + (TC_16_29.port_a.Q_flow + (TC_16_1478.port_a.Q_flow + TC_16_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA003002001.port.T = TC_15_16.port_b.T; CABI0CabiA003002001.port.T = TC_16_0.port_a.T; CABI0CabiA003002001.port.T = TC_16_1478.port_a.T; CABI0CabiA003002001.port.T = TC_16_17.port_a.T; CABI0CabiA003002001.port.T = TC_16_29.port_a.T; CABI0CabiA003002001.port.T = TC_3_16.port_b.T; CABI0CabiA003002001.port.T = TsCABI0CabiA003002001.port.T; TsCABI0CabiA002002001.port.Q_flow + (TC_14_15.port_b.Q_flow + (TC_2_15.port_b.Q_flow + (CABI0CabiA002002001.port.Q_flow + (TC_15_16.port_a.Q_flow + (TC_15_28.port_a.Q_flow + (TC_15_1477.port_a.Q_flow + TC_15_0.port_a.Q_flow)))))) = 0.0; CABI0CabiA002002001.port.T = TC_14_15.port_b.T; CABI0CabiA002002001.port.T = TC_15_0.port_a.T; CABI0CabiA002002001.port.T = TC_15_1477.port_a.T; CABI0CabiA002002001.port.T = TC_15_16.port_a.T; CABI0CabiA002002001.port.T = TC_15_28.port_a.T; CABI0CabiA002002001.port.T = TC_2_15.port_b.T; CABI0CabiA002002001.port.T = TsCABI0CabiA002002001.port.T; TsCABI0CabiA001002001.port.Q_flow + (TC_1_14.port_b.Q_flow + (CABI0CabiA001002001.port.Q_flow + (TC_14_15.port_a.Q_flow + (TC_14_27.port_a.Q_flow + (TC_14_221.port_a.Q_flow + TC_14_0.port_a.Q_flow))))) = 0.0; CABI0CabiA001002001.port.T = TC_14_0.port_a.T; CABI0CabiA001002001.port.T = TC_14_15.port_a.T; CABI0CabiA001002001.port.T = TC_14_221.port_a.T; CABI0CabiA001002001.port.T = TC_14_27.port_a.T; CABI0CabiA001002001.port.T = TC_1_14.port_b.T; CABI0CabiA001002001.port.T = TsCABI0CabiA001002001.port.T; TsCABI0CabiA013001001.port.Q_flow + (TC_12_13.port_b.Q_flow + (CABI0CabiA013001001.port.Q_flow + (TC_13_26.port_a.Q_flow + (TC_13_220.port_a.Q_flow + TC_13_0.port_a.Q_flow)))) = 0.0; CABI0CabiA013001001.port.T = TC_12_13.port_b.T; CABI0CabiA013001001.port.T = TC_13_0.port_a.T; CABI0CabiA013001001.port.T = TC_13_220.port_a.T; CABI0CabiA013001001.port.T = TC_13_26.port_a.T; CABI0CabiA013001001.port.T = TsCABI0CabiA013001001.port.T; TsCABI0CabiA012001001.port.Q_flow + (TC_11_12.port_b.Q_flow + (CABI0CabiA012001001.port.Q_flow + (TC_12_13.port_a.Q_flow + (TC_12_25.port_a.Q_flow + (TC_12_219.port_a.Q_flow + TC_12_0.port_a.Q_flow))))) = 0.0; CABI0CabiA012001001.port.T = TC_11_12.port_b.T; CABI0CabiA012001001.port.T = TC_12_0.port_a.T; CABI0CabiA012001001.port.T = TC_12_13.port_a.T; CABI0CabiA012001001.port.T = TC_12_219.port_a.T; CABI0CabiA012001001.port.T = TC_12_25.port_a.T; CABI0CabiA012001001.port.T = TsCABI0CabiA012001001.port.T; TsCABI0CabiA011001001.port.Q_flow + (TC_10_11.port_b.Q_flow + (CABI0CabiA011001001.port.Q_flow + (TC_11_12.port_a.Q_flow + (TC_11_24.port_a.Q_flow + (TC_11_218.port_a.Q_flow + TC_11_0.port_a.Q_flow))))) = 0.0; CABI0CabiA011001001.port.T = TC_10_11.port_b.T; CABI0CabiA011001001.port.T = TC_11_0.port_a.T; CABI0CabiA011001001.port.T = TC_11_12.port_a.T; CABI0CabiA011001001.port.T = TC_11_218.port_a.T; CABI0CabiA011001001.port.T = TC_11_24.port_a.T; CABI0CabiA011001001.port.T = TsCABI0CabiA011001001.port.T; TsCABI0CabiA010001001.port.Q_flow + (TC_9_10.port_b.Q_flow + (CABI0CabiA010001001.port.Q_flow + (TC_10_11.port_a.Q_flow + (TC_10_23.port_a.Q_flow + (TC_10_217.port_a.Q_flow + TC_10_0.port_a.Q_flow))))) = 0.0; CABI0CabiA010001001.port.T = TC_10_0.port_a.T; CABI0CabiA010001001.port.T = TC_10_11.port_a.T; CABI0CabiA010001001.port.T = TC_10_217.port_a.T; CABI0CabiA010001001.port.T = TC_10_23.port_a.T; CABI0CabiA010001001.port.T = TC_9_10.port_b.T; CABI0CabiA010001001.port.T = TsCABI0CabiA010001001.port.T; TsCABI0CabiA009001001.port.Q_flow + (TC_8_9.port_b.Q_flow + (CABI0CabiA009001001.port.Q_flow + (TC_9_10.port_a.Q_flow + (TC_9_22.port_a.Q_flow + (TC_9_216.port_a.Q_flow + TC_9_0.port_a.Q_flow))))) = 0.0; CABI0CabiA009001001.port.T = TC_8_9.port_b.T; CABI0CabiA009001001.port.T = TC_9_0.port_a.T; CABI0CabiA009001001.port.T = TC_9_10.port_a.T; CABI0CabiA009001001.port.T = TC_9_216.port_a.T; CABI0CabiA009001001.port.T = TC_9_22.port_a.T; CABI0CabiA009001001.port.T = TsCABI0CabiA009001001.port.T; TsCABI0CabiA008001001.port.Q_flow + (TC_7_8.port_b.Q_flow + (CABI0CabiA008001001.port.Q_flow + (TC_8_9.port_a.Q_flow + (TC_8_21.port_a.Q_flow + (TC_8_215.port_a.Q_flow + TC_8_0.port_a.Q_flow))))) = 0.0; CABI0CabiA008001001.port.T = TC_7_8.port_b.T; CABI0CabiA008001001.port.T = TC_8_0.port_a.T; CABI0CabiA008001001.port.T = TC_8_21.port_a.T; CABI0CabiA008001001.port.T = TC_8_215.port_a.T; CABI0CabiA008001001.port.T = TC_8_9.port_a.T; CABI0CabiA008001001.port.T = TsCABI0CabiA008001001.port.T; TsCABI0CabiA007001001.port.Q_flow + (TC_6_7.port_b.Q_flow + (CABI0CabiA007001001.port.Q_flow + (TC_7_8.port_a.Q_flow + (TC_7_20.port_a.Q_flow + (TC_7_214.port_a.Q_flow + TC_7_0.port_a.Q_flow))))) = 0.0; CABI0CabiA007001001.port.T = TC_6_7.port_b.T; CABI0CabiA007001001.port.T = TC_7_0.port_a.T; CABI0CabiA007001001.port.T = TC_7_20.port_a.T; CABI0CabiA007001001.port.T = TC_7_214.port_a.T; CABI0CabiA007001001.port.T = TC_7_8.port_a.T; CABI0CabiA007001001.port.T = TsCABI0CabiA007001001.port.T; TsCABI0CabiA006001001.port.Q_flow + (TC_5_6.port_b.Q_flow + (CABI0CabiA006001001.port.Q_flow + (TC_6_7.port_a.Q_flow + (TC_6_19.port_a.Q_flow + (TC_6_213.port_a.Q_flow + TC_6_0.port_a.Q_flow))))) = 0.0; CABI0CabiA006001001.port.T = TC_5_6.port_b.T; CABI0CabiA006001001.port.T = TC_6_0.port_a.T; CABI0CabiA006001001.port.T = TC_6_19.port_a.T; CABI0CabiA006001001.port.T = TC_6_213.port_a.T; CABI0CabiA006001001.port.T = TC_6_7.port_a.T; CABI0CabiA006001001.port.T = TsCABI0CabiA006001001.port.T; TsCABI0CabiA005001001.port.Q_flow + (TC_4_5.port_b.Q_flow + (CABI0CabiA005001001.port.Q_flow + (TC_5_6.port_a.Q_flow + (TC_5_18.port_a.Q_flow + (TC_5_212.port_a.Q_flow + TC_5_0.port_a.Q_flow))))) = 0.0; CABI0CabiA005001001.port.T = TC_4_5.port_b.T; CABI0CabiA005001001.port.T = TC_5_0.port_a.T; CABI0CabiA005001001.port.T = TC_5_18.port_a.T; CABI0CabiA005001001.port.T = TC_5_212.port_a.T; CABI0CabiA005001001.port.T = TC_5_6.port_a.T; CABI0CabiA005001001.port.T = TsCABI0CabiA005001001.port.T; TsCABI0CabiA004001001.port.Q_flow + (TC_3_4.port_b.Q_flow + (CABI0CabiA004001001.port.Q_flow + (TC_4_5.port_a.Q_flow + (TC_4_17.port_a.Q_flow + (TC_4_211.port_a.Q_flow + TC_4_0.port_a.Q_flow))))) = 0.0; CABI0CabiA004001001.port.T = TC_3_4.port_b.T; CABI0CabiA004001001.port.T = TC_4_0.port_a.T; CABI0CabiA004001001.port.T = TC_4_17.port_a.T; CABI0CabiA004001001.port.T = TC_4_211.port_a.T; CABI0CabiA004001001.port.T = TC_4_5.port_a.T; CABI0CabiA004001001.port.T = TsCABI0CabiA004001001.port.T; TsCABI0CabiA003001001.port.Q_flow + (TC_2_3.port_b.Q_flow + (CABI0CabiA003001001.port.Q_flow + (TC_3_4.port_a.Q_flow + (TC_3_16.port_a.Q_flow + (TC_3_210.port_a.Q_flow + TC_3_0.port_a.Q_flow))))) = 0.0; CABI0CabiA003001001.port.T = TC_2_3.port_b.T; CABI0CabiA003001001.port.T = TC_3_0.port_a.T; CABI0CabiA003001001.port.T = TC_3_16.port_a.T; CABI0CabiA003001001.port.T = TC_3_210.port_a.T; CABI0CabiA003001001.port.T = TC_3_4.port_a.T; CABI0CabiA003001001.port.T = TsCABI0CabiA003001001.port.T; TsCABI0CabiA002001001.port.Q_flow + (TC_1_2.port_b.Q_flow + (CABI0CabiA002001001.port.Q_flow + (TC_2_3.port_a.Q_flow + (TC_2_15.port_a.Q_flow + (TC_2_209.port_a.Q_flow + TC_2_0.port_a.Q_flow))))) = 0.0; CABI0CabiA002001001.port.T = TC_1_2.port_b.T; CABI0CabiA002001001.port.T = TC_2_0.port_a.T; CABI0CabiA002001001.port.T = TC_2_15.port_a.T; CABI0CabiA002001001.port.T = TC_2_209.port_a.T; CABI0CabiA002001001.port.T = TC_2_3.port_a.T; CABI0CabiA002001001.port.T = TsCABI0CabiA002001001.port.T; TsCABI0CabiA001001001.port.Q_flow + (CABI0CabiA001001001.port.Q_flow + (TC_1_2.port_a.Q_flow + (TC_1_14.port_a.Q_flow + (TC_1_424.port_a.Q_flow + TC_1_0.port_a.Q_flow)))) = 0.0; CABI0CabiA001001001.port.T = TC_1_0.port_a.T; CABI0CabiA001001001.port.T = TC_1_14.port_a.T; CABI0CabiA001001001.port.T = TC_1_2.port_a.T; CABI0CabiA001001001.port.T = TC_1_424.port_a.T; CABI0CabiA001001001.port.T = TsCABI0CabiA001001001.port.T; TC_740_0.port_b.Q_flow + FixedTemp740.port.Q_flow = 0.0; FixedTemp740.port.T = TC_740_0.port_b.T; TC_739_0.port_b.Q_flow + FixedTemp739.port.Q_flow = 0.0; FixedTemp739.port.T = TC_739_0.port_b.T; TC_738_0.port_b.Q_flow + FixedTemp738.port.Q_flow = 0.0; FixedTemp738.port.T = TC_738_0.port_b.T; TC_737_0.port_b.Q_flow + FixedTemp737.port.Q_flow = 0.0; FixedTemp737.port.T = TC_737_0.port_b.T; TC_736_0.port_b.Q_flow + FixedTemp736.port.Q_flow = 0.0; FixedTemp736.port.T = TC_736_0.port_b.T; TC_735_0.port_b.Q_flow + FixedTemp735.port.Q_flow = 0.0; FixedTemp735.port.T = TC_735_0.port_b.T; TC_734_0.port_b.Q_flow + FixedTemp734.port.Q_flow = 0.0; FixedTemp734.port.T = TC_734_0.port_b.T; TC_733_0.port_b.Q_flow + FixedTemp733.port.Q_flow = 0.0; FixedTemp733.port.T = TC_733_0.port_b.T; TC_732_0.port_b.Q_flow + FixedTemp732.port.Q_flow = 0.0; FixedTemp732.port.T = TC_732_0.port_b.T; TC_731_0.port_b.Q_flow + FixedTemp731.port.Q_flow = 0.0; FixedTemp731.port.T = TC_731_0.port_b.T; TC_730_0.port_b.Q_flow + FixedTemp730.port.Q_flow = 0.0; FixedTemp730.port.T = TC_730_0.port_b.T; TC_729_0.port_b.Q_flow + FixedTemp729.port.Q_flow = 0.0; FixedTemp729.port.T = TC_729_0.port_b.T; TC_728_0.port_b.Q_flow + FixedTemp728.port.Q_flow = 0.0; FixedTemp728.port.T = TC_728_0.port_b.T; TC_727_0.port_b.Q_flow + FixedTemp727.port.Q_flow = 0.0; FixedTemp727.port.T = TC_727_0.port_b.T; TC_726_0.port_b.Q_flow + FixedTemp726.port.Q_flow = 0.0; FixedTemp726.port.T = TC_726_0.port_b.T; TC_725_0.port_b.Q_flow + FixedTemp725.port.Q_flow = 0.0; FixedTemp725.port.T = TC_725_0.port_b.T; TC_724_0.port_b.Q_flow + FixedTemp724.port.Q_flow = 0.0; FixedTemp724.port.T = TC_724_0.port_b.T; TC_723_0.port_b.Q_flow + FixedTemp723.port.Q_flow = 0.0; FixedTemp723.port.T = TC_723_0.port_b.T; TC_722_0.port_b.Q_flow + FixedTemp722.port.Q_flow = 0.0; FixedTemp722.port.T = TC_722_0.port_b.T; TC_721_0.port_b.Q_flow + FixedTemp721.port.Q_flow = 0.0; FixedTemp721.port.T = TC_721_0.port_b.T; TC_720_0.port_b.Q_flow + FixedTemp720.port.Q_flow = 0.0; FixedTemp720.port.T = TC_720_0.port_b.T; TC_719_0.port_b.Q_flow + FixedTemp719.port.Q_flow = 0.0; FixedTemp719.port.T = TC_719_0.port_b.T; TC_718_0.port_b.Q_flow + FixedTemp718.port.Q_flow = 0.0; FixedTemp718.port.T = TC_718_0.port_b.T; TC_717_0.port_b.Q_flow + FixedTemp717.port.Q_flow = 0.0; FixedTemp717.port.T = TC_717_0.port_b.T; TC_716_0.port_b.Q_flow + FixedTemp716.port.Q_flow = 0.0; FixedTemp716.port.T = TC_716_0.port_b.T; TC_715_0.port_b.Q_flow + FixedTemp715.port.Q_flow = 0.0; FixedTemp715.port.T = TC_715_0.port_b.T; TC_714_0.port_b.Q_flow + FixedTemp714.port.Q_flow = 0.0; FixedTemp714.port.T = TC_714_0.port_b.T; TC_713_0.port_b.Q_flow + FixedTemp713.port.Q_flow = 0.0; FixedTemp713.port.T = TC_713_0.port_b.T; TC_712_0.port_b.Q_flow + FixedTemp712.port.Q_flow = 0.0; FixedTemp712.port.T = TC_712_0.port_b.T; TC_711_0.port_b.Q_flow + FixedTemp711.port.Q_flow = 0.0; FixedTemp711.port.T = TC_711_0.port_b.T; TC_710_0.port_b.Q_flow + FixedTemp710.port.Q_flow = 0.0; FixedTemp710.port.T = TC_710_0.port_b.T; TC_709_0.port_b.Q_flow + FixedTemp709.port.Q_flow = 0.0; FixedTemp709.port.T = TC_709_0.port_b.T; TC_708_0.port_b.Q_flow + FixedTemp708.port.Q_flow = 0.0; FixedTemp708.port.T = TC_708_0.port_b.T; TC_707_0.port_b.Q_flow + FixedTemp707.port.Q_flow = 0.0; FixedTemp707.port.T = TC_707_0.port_b.T; TC_706_0.port_b.Q_flow + FixedTemp706.port.Q_flow = 0.0; FixedTemp706.port.T = TC_706_0.port_b.T; TC_705_0.port_b.Q_flow + FixedTemp705.port.Q_flow = 0.0; FixedTemp705.port.T = TC_705_0.port_b.T; TC_704_0.port_b.Q_flow + FixedTemp704.port.Q_flow = 0.0; FixedTemp704.port.T = TC_704_0.port_b.T; TC_703_0.port_b.Q_flow + FixedTemp703.port.Q_flow = 0.0; FixedTemp703.port.T = TC_703_0.port_b.T; TC_702_0.port_b.Q_flow + FixedTemp702.port.Q_flow = 0.0; FixedTemp702.port.T = TC_702_0.port_b.T; TC_701_0.port_b.Q_flow + FixedTemp701.port.Q_flow = 0.0; FixedTemp701.port.T = TC_701_0.port_b.T; TC_700_0.port_b.Q_flow + FixedTemp700.port.Q_flow = 0.0; FixedTemp700.port.T = TC_700_0.port_b.T; TC_699_0.port_b.Q_flow + FixedTemp699.port.Q_flow = 0.0; FixedTemp699.port.T = TC_699_0.port_b.T; TC_698_0.port_b.Q_flow + FixedTemp698.port.Q_flow = 0.0; FixedTemp698.port.T = TC_698_0.port_b.T; TC_697_0.port_b.Q_flow + FixedTemp697.port.Q_flow = 0.0; FixedTemp697.port.T = TC_697_0.port_b.T; TC_696_0.port_b.Q_flow + FixedTemp696.port.Q_flow = 0.0; FixedTemp696.port.T = TC_696_0.port_b.T; TC_695_0.port_b.Q_flow + FixedTemp695.port.Q_flow = 0.0; FixedTemp695.port.T = TC_695_0.port_b.T; TC_694_0.port_b.Q_flow + FixedTemp694.port.Q_flow = 0.0; FixedTemp694.port.T = TC_694_0.port_b.T; TC_693_0.port_b.Q_flow + FixedTemp693.port.Q_flow = 0.0; FixedTemp693.port.T = TC_693_0.port_b.T; TC_692_0.port_b.Q_flow + FixedTemp692.port.Q_flow = 0.0; FixedTemp692.port.T = TC_692_0.port_b.T; TC_691_0.port_b.Q_flow + FixedTemp691.port.Q_flow = 0.0; FixedTemp691.port.T = TC_691_0.port_b.T; TC_690_0.port_b.Q_flow + FixedTemp690.port.Q_flow = 0.0; FixedTemp690.port.T = TC_690_0.port_b.T; TC_689_0.port_b.Q_flow + FixedTemp689.port.Q_flow = 0.0; FixedTemp689.port.T = TC_689_0.port_b.T; TC_688_0.port_b.Q_flow + FixedTemp688.port.Q_flow = 0.0; FixedTemp688.port.T = TC_688_0.port_b.T; TC_687_0.port_b.Q_flow + FixedTemp687.port.Q_flow = 0.0; FixedTemp687.port.T = TC_687_0.port_b.T; TC_686_0.port_b.Q_flow + FixedTemp686.port.Q_flow = 0.0; FixedTemp686.port.T = TC_686_0.port_b.T; TC_685_0.port_b.Q_flow + FixedTemp685.port.Q_flow = 0.0; FixedTemp685.port.T = TC_685_0.port_b.T; TC_684_0.port_b.Q_flow + FixedTemp684.port.Q_flow = 0.0; FixedTemp684.port.T = TC_684_0.port_b.T; TC_683_0.port_b.Q_flow + FixedTemp683.port.Q_flow = 0.0; FixedTemp683.port.T = TC_683_0.port_b.T; TC_682_0.port_b.Q_flow + FixedTemp682.port.Q_flow = 0.0; FixedTemp682.port.T = TC_682_0.port_b.T; TC_681_0.port_b.Q_flow + FixedTemp681.port.Q_flow = 0.0; FixedTemp681.port.T = TC_681_0.port_b.T; TC_680_0.port_b.Q_flow + FixedTemp680.port.Q_flow = 0.0; FixedTemp680.port.T = TC_680_0.port_b.T; TC_679_0.port_b.Q_flow + FixedTemp679.port.Q_flow = 0.0; FixedTemp679.port.T = TC_679_0.port_b.T; TC_678_0.port_b.Q_flow + FixedTemp678.port.Q_flow = 0.0; FixedTemp678.port.T = TC_678_0.port_b.T; TC_677_0.port_b.Q_flow + FixedTemp677.port.Q_flow = 0.0; FixedTemp677.port.T = TC_677_0.port_b.T; TC_676_0.port_b.Q_flow + FixedTemp676.port.Q_flow = 0.0; FixedTemp676.port.T = TC_676_0.port_b.T; TC_675_0.port_b.Q_flow + FixedTemp675.port.Q_flow = 0.0; FixedTemp675.port.T = TC_675_0.port_b.T; TC_674_0.port_b.Q_flow + FixedTemp674.port.Q_flow = 0.0; FixedTemp674.port.T = TC_674_0.port_b.T; TC_673_0.port_b.Q_flow + FixedTemp673.port.Q_flow = 0.0; FixedTemp673.port.T = TC_673_0.port_b.T; TC_672_0.port_b.Q_flow + FixedTemp672.port.Q_flow = 0.0; FixedTemp672.port.T = TC_672_0.port_b.T; TC_671_0.port_b.Q_flow + FixedTemp671.port.Q_flow = 0.0; FixedTemp671.port.T = TC_671_0.port_b.T; TC_670_0.port_b.Q_flow + FixedTemp670.port.Q_flow = 0.0; FixedTemp670.port.T = TC_670_0.port_b.T; TC_669_0.port_b.Q_flow + FixedTemp669.port.Q_flow = 0.0; FixedTemp669.port.T = TC_669_0.port_b.T; TC_668_0.port_b.Q_flow + FixedTemp668.port.Q_flow = 0.0; FixedTemp668.port.T = TC_668_0.port_b.T; TC_667_0.port_b.Q_flow + FixedTemp667.port.Q_flow = 0.0; FixedTemp667.port.T = TC_667_0.port_b.T; TC_666_0.port_b.Q_flow + FixedTemp666.port.Q_flow = 0.0; FixedTemp666.port.T = TC_666_0.port_b.T; TC_665_0.port_b.Q_flow + FixedTemp665.port.Q_flow = 0.0; FixedTemp665.port.T = TC_665_0.port_b.T; TC_664_0.port_b.Q_flow + FixedTemp664.port.Q_flow = 0.0; FixedTemp664.port.T = TC_664_0.port_b.T; TC_663_0.port_b.Q_flow + FixedTemp663.port.Q_flow = 0.0; FixedTemp663.port.T = TC_663_0.port_b.T; TC_662_0.port_b.Q_flow + FixedTemp662.port.Q_flow = 0.0; FixedTemp662.port.T = TC_662_0.port_b.T; TC_661_0.port_b.Q_flow + FixedTemp661.port.Q_flow = 0.0; FixedTemp661.port.T = TC_661_0.port_b.T; TC_660_0.port_b.Q_flow + FixedTemp660.port.Q_flow = 0.0; FixedTemp660.port.T = TC_660_0.port_b.T; TC_659_0.port_b.Q_flow + FixedTemp659.port.Q_flow = 0.0; FixedTemp659.port.T = TC_659_0.port_b.T; TC_658_0.port_b.Q_flow + FixedTemp658.port.Q_flow = 0.0; FixedTemp658.port.T = TC_658_0.port_b.T; TC_657_0.port_b.Q_flow + FixedTemp657.port.Q_flow = 0.0; FixedTemp657.port.T = TC_657_0.port_b.T; TC_656_0.port_b.Q_flow + FixedTemp656.port.Q_flow = 0.0; FixedTemp656.port.T = TC_656_0.port_b.T; TC_655_0.port_b.Q_flow + FixedTemp655.port.Q_flow = 0.0; FixedTemp655.port.T = TC_655_0.port_b.T; TC_654_0.port_b.Q_flow + FixedTemp654.port.Q_flow = 0.0; FixedTemp654.port.T = TC_654_0.port_b.T; TC_653_0.port_b.Q_flow + FixedTemp653.port.Q_flow = 0.0; FixedTemp653.port.T = TC_653_0.port_b.T; TC_652_0.port_b.Q_flow + FixedTemp652.port.Q_flow = 0.0; FixedTemp652.port.T = TC_652_0.port_b.T; TC_651_0.port_b.Q_flow + FixedTemp651.port.Q_flow = 0.0; FixedTemp651.port.T = TC_651_0.port_b.T; TC_650_0.port_b.Q_flow + FixedTemp650.port.Q_flow = 0.0; FixedTemp650.port.T = TC_650_0.port_b.T; TC_649_0.port_b.Q_flow + FixedTemp649.port.Q_flow = 0.0; FixedTemp649.port.T = TC_649_0.port_b.T; TC_648_0.port_b.Q_flow + FixedTemp648.port.Q_flow = 0.0; FixedTemp648.port.T = TC_648_0.port_b.T; TC_647_0.port_b.Q_flow + FixedTemp647.port.Q_flow = 0.0; FixedTemp647.port.T = TC_647_0.port_b.T; TC_646_0.port_b.Q_flow + FixedTemp646.port.Q_flow = 0.0; FixedTemp646.port.T = TC_646_0.port_b.T; TC_645_0.port_b.Q_flow + FixedTemp645.port.Q_flow = 0.0; FixedTemp645.port.T = TC_645_0.port_b.T; TC_644_0.port_b.Q_flow + FixedTemp644.port.Q_flow = 0.0; FixedTemp644.port.T = TC_644_0.port_b.T; TC_643_0.port_b.Q_flow + FixedTemp643.port.Q_flow = 0.0; FixedTemp643.port.T = TC_643_0.port_b.T; TC_642_0.port_b.Q_flow + FixedTemp642.port.Q_flow = 0.0; FixedTemp642.port.T = TC_642_0.port_b.T; TC_641_0.port_b.Q_flow + FixedTemp641.port.Q_flow = 0.0; FixedTemp641.port.T = TC_641_0.port_b.T; TC_640_0.port_b.Q_flow + FixedTemp640.port.Q_flow = 0.0; FixedTemp640.port.T = TC_640_0.port_b.T; TC_639_0.port_b.Q_flow + FixedTemp639.port.Q_flow = 0.0; FixedTemp639.port.T = TC_639_0.port_b.T; TC_638_0.port_b.Q_flow + FixedTemp638.port.Q_flow = 0.0; FixedTemp638.port.T = TC_638_0.port_b.T; TC_637_0.port_b.Q_flow + FixedTemp637.port.Q_flow = 0.0; FixedTemp637.port.T = TC_637_0.port_b.T; TC_636_0.port_b.Q_flow + FixedTemp636.port.Q_flow = 0.0; FixedTemp636.port.T = TC_636_0.port_b.T; TC_635_0.port_b.Q_flow + FixedTemp635.port.Q_flow = 0.0; FixedTemp635.port.T = TC_635_0.port_b.T; TC_634_0.port_b.Q_flow + FixedTemp634.port.Q_flow = 0.0; FixedTemp634.port.T = TC_634_0.port_b.T; TC_633_0.port_b.Q_flow + FixedTemp633.port.Q_flow = 0.0; FixedTemp633.port.T = TC_633_0.port_b.T; TC_632_0.port_b.Q_flow + FixedTemp632.port.Q_flow = 0.0; FixedTemp632.port.T = TC_632_0.port_b.T; TC_631_0.port_b.Q_flow + FixedTemp631.port.Q_flow = 0.0; FixedTemp631.port.T = TC_631_0.port_b.T; TC_630_0.port_b.Q_flow + FixedTemp630.port.Q_flow = 0.0; FixedTemp630.port.T = TC_630_0.port_b.T; TC_629_0.port_b.Q_flow + FixedTemp629.port.Q_flow = 0.0; FixedTemp629.port.T = TC_629_0.port_b.T; TC_628_0.port_b.Q_flow + FixedTemp628.port.Q_flow = 0.0; FixedTemp628.port.T = TC_628_0.port_b.T; TC_627_0.port_b.Q_flow + FixedTemp627.port.Q_flow = 0.0; FixedTemp627.port.T = TC_627_0.port_b.T; TC_626_0.port_b.Q_flow + FixedTemp626.port.Q_flow = 0.0; FixedTemp626.port.T = TC_626_0.port_b.T; TC_625_0.port_b.Q_flow + FixedTemp625.port.Q_flow = 0.0; FixedTemp625.port.T = TC_625_0.port_b.T; TC_624_0.port_b.Q_flow + FixedTemp624.port.Q_flow = 0.0; FixedTemp624.port.T = TC_624_0.port_b.T; TC_623_0.port_b.Q_flow + FixedTemp623.port.Q_flow = 0.0; FixedTemp623.port.T = TC_623_0.port_b.T; TC_622_0.port_b.Q_flow + FixedTemp622.port.Q_flow = 0.0; FixedTemp622.port.T = TC_622_0.port_b.T; TC_621_0.port_b.Q_flow + FixedTemp621.port.Q_flow = 0.0; FixedTemp621.port.T = TC_621_0.port_b.T; TC_620_0.port_b.Q_flow + FixedTemp620.port.Q_flow = 0.0; FixedTemp620.port.T = TC_620_0.port_b.T; TC_619_0.port_b.Q_flow + FixedTemp619.port.Q_flow = 0.0; FixedTemp619.port.T = TC_619_0.port_b.T; TC_618_0.port_b.Q_flow + FixedTemp618.port.Q_flow = 0.0; FixedTemp618.port.T = TC_618_0.port_b.T; TC_617_0.port_b.Q_flow + FixedTemp617.port.Q_flow = 0.0; FixedTemp617.port.T = TC_617_0.port_b.T; TC_616_0.port_b.Q_flow + FixedTemp616.port.Q_flow = 0.0; FixedTemp616.port.T = TC_616_0.port_b.T; TC_615_0.port_b.Q_flow + FixedTemp615.port.Q_flow = 0.0; FixedTemp615.port.T = TC_615_0.port_b.T; TC_614_0.port_b.Q_flow + FixedTemp614.port.Q_flow = 0.0; FixedTemp614.port.T = TC_614_0.port_b.T; TC_613_0.port_b.Q_flow + FixedTemp613.port.Q_flow = 0.0; FixedTemp613.port.T = TC_613_0.port_b.T; TC_612_0.port_b.Q_flow + FixedTemp612.port.Q_flow = 0.0; FixedTemp612.port.T = TC_612_0.port_b.T; TC_611_0.port_b.Q_flow + FixedTemp611.port.Q_flow = 0.0; FixedTemp611.port.T = TC_611_0.port_b.T; TC_610_0.port_b.Q_flow + FixedTemp610.port.Q_flow = 0.0; FixedTemp610.port.T = TC_610_0.port_b.T; TC_609_0.port_b.Q_flow + FixedTemp609.port.Q_flow = 0.0; FixedTemp609.port.T = TC_609_0.port_b.T; TC_608_0.port_b.Q_flow + FixedTemp608.port.Q_flow = 0.0; FixedTemp608.port.T = TC_608_0.port_b.T; TC_607_0.port_b.Q_flow + FixedTemp607.port.Q_flow = 0.0; FixedTemp607.port.T = TC_607_0.port_b.T; TC_606_0.port_b.Q_flow + FixedTemp606.port.Q_flow = 0.0; FixedTemp606.port.T = TC_606_0.port_b.T; TC_605_0.port_b.Q_flow + FixedTemp605.port.Q_flow = 0.0; FixedTemp605.port.T = TC_605_0.port_b.T; TC_604_0.port_b.Q_flow + FixedTemp604.port.Q_flow = 0.0; FixedTemp604.port.T = TC_604_0.port_b.T; TC_603_0.port_b.Q_flow + FixedTemp603.port.Q_flow = 0.0; FixedTemp603.port.T = TC_603_0.port_b.T; TC_602_0.port_b.Q_flow + FixedTemp602.port.Q_flow = 0.0; FixedTemp602.port.T = TC_602_0.port_b.T; TC_601_0.port_b.Q_flow + FixedTemp601.port.Q_flow = 0.0; FixedTemp601.port.T = TC_601_0.port_b.T; TC_600_0.port_b.Q_flow + FixedTemp600.port.Q_flow = 0.0; FixedTemp600.port.T = TC_600_0.port_b.T; TC_599_0.port_b.Q_flow + FixedTemp599.port.Q_flow = 0.0; FixedTemp599.port.T = TC_599_0.port_b.T; TC_598_0.port_b.Q_flow + FixedTemp598.port.Q_flow = 0.0; FixedTemp598.port.T = TC_598_0.port_b.T; TC_597_0.port_b.Q_flow + FixedTemp597.port.Q_flow = 0.0; FixedTemp597.port.T = TC_597_0.port_b.T; TC_596_0.port_b.Q_flow + FixedTemp596.port.Q_flow = 0.0; FixedTemp596.port.T = TC_596_0.port_b.T; TC_595_0.port_b.Q_flow + FixedTemp595.port.Q_flow = 0.0; FixedTemp595.port.T = TC_595_0.port_b.T; TC_594_0.port_b.Q_flow + FixedTemp594.port.Q_flow = 0.0; FixedTemp594.port.T = TC_594_0.port_b.T; TC_593_0.port_b.Q_flow + FixedTemp593.port.Q_flow = 0.0; FixedTemp593.port.T = TC_593_0.port_b.T; TC_592_0.port_b.Q_flow + FixedTemp592.port.Q_flow = 0.0; FixedTemp592.port.T = TC_592_0.port_b.T; TC_591_0.port_b.Q_flow + FixedTemp591.port.Q_flow = 0.0; FixedTemp591.port.T = TC_591_0.port_b.T; TC_590_0.port_b.Q_flow + FixedTemp590.port.Q_flow = 0.0; FixedTemp590.port.T = TC_590_0.port_b.T; TC_589_0.port_b.Q_flow + FixedTemp589.port.Q_flow = 0.0; FixedTemp589.port.T = TC_589_0.port_b.T; TC_588_0.port_b.Q_flow + FixedTemp588.port.Q_flow = 0.0; FixedTemp588.port.T = TC_588_0.port_b.T; TC_587_0.port_b.Q_flow + FixedTemp587.port.Q_flow = 0.0; FixedTemp587.port.T = TC_587_0.port_b.T; TC_586_0.port_b.Q_flow + FixedTemp586.port.Q_flow = 0.0; FixedTemp586.port.T = TC_586_0.port_b.T; TC_585_0.port_b.Q_flow + FixedTemp585.port.Q_flow = 0.0; FixedTemp585.port.T = TC_585_0.port_b.T; TC_584_0.port_b.Q_flow + FixedTemp584.port.Q_flow = 0.0; FixedTemp584.port.T = TC_584_0.port_b.T; TC_583_0.port_b.Q_flow + FixedTemp583.port.Q_flow = 0.0; FixedTemp583.port.T = TC_583_0.port_b.T; TC_582_0.port_b.Q_flow + FixedTemp582.port.Q_flow = 0.0; FixedTemp582.port.T = TC_582_0.port_b.T; TC_581_0.port_b.Q_flow + FixedTemp581.port.Q_flow = 0.0; FixedTemp581.port.T = TC_581_0.port_b.T; TC_580_0.port_b.Q_flow + FixedTemp580.port.Q_flow = 0.0; FixedTemp580.port.T = TC_580_0.port_b.T; TC_579_0.port_b.Q_flow + FixedTemp579.port.Q_flow = 0.0; FixedTemp579.port.T = TC_579_0.port_b.T; TC_578_0.port_b.Q_flow + FixedTemp578.port.Q_flow = 0.0; FixedTemp578.port.T = TC_578_0.port_b.T; TC_577_0.port_b.Q_flow + FixedTemp577.port.Q_flow = 0.0; FixedTemp577.port.T = TC_577_0.port_b.T; TC_576_0.port_b.Q_flow + FixedTemp576.port.Q_flow = 0.0; FixedTemp576.port.T = TC_576_0.port_b.T; TC_575_0.port_b.Q_flow + FixedTemp575.port.Q_flow = 0.0; FixedTemp575.port.T = TC_575_0.port_b.T; TC_574_0.port_b.Q_flow + FixedTemp574.port.Q_flow = 0.0; FixedTemp574.port.T = TC_574_0.port_b.T; TC_573_0.port_b.Q_flow + FixedTemp573.port.Q_flow = 0.0; FixedTemp573.port.T = TC_573_0.port_b.T; TC_572_0.port_b.Q_flow + FixedTemp572.port.Q_flow = 0.0; FixedTemp572.port.T = TC_572_0.port_b.T; TC_571_0.port_b.Q_flow + FixedTemp571.port.Q_flow = 0.0; FixedTemp571.port.T = TC_571_0.port_b.T; TC_570_0.port_b.Q_flow + FixedTemp570.port.Q_flow = 0.0; FixedTemp570.port.T = TC_570_0.port_b.T; TC_569_0.port_b.Q_flow + FixedTemp569.port.Q_flow = 0.0; FixedTemp569.port.T = TC_569_0.port_b.T; TC_568_0.port_b.Q_flow + FixedTemp568.port.Q_flow = 0.0; FixedTemp568.port.T = TC_568_0.port_b.T; TC_567_0.port_b.Q_flow + FixedTemp567.port.Q_flow = 0.0; FixedTemp567.port.T = TC_567_0.port_b.T; TC_566_0.port_b.Q_flow + FixedTemp566.port.Q_flow = 0.0; FixedTemp566.port.T = TC_566_0.port_b.T; TC_565_0.port_b.Q_flow + FixedTemp565.port.Q_flow = 0.0; FixedTemp565.port.T = TC_565_0.port_b.T; TC_564_0.port_b.Q_flow + FixedTemp564.port.Q_flow = 0.0; FixedTemp564.port.T = TC_564_0.port_b.T; TC_563_0.port_b.Q_flow + FixedTemp563.port.Q_flow = 0.0; FixedTemp563.port.T = TC_563_0.port_b.T; TC_562_0.port_b.Q_flow + FixedTemp562.port.Q_flow = 0.0; FixedTemp562.port.T = TC_562_0.port_b.T; TC_561_0.port_b.Q_flow + FixedTemp561.port.Q_flow = 0.0; FixedTemp561.port.T = TC_561_0.port_b.T; TC_560_0.port_b.Q_flow + FixedTemp560.port.Q_flow = 0.0; FixedTemp560.port.T = TC_560_0.port_b.T; TC_559_0.port_b.Q_flow + FixedTemp559.port.Q_flow = 0.0; FixedTemp559.port.T = TC_559_0.port_b.T; TC_558_0.port_b.Q_flow + FixedTemp558.port.Q_flow = 0.0; FixedTemp558.port.T = TC_558_0.port_b.T; TC_557_0.port_b.Q_flow + FixedTemp557.port.Q_flow = 0.0; FixedTemp557.port.T = TC_557_0.port_b.T; TC_556_0.port_b.Q_flow + FixedTemp556.port.Q_flow = 0.0; FixedTemp556.port.T = TC_556_0.port_b.T; TC_555_0.port_b.Q_flow + FixedTemp555.port.Q_flow = 0.0; FixedTemp555.port.T = TC_555_0.port_b.T; TC_554_0.port_b.Q_flow + FixedTemp554.port.Q_flow = 0.0; FixedTemp554.port.T = TC_554_0.port_b.T; TC_553_0.port_b.Q_flow + FixedTemp553.port.Q_flow = 0.0; FixedTemp553.port.T = TC_553_0.port_b.T; TC_552_0.port_b.Q_flow + FixedTemp552.port.Q_flow = 0.0; FixedTemp552.port.T = TC_552_0.port_b.T; TC_551_0.port_b.Q_flow + FixedTemp551.port.Q_flow = 0.0; FixedTemp551.port.T = TC_551_0.port_b.T; TC_550_0.port_b.Q_flow + FixedTemp550.port.Q_flow = 0.0; FixedTemp550.port.T = TC_550_0.port_b.T; TC_549_0.port_b.Q_flow + FixedTemp549.port.Q_flow = 0.0; FixedTemp549.port.T = TC_549_0.port_b.T; TC_548_0.port_b.Q_flow + FixedTemp548.port.Q_flow = 0.0; FixedTemp548.port.T = TC_548_0.port_b.T; TC_547_0.port_b.Q_flow + FixedTemp547.port.Q_flow = 0.0; FixedTemp547.port.T = TC_547_0.port_b.T; TC_546_0.port_b.Q_flow + FixedTemp546.port.Q_flow = 0.0; FixedTemp546.port.T = TC_546_0.port_b.T; TC_545_0.port_b.Q_flow + FixedTemp545.port.Q_flow = 0.0; FixedTemp545.port.T = TC_545_0.port_b.T; TC_544_0.port_b.Q_flow + FixedTemp544.port.Q_flow = 0.0; FixedTemp544.port.T = TC_544_0.port_b.T; TC_543_0.port_b.Q_flow + FixedTemp543.port.Q_flow = 0.0; FixedTemp543.port.T = TC_543_0.port_b.T; TC_542_0.port_b.Q_flow + FixedTemp542.port.Q_flow = 0.0; FixedTemp542.port.T = TC_542_0.port_b.T; TC_541_0.port_b.Q_flow + FixedTemp541.port.Q_flow = 0.0; FixedTemp541.port.T = TC_541_0.port_b.T; TC_540_0.port_b.Q_flow + FixedTemp540.port.Q_flow = 0.0; FixedTemp540.port.T = TC_540_0.port_b.T; TC_539_0.port_b.Q_flow + FixedTemp539.port.Q_flow = 0.0; FixedTemp539.port.T = TC_539_0.port_b.T; TC_538_0.port_b.Q_flow + FixedTemp538.port.Q_flow = 0.0; FixedTemp538.port.T = TC_538_0.port_b.T; TC_537_0.port_b.Q_flow + FixedTemp537.port.Q_flow = 0.0; FixedTemp537.port.T = TC_537_0.port_b.T; TC_536_0.port_b.Q_flow + FixedTemp536.port.Q_flow = 0.0; FixedTemp536.port.T = TC_536_0.port_b.T; TC_535_0.port_b.Q_flow + FixedTemp535.port.Q_flow = 0.0; FixedTemp535.port.T = TC_535_0.port_b.T; TC_534_0.port_b.Q_flow + FixedTemp534.port.Q_flow = 0.0; FixedTemp534.port.T = TC_534_0.port_b.T; TC_533_0.port_b.Q_flow + FixedTemp533.port.Q_flow = 0.0; FixedTemp533.port.T = TC_533_0.port_b.T; TC_532_0.port_b.Q_flow + FixedTemp532.port.Q_flow = 0.0; FixedTemp532.port.T = TC_532_0.port_b.T; TC_531_0.port_b.Q_flow + FixedTemp531.port.Q_flow = 0.0; FixedTemp531.port.T = TC_531_0.port_b.T; TC_530_0.port_b.Q_flow + FixedTemp530.port.Q_flow = 0.0; FixedTemp530.port.T = TC_530_0.port_b.T; TC_529_0.port_b.Q_flow + FixedTemp529.port.Q_flow = 0.0; FixedTemp529.port.T = TC_529_0.port_b.T; TC_528_0.port_b.Q_flow + FixedTemp528.port.Q_flow = 0.0; FixedTemp528.port.T = TC_528_0.port_b.T; TC_527_0.port_b.Q_flow + FixedTemp527.port.Q_flow = 0.0; FixedTemp527.port.T = TC_527_0.port_b.T; TC_526_0.port_b.Q_flow + FixedTemp526.port.Q_flow = 0.0; FixedTemp526.port.T = TC_526_0.port_b.T; TC_525_0.port_b.Q_flow + FixedTemp525.port.Q_flow = 0.0; FixedTemp525.port.T = TC_525_0.port_b.T; TC_524_0.port_b.Q_flow + FixedTemp524.port.Q_flow = 0.0; FixedTemp524.port.T = TC_524_0.port_b.T; TC_523_0.port_b.Q_flow + FixedTemp523.port.Q_flow = 0.0; FixedTemp523.port.T = TC_523_0.port_b.T; TC_522_0.port_b.Q_flow + FixedTemp522.port.Q_flow = 0.0; FixedTemp522.port.T = TC_522_0.port_b.T; TC_521_0.port_b.Q_flow + FixedTemp521.port.Q_flow = 0.0; FixedTemp521.port.T = TC_521_0.port_b.T; TC_520_0.port_b.Q_flow + FixedTemp520.port.Q_flow = 0.0; FixedTemp520.port.T = TC_520_0.port_b.T; TC_519_0.port_b.Q_flow + FixedTemp519.port.Q_flow = 0.0; FixedTemp519.port.T = TC_519_0.port_b.T; TC_518_0.port_b.Q_flow + FixedTemp518.port.Q_flow = 0.0; FixedTemp518.port.T = TC_518_0.port_b.T; TC_517_0.port_b.Q_flow + FixedTemp517.port.Q_flow = 0.0; FixedTemp517.port.T = TC_517_0.port_b.T; TC_516_0.port_b.Q_flow + FixedTemp516.port.Q_flow = 0.0; FixedTemp516.port.T = TC_516_0.port_b.T; TC_515_0.port_b.Q_flow + FixedTemp515.port.Q_flow = 0.0; FixedTemp515.port.T = TC_515_0.port_b.T; TC_514_0.port_b.Q_flow + FixedTemp514.port.Q_flow = 0.0; FixedTemp514.port.T = TC_514_0.port_b.T; TC_513_0.port_b.Q_flow + FixedTemp513.port.Q_flow = 0.0; FixedTemp513.port.T = TC_513_0.port_b.T; TC_512_0.port_b.Q_flow + FixedTemp512.port.Q_flow = 0.0; FixedTemp512.port.T = TC_512_0.port_b.T; TC_511_0.port_b.Q_flow + FixedTemp511.port.Q_flow = 0.0; FixedTemp511.port.T = TC_511_0.port_b.T; TC_510_0.port_b.Q_flow + FixedTemp510.port.Q_flow = 0.0; FixedTemp510.port.T = TC_510_0.port_b.T; TC_509_0.port_b.Q_flow + FixedTemp509.port.Q_flow = 0.0; FixedTemp509.port.T = TC_509_0.port_b.T; TC_508_0.port_b.Q_flow + FixedTemp508.port.Q_flow = 0.0; FixedTemp508.port.T = TC_508_0.port_b.T; TC_507_0.port_b.Q_flow + FixedTemp507.port.Q_flow = 0.0; FixedTemp507.port.T = TC_507_0.port_b.T; TC_506_0.port_b.Q_flow + FixedTemp506.port.Q_flow = 0.0; FixedTemp506.port.T = TC_506_0.port_b.T; TC_505_0.port_b.Q_flow + FixedTemp505.port.Q_flow = 0.0; FixedTemp505.port.T = TC_505_0.port_b.T; TC_504_0.port_b.Q_flow + FixedTemp504.port.Q_flow = 0.0; FixedTemp504.port.T = TC_504_0.port_b.T; TC_503_0.port_b.Q_flow + FixedTemp503.port.Q_flow = 0.0; FixedTemp503.port.T = TC_503_0.port_b.T; TC_502_0.port_b.Q_flow + FixedTemp502.port.Q_flow = 0.0; FixedTemp502.port.T = TC_502_0.port_b.T; TC_501_0.port_b.Q_flow + FixedTemp501.port.Q_flow = 0.0; FixedTemp501.port.T = TC_501_0.port_b.T; TC_500_0.port_b.Q_flow + FixedTemp500.port.Q_flow = 0.0; FixedTemp500.port.T = TC_500_0.port_b.T; TC_499_0.port_b.Q_flow + FixedTemp499.port.Q_flow = 0.0; FixedTemp499.port.T = TC_499_0.port_b.T; TC_498_0.port_b.Q_flow + FixedTemp498.port.Q_flow = 0.0; FixedTemp498.port.T = TC_498_0.port_b.T; TC_497_0.port_b.Q_flow + FixedTemp497.port.Q_flow = 0.0; FixedTemp497.port.T = TC_497_0.port_b.T; TC_496_0.port_b.Q_flow + FixedTemp496.port.Q_flow = 0.0; FixedTemp496.port.T = TC_496_0.port_b.T; TC_495_0.port_b.Q_flow + FixedTemp495.port.Q_flow = 0.0; FixedTemp495.port.T = TC_495_0.port_b.T; TC_494_0.port_b.Q_flow + FixedTemp494.port.Q_flow = 0.0; FixedTemp494.port.T = TC_494_0.port_b.T; TC_493_0.port_b.Q_flow + FixedTemp493.port.Q_flow = 0.0; FixedTemp493.port.T = TC_493_0.port_b.T; TC_492_0.port_b.Q_flow + FixedTemp492.port.Q_flow = 0.0; FixedTemp492.port.T = TC_492_0.port_b.T; TC_491_0.port_b.Q_flow + FixedTemp491.port.Q_flow = 0.0; FixedTemp491.port.T = TC_491_0.port_b.T; TC_490_0.port_b.Q_flow + FixedTemp490.port.Q_flow = 0.0; FixedTemp490.port.T = TC_490_0.port_b.T; TC_489_0.port_b.Q_flow + FixedTemp489.port.Q_flow = 0.0; FixedTemp489.port.T = TC_489_0.port_b.T; TC_488_0.port_b.Q_flow + FixedTemp488.port.Q_flow = 0.0; FixedTemp488.port.T = TC_488_0.port_b.T; TC_487_0.port_b.Q_flow + FixedTemp487.port.Q_flow = 0.0; FixedTemp487.port.T = TC_487_0.port_b.T; TC_486_0.port_b.Q_flow + FixedTemp486.port.Q_flow = 0.0; FixedTemp486.port.T = TC_486_0.port_b.T; TC_485_0.port_b.Q_flow + FixedTemp485.port.Q_flow = 0.0; FixedTemp485.port.T = TC_485_0.port_b.T; TC_484_0.port_b.Q_flow + FixedTemp484.port.Q_flow = 0.0; FixedTemp484.port.T = TC_484_0.port_b.T; TC_483_0.port_b.Q_flow + FixedTemp483.port.Q_flow = 0.0; FixedTemp483.port.T = TC_483_0.port_b.T; TC_482_0.port_b.Q_flow + FixedTemp482.port.Q_flow = 0.0; FixedTemp482.port.T = TC_482_0.port_b.T; TC_481_0.port_b.Q_flow + FixedTemp481.port.Q_flow = 0.0; FixedTemp481.port.T = TC_481_0.port_b.T; TC_480_0.port_b.Q_flow + FixedTemp480.port.Q_flow = 0.0; FixedTemp480.port.T = TC_480_0.port_b.T; TC_479_0.port_b.Q_flow + FixedTemp479.port.Q_flow = 0.0; FixedTemp479.port.T = TC_479_0.port_b.T; TC_478_0.port_b.Q_flow + FixedTemp478.port.Q_flow = 0.0; FixedTemp478.port.T = TC_478_0.port_b.T; TC_477_0.port_b.Q_flow + FixedTemp477.port.Q_flow = 0.0; FixedTemp477.port.T = TC_477_0.port_b.T; TC_476_0.port_b.Q_flow + FixedTemp476.port.Q_flow = 0.0; FixedTemp476.port.T = TC_476_0.port_b.T; TC_475_0.port_b.Q_flow + FixedTemp475.port.Q_flow = 0.0; FixedTemp475.port.T = TC_475_0.port_b.T; TC_474_0.port_b.Q_flow + FixedTemp474.port.Q_flow = 0.0; FixedTemp474.port.T = TC_474_0.port_b.T; TC_473_0.port_b.Q_flow + FixedTemp473.port.Q_flow = 0.0; FixedTemp473.port.T = TC_473_0.port_b.T; TC_472_0.port_b.Q_flow + FixedTemp472.port.Q_flow = 0.0; FixedTemp472.port.T = TC_472_0.port_b.T; TC_471_0.port_b.Q_flow + FixedTemp471.port.Q_flow = 0.0; FixedTemp471.port.T = TC_471_0.port_b.T; TC_470_0.port_b.Q_flow + FixedTemp470.port.Q_flow = 0.0; FixedTemp470.port.T = TC_470_0.port_b.T; TC_469_0.port_b.Q_flow + FixedTemp469.port.Q_flow = 0.0; FixedTemp469.port.T = TC_469_0.port_b.T; TC_468_0.port_b.Q_flow + FixedTemp468.port.Q_flow = 0.0; FixedTemp468.port.T = TC_468_0.port_b.T; TC_467_0.port_b.Q_flow + FixedTemp467.port.Q_flow = 0.0; FixedTemp467.port.T = TC_467_0.port_b.T; TC_466_0.port_b.Q_flow + FixedTemp466.port.Q_flow = 0.0; FixedTemp466.port.T = TC_466_0.port_b.T; TC_465_0.port_b.Q_flow + FixedTemp465.port.Q_flow = 0.0; FixedTemp465.port.T = TC_465_0.port_b.T; TC_464_0.port_b.Q_flow + FixedTemp464.port.Q_flow = 0.0; FixedTemp464.port.T = TC_464_0.port_b.T; TC_463_0.port_b.Q_flow + FixedTemp463.port.Q_flow = 0.0; FixedTemp463.port.T = TC_463_0.port_b.T; TC_462_0.port_b.Q_flow + FixedTemp462.port.Q_flow = 0.0; FixedTemp462.port.T = TC_462_0.port_b.T; TC_461_0.port_b.Q_flow + FixedTemp461.port.Q_flow = 0.0; FixedTemp461.port.T = TC_461_0.port_b.T; TC_460_0.port_b.Q_flow + FixedTemp460.port.Q_flow = 0.0; FixedTemp460.port.T = TC_460_0.port_b.T; TC_459_0.port_b.Q_flow + FixedTemp459.port.Q_flow = 0.0; FixedTemp459.port.T = TC_459_0.port_b.T; TC_458_0.port_b.Q_flow + FixedTemp458.port.Q_flow = 0.0; FixedTemp458.port.T = TC_458_0.port_b.T; TC_457_0.port_b.Q_flow + FixedTemp457.port.Q_flow = 0.0; FixedTemp457.port.T = TC_457_0.port_b.T; TC_456_0.port_b.Q_flow + FixedTemp456.port.Q_flow = 0.0; FixedTemp456.port.T = TC_456_0.port_b.T; TC_455_0.port_b.Q_flow + FixedTemp455.port.Q_flow = 0.0; FixedTemp455.port.T = TC_455_0.port_b.T; TC_454_0.port_b.Q_flow + FixedTemp454.port.Q_flow = 0.0; FixedTemp454.port.T = TC_454_0.port_b.T; TC_453_0.port_b.Q_flow + FixedTemp453.port.Q_flow = 0.0; FixedTemp453.port.T = TC_453_0.port_b.T; TC_452_0.port_b.Q_flow + FixedTemp452.port.Q_flow = 0.0; FixedTemp452.port.T = TC_452_0.port_b.T; TC_451_0.port_b.Q_flow + FixedTemp451.port.Q_flow = 0.0; FixedTemp451.port.T = TC_451_0.port_b.T; TC_450_0.port_b.Q_flow + FixedTemp450.port.Q_flow = 0.0; FixedTemp450.port.T = TC_450_0.port_b.T; TC_449_0.port_b.Q_flow + FixedTemp449.port.Q_flow = 0.0; FixedTemp449.port.T = TC_449_0.port_b.T; TC_448_0.port_b.Q_flow + FixedTemp448.port.Q_flow = 0.0; FixedTemp448.port.T = TC_448_0.port_b.T; TC_447_0.port_b.Q_flow + FixedTemp447.port.Q_flow = 0.0; FixedTemp447.port.T = TC_447_0.port_b.T; TC_446_0.port_b.Q_flow + FixedTemp446.port.Q_flow = 0.0; FixedTemp446.port.T = TC_446_0.port_b.T; TC_445_0.port_b.Q_flow + FixedTemp445.port.Q_flow = 0.0; FixedTemp445.port.T = TC_445_0.port_b.T; TC_444_0.port_b.Q_flow + FixedTemp444.port.Q_flow = 0.0; FixedTemp444.port.T = TC_444_0.port_b.T; TC_443_0.port_b.Q_flow + FixedTemp443.port.Q_flow = 0.0; FixedTemp443.port.T = TC_443_0.port_b.T; TC_442_0.port_b.Q_flow + FixedTemp442.port.Q_flow = 0.0; FixedTemp442.port.T = TC_442_0.port_b.T; TC_441_0.port_b.Q_flow + FixedTemp441.port.Q_flow = 0.0; FixedTemp441.port.T = TC_441_0.port_b.T; TC_440_0.port_b.Q_flow + FixedTemp440.port.Q_flow = 0.0; FixedTemp440.port.T = TC_440_0.port_b.T; TC_439_0.port_b.Q_flow + FixedTemp439.port.Q_flow = 0.0; FixedTemp439.port.T = TC_439_0.port_b.T; TC_438_0.port_b.Q_flow + FixedTemp438.port.Q_flow = 0.0; FixedTemp438.port.T = TC_438_0.port_b.T; TC_437_0.port_b.Q_flow + FixedTemp437.port.Q_flow = 0.0; FixedTemp437.port.T = TC_437_0.port_b.T; TC_436_0.port_b.Q_flow + FixedTemp436.port.Q_flow = 0.0; FixedTemp436.port.T = TC_436_0.port_b.T; TC_435_0.port_b.Q_flow + FixedTemp435.port.Q_flow = 0.0; FixedTemp435.port.T = TC_435_0.port_b.T; TC_434_0.port_b.Q_flow + FixedTemp434.port.Q_flow = 0.0; FixedTemp434.port.T = TC_434_0.port_b.T; TC_433_0.port_b.Q_flow + FixedTemp433.port.Q_flow = 0.0; FixedTemp433.port.T = TC_433_0.port_b.T; TC_432_0.port_b.Q_flow + FixedTemp432.port.Q_flow = 0.0; FixedTemp432.port.T = TC_432_0.port_b.T; TC_431_0.port_b.Q_flow + FixedTemp431.port.Q_flow = 0.0; FixedTemp431.port.T = TC_431_0.port_b.T; TC_430_0.port_b.Q_flow + FixedTemp430.port.Q_flow = 0.0; FixedTemp430.port.T = TC_430_0.port_b.T; TC_429_0.port_b.Q_flow + FixedTemp429.port.Q_flow = 0.0; FixedTemp429.port.T = TC_429_0.port_b.T; TC_428_0.port_b.Q_flow + FixedTemp428.port.Q_flow = 0.0; FixedTemp428.port.T = TC_428_0.port_b.T; TC_427_0.port_b.Q_flow + FixedTemp427.port.Q_flow = 0.0; FixedTemp427.port.T = TC_427_0.port_b.T; TC_426_0.port_b.Q_flow + FixedTemp426.port.Q_flow = 0.0; FixedTemp426.port.T = TC_426_0.port_b.T; TC_425_0.port_b.Q_flow + FixedTemp425.port.Q_flow = 0.0; FixedTemp425.port.T = TC_425_0.port_b.T; TC_424_0.port_b.Q_flow + FixedTemp424.port.Q_flow = 0.0; FixedTemp424.port.T = TC_424_0.port_b.T; TC_423_0.port_b.Q_flow + FixedTemp423.port.Q_flow = 0.0; FixedTemp423.port.T = TC_423_0.port_b.T; TC_422_0.port_b.Q_flow + FixedTemp422.port.Q_flow = 0.0; FixedTemp422.port.T = TC_422_0.port_b.T; TC_421_0.port_b.Q_flow + FixedTemp421.port.Q_flow = 0.0; FixedTemp421.port.T = TC_421_0.port_b.T; TC_420_0.port_b.Q_flow + FixedTemp420.port.Q_flow = 0.0; FixedTemp420.port.T = TC_420_0.port_b.T; TC_419_0.port_b.Q_flow + FixedTemp419.port.Q_flow = 0.0; FixedTemp419.port.T = TC_419_0.port_b.T; TC_418_0.port_b.Q_flow + FixedTemp418.port.Q_flow = 0.0; FixedTemp418.port.T = TC_418_0.port_b.T; TC_417_0.port_b.Q_flow + FixedTemp417.port.Q_flow = 0.0; FixedTemp417.port.T = TC_417_0.port_b.T; TC_416_0.port_b.Q_flow + FixedTemp416.port.Q_flow = 0.0; FixedTemp416.port.T = TC_416_0.port_b.T; TC_415_0.port_b.Q_flow + FixedTemp415.port.Q_flow = 0.0; FixedTemp415.port.T = TC_415_0.port_b.T; TC_414_0.port_b.Q_flow + FixedTemp414.port.Q_flow = 0.0; FixedTemp414.port.T = TC_414_0.port_b.T; TC_413_0.port_b.Q_flow + FixedTemp413.port.Q_flow = 0.0; FixedTemp413.port.T = TC_413_0.port_b.T; TC_412_0.port_b.Q_flow + FixedTemp412.port.Q_flow = 0.0; FixedTemp412.port.T = TC_412_0.port_b.T; TC_411_0.port_b.Q_flow + FixedTemp411.port.Q_flow = 0.0; FixedTemp411.port.T = TC_411_0.port_b.T; TC_410_0.port_b.Q_flow + FixedTemp410.port.Q_flow = 0.0; FixedTemp410.port.T = TC_410_0.port_b.T; TC_409_0.port_b.Q_flow + FixedTemp409.port.Q_flow = 0.0; FixedTemp409.port.T = TC_409_0.port_b.T; TC_408_0.port_b.Q_flow + FixedTemp408.port.Q_flow = 0.0; FixedTemp408.port.T = TC_408_0.port_b.T; TC_407_0.port_b.Q_flow + FixedTemp407.port.Q_flow = 0.0; FixedTemp407.port.T = TC_407_0.port_b.T; TC_406_0.port_b.Q_flow + FixedTemp406.port.Q_flow = 0.0; FixedTemp406.port.T = TC_406_0.port_b.T; TC_405_0.port_b.Q_flow + FixedTemp405.port.Q_flow = 0.0; FixedTemp405.port.T = TC_405_0.port_b.T; TC_404_0.port_b.Q_flow + FixedTemp404.port.Q_flow = 0.0; FixedTemp404.port.T = TC_404_0.port_b.T; TC_403_0.port_b.Q_flow + FixedTemp403.port.Q_flow = 0.0; FixedTemp403.port.T = TC_403_0.port_b.T; TC_402_0.port_b.Q_flow + FixedTemp402.port.Q_flow = 0.0; FixedTemp402.port.T = TC_402_0.port_b.T; TC_401_0.port_b.Q_flow + FixedTemp401.port.Q_flow = 0.0; FixedTemp401.port.T = TC_401_0.port_b.T; TC_400_0.port_b.Q_flow + FixedTemp400.port.Q_flow = 0.0; FixedTemp400.port.T = TC_400_0.port_b.T; TC_399_0.port_b.Q_flow + FixedTemp399.port.Q_flow = 0.0; FixedTemp399.port.T = TC_399_0.port_b.T; TC_398_0.port_b.Q_flow + FixedTemp398.port.Q_flow = 0.0; FixedTemp398.port.T = TC_398_0.port_b.T; TC_397_0.port_b.Q_flow + FixedTemp397.port.Q_flow = 0.0; FixedTemp397.port.T = TC_397_0.port_b.T; TC_396_0.port_b.Q_flow + FixedTemp396.port.Q_flow = 0.0; FixedTemp396.port.T = TC_396_0.port_b.T; TC_395_0.port_b.Q_flow + FixedTemp395.port.Q_flow = 0.0; FixedTemp395.port.T = TC_395_0.port_b.T; TC_394_0.port_b.Q_flow + FixedTemp394.port.Q_flow = 0.0; FixedTemp394.port.T = TC_394_0.port_b.T; TC_393_0.port_b.Q_flow + FixedTemp393.port.Q_flow = 0.0; FixedTemp393.port.T = TC_393_0.port_b.T; TC_392_0.port_b.Q_flow + FixedTemp392.port.Q_flow = 0.0; FixedTemp392.port.T = TC_392_0.port_b.T; TC_391_0.port_b.Q_flow + FixedTemp391.port.Q_flow = 0.0; FixedTemp391.port.T = TC_391_0.port_b.T; TC_390_0.port_b.Q_flow + FixedTemp390.port.Q_flow = 0.0; FixedTemp390.port.T = TC_390_0.port_b.T; TC_389_0.port_b.Q_flow + FixedTemp389.port.Q_flow = 0.0; FixedTemp389.port.T = TC_389_0.port_b.T; TC_388_0.port_b.Q_flow + FixedTemp388.port.Q_flow = 0.0; FixedTemp388.port.T = TC_388_0.port_b.T; TC_387_0.port_b.Q_flow + FixedTemp387.port.Q_flow = 0.0; FixedTemp387.port.T = TC_387_0.port_b.T; TC_386_0.port_b.Q_flow + FixedTemp386.port.Q_flow = 0.0; FixedTemp386.port.T = TC_386_0.port_b.T; TC_385_0.port_b.Q_flow + FixedTemp385.port.Q_flow = 0.0; FixedTemp385.port.T = TC_385_0.port_b.T; TC_384_0.port_b.Q_flow + FixedTemp384.port.Q_flow = 0.0; FixedTemp384.port.T = TC_384_0.port_b.T; TC_383_0.port_b.Q_flow + FixedTemp383.port.Q_flow = 0.0; FixedTemp383.port.T = TC_383_0.port_b.T; TC_382_0.port_b.Q_flow + FixedTemp382.port.Q_flow = 0.0; FixedTemp382.port.T = TC_382_0.port_b.T; TC_381_0.port_b.Q_flow + FixedTemp381.port.Q_flow = 0.0; FixedTemp381.port.T = TC_381_0.port_b.T; TC_380_0.port_b.Q_flow + FixedTemp380.port.Q_flow = 0.0; FixedTemp380.port.T = TC_380_0.port_b.T; TC_379_0.port_b.Q_flow + FixedTemp379.port.Q_flow = 0.0; FixedTemp379.port.T = TC_379_0.port_b.T; TC_378_0.port_b.Q_flow + FixedTemp378.port.Q_flow = 0.0; FixedTemp378.port.T = TC_378_0.port_b.T; TC_377_0.port_b.Q_flow + FixedTemp377.port.Q_flow = 0.0; FixedTemp377.port.T = TC_377_0.port_b.T; TC_376_0.port_b.Q_flow + FixedTemp376.port.Q_flow = 0.0; FixedTemp376.port.T = TC_376_0.port_b.T; TC_375_0.port_b.Q_flow + FixedTemp375.port.Q_flow = 0.0; FixedTemp375.port.T = TC_375_0.port_b.T; TC_374_0.port_b.Q_flow + FixedTemp374.port.Q_flow = 0.0; FixedTemp374.port.T = TC_374_0.port_b.T; TC_373_0.port_b.Q_flow + FixedTemp373.port.Q_flow = 0.0; FixedTemp373.port.T = TC_373_0.port_b.T; TC_372_0.port_b.Q_flow + FixedTemp372.port.Q_flow = 0.0; FixedTemp372.port.T = TC_372_0.port_b.T; TC_371_0.port_b.Q_flow + FixedTemp371.port.Q_flow = 0.0; FixedTemp371.port.T = TC_371_0.port_b.T; TC_370_0.port_b.Q_flow + FixedTemp370.port.Q_flow = 0.0; FixedTemp370.port.T = TC_370_0.port_b.T; TC_369_0.port_b.Q_flow + FixedTemp369.port.Q_flow = 0.0; FixedTemp369.port.T = TC_369_0.port_b.T; TC_368_0.port_b.Q_flow + FixedTemp368.port.Q_flow = 0.0; FixedTemp368.port.T = TC_368_0.port_b.T; TC_367_0.port_b.Q_flow + FixedTemp367.port.Q_flow = 0.0; FixedTemp367.port.T = TC_367_0.port_b.T; TC_366_0.port_b.Q_flow + FixedTemp366.port.Q_flow = 0.0; FixedTemp366.port.T = TC_366_0.port_b.T; TC_365_0.port_b.Q_flow + FixedTemp365.port.Q_flow = 0.0; FixedTemp365.port.T = TC_365_0.port_b.T; TC_364_0.port_b.Q_flow + FixedTemp364.port.Q_flow = 0.0; FixedTemp364.port.T = TC_364_0.port_b.T; TC_363_0.port_b.Q_flow + FixedTemp363.port.Q_flow = 0.0; FixedTemp363.port.T = TC_363_0.port_b.T; TC_362_0.port_b.Q_flow + FixedTemp362.port.Q_flow = 0.0; FixedTemp362.port.T = TC_362_0.port_b.T; TC_361_0.port_b.Q_flow + FixedTemp361.port.Q_flow = 0.0; FixedTemp361.port.T = TC_361_0.port_b.T; TC_360_0.port_b.Q_flow + FixedTemp360.port.Q_flow = 0.0; FixedTemp360.port.T = TC_360_0.port_b.T; TC_359_0.port_b.Q_flow + FixedTemp359.port.Q_flow = 0.0; FixedTemp359.port.T = TC_359_0.port_b.T; TC_358_0.port_b.Q_flow + FixedTemp358.port.Q_flow = 0.0; FixedTemp358.port.T = TC_358_0.port_b.T; TC_357_0.port_b.Q_flow + FixedTemp357.port.Q_flow = 0.0; FixedTemp357.port.T = TC_357_0.port_b.T; TC_356_0.port_b.Q_flow + FixedTemp356.port.Q_flow = 0.0; FixedTemp356.port.T = TC_356_0.port_b.T; TC_355_0.port_b.Q_flow + FixedTemp355.port.Q_flow = 0.0; FixedTemp355.port.T = TC_355_0.port_b.T; TC_354_0.port_b.Q_flow + FixedTemp354.port.Q_flow = 0.0; FixedTemp354.port.T = TC_354_0.port_b.T; TC_353_0.port_b.Q_flow + FixedTemp353.port.Q_flow = 0.0; FixedTemp353.port.T = TC_353_0.port_b.T; TC_352_0.port_b.Q_flow + FixedTemp352.port.Q_flow = 0.0; FixedTemp352.port.T = TC_352_0.port_b.T; TC_351_0.port_b.Q_flow + FixedTemp351.port.Q_flow = 0.0; FixedTemp351.port.T = TC_351_0.port_b.T; TC_350_0.port_b.Q_flow + FixedTemp350.port.Q_flow = 0.0; FixedTemp350.port.T = TC_350_0.port_b.T; TC_349_0.port_b.Q_flow + FixedTemp349.port.Q_flow = 0.0; FixedTemp349.port.T = TC_349_0.port_b.T; TC_348_0.port_b.Q_flow + FixedTemp348.port.Q_flow = 0.0; FixedTemp348.port.T = TC_348_0.port_b.T; TC_347_0.port_b.Q_flow + FixedTemp347.port.Q_flow = 0.0; FixedTemp347.port.T = TC_347_0.port_b.T; TC_346_0.port_b.Q_flow + FixedTemp346.port.Q_flow = 0.0; FixedTemp346.port.T = TC_346_0.port_b.T; TC_345_0.port_b.Q_flow + FixedTemp345.port.Q_flow = 0.0; FixedTemp345.port.T = TC_345_0.port_b.T; TC_344_0.port_b.Q_flow + FixedTemp344.port.Q_flow = 0.0; FixedTemp344.port.T = TC_344_0.port_b.T; TC_343_0.port_b.Q_flow + FixedTemp343.port.Q_flow = 0.0; FixedTemp343.port.T = TC_343_0.port_b.T; TC_342_0.port_b.Q_flow + FixedTemp342.port.Q_flow = 0.0; FixedTemp342.port.T = TC_342_0.port_b.T; TC_341_0.port_b.Q_flow + FixedTemp341.port.Q_flow = 0.0; FixedTemp341.port.T = TC_341_0.port_b.T; TC_340_0.port_b.Q_flow + FixedTemp340.port.Q_flow = 0.0; FixedTemp340.port.T = TC_340_0.port_b.T; TC_339_0.port_b.Q_flow + FixedTemp339.port.Q_flow = 0.0; FixedTemp339.port.T = TC_339_0.port_b.T; TC_338_0.port_b.Q_flow + FixedTemp338.port.Q_flow = 0.0; FixedTemp338.port.T = TC_338_0.port_b.T; TC_337_0.port_b.Q_flow + FixedTemp337.port.Q_flow = 0.0; FixedTemp337.port.T = TC_337_0.port_b.T; TC_336_0.port_b.Q_flow + FixedTemp336.port.Q_flow = 0.0; FixedTemp336.port.T = TC_336_0.port_b.T; TC_335_0.port_b.Q_flow + FixedTemp335.port.Q_flow = 0.0; FixedTemp335.port.T = TC_335_0.port_b.T; TC_334_0.port_b.Q_flow + FixedTemp334.port.Q_flow = 0.0; FixedTemp334.port.T = TC_334_0.port_b.T; TC_333_0.port_b.Q_flow + FixedTemp333.port.Q_flow = 0.0; FixedTemp333.port.T = TC_333_0.port_b.T; TC_332_0.port_b.Q_flow + FixedTemp332.port.Q_flow = 0.0; FixedTemp332.port.T = TC_332_0.port_b.T; TC_331_0.port_b.Q_flow + FixedTemp331.port.Q_flow = 0.0; FixedTemp331.port.T = TC_331_0.port_b.T; TC_330_0.port_b.Q_flow + FixedTemp330.port.Q_flow = 0.0; FixedTemp330.port.T = TC_330_0.port_b.T; TC_329_0.port_b.Q_flow + FixedTemp329.port.Q_flow = 0.0; FixedTemp329.port.T = TC_329_0.port_b.T; TC_328_0.port_b.Q_flow + FixedTemp328.port.Q_flow = 0.0; FixedTemp328.port.T = TC_328_0.port_b.T; TC_327_0.port_b.Q_flow + FixedTemp327.port.Q_flow = 0.0; FixedTemp327.port.T = TC_327_0.port_b.T; TC_326_0.port_b.Q_flow + FixedTemp326.port.Q_flow = 0.0; FixedTemp326.port.T = TC_326_0.port_b.T; TC_325_0.port_b.Q_flow + FixedTemp325.port.Q_flow = 0.0; FixedTemp325.port.T = TC_325_0.port_b.T; TC_324_0.port_b.Q_flow + FixedTemp324.port.Q_flow = 0.0; FixedTemp324.port.T = TC_324_0.port_b.T; TC_323_0.port_b.Q_flow + FixedTemp323.port.Q_flow = 0.0; FixedTemp323.port.T = TC_323_0.port_b.T; TC_322_0.port_b.Q_flow + FixedTemp322.port.Q_flow = 0.0; FixedTemp322.port.T = TC_322_0.port_b.T; TC_321_0.port_b.Q_flow + FixedTemp321.port.Q_flow = 0.0; FixedTemp321.port.T = TC_321_0.port_b.T; TC_320_0.port_b.Q_flow + FixedTemp320.port.Q_flow = 0.0; FixedTemp320.port.T = TC_320_0.port_b.T; TC_319_0.port_b.Q_flow + FixedTemp319.port.Q_flow = 0.0; FixedTemp319.port.T = TC_319_0.port_b.T; TC_318_0.port_b.Q_flow + FixedTemp318.port.Q_flow = 0.0; FixedTemp318.port.T = TC_318_0.port_b.T; TC_317_0.port_b.Q_flow + FixedTemp317.port.Q_flow = 0.0; FixedTemp317.port.T = TC_317_0.port_b.T; TC_316_0.port_b.Q_flow + FixedTemp316.port.Q_flow = 0.0; FixedTemp316.port.T = TC_316_0.port_b.T; TC_315_0.port_b.Q_flow + FixedTemp315.port.Q_flow = 0.0; FixedTemp315.port.T = TC_315_0.port_b.T; TC_314_0.port_b.Q_flow + FixedTemp314.port.Q_flow = 0.0; FixedTemp314.port.T = TC_314_0.port_b.T; TC_313_0.port_b.Q_flow + FixedTemp313.port.Q_flow = 0.0; FixedTemp313.port.T = TC_313_0.port_b.T; TC_312_0.port_b.Q_flow + FixedTemp312.port.Q_flow = 0.0; FixedTemp312.port.T = TC_312_0.port_b.T; TC_311_0.port_b.Q_flow + FixedTemp311.port.Q_flow = 0.0; FixedTemp311.port.T = TC_311_0.port_b.T; TC_310_0.port_b.Q_flow + FixedTemp310.port.Q_flow = 0.0; FixedTemp310.port.T = TC_310_0.port_b.T; TC_309_0.port_b.Q_flow + FixedTemp309.port.Q_flow = 0.0; FixedTemp309.port.T = TC_309_0.port_b.T; TC_308_0.port_b.Q_flow + FixedTemp308.port.Q_flow = 0.0; FixedTemp308.port.T = TC_308_0.port_b.T; TC_307_0.port_b.Q_flow + FixedTemp307.port.Q_flow = 0.0; FixedTemp307.port.T = TC_307_0.port_b.T; TC_306_0.port_b.Q_flow + FixedTemp306.port.Q_flow = 0.0; FixedTemp306.port.T = TC_306_0.port_b.T; TC_305_0.port_b.Q_flow + FixedTemp305.port.Q_flow = 0.0; FixedTemp305.port.T = TC_305_0.port_b.T; TC_304_0.port_b.Q_flow + FixedTemp304.port.Q_flow = 0.0; FixedTemp304.port.T = TC_304_0.port_b.T; TC_303_0.port_b.Q_flow + FixedTemp303.port.Q_flow = 0.0; FixedTemp303.port.T = TC_303_0.port_b.T; TC_302_0.port_b.Q_flow + FixedTemp302.port.Q_flow = 0.0; FixedTemp302.port.T = TC_302_0.port_b.T; TC_301_0.port_b.Q_flow + FixedTemp301.port.Q_flow = 0.0; FixedTemp301.port.T = TC_301_0.port_b.T; TC_300_0.port_b.Q_flow + FixedTemp300.port.Q_flow = 0.0; FixedTemp300.port.T = TC_300_0.port_b.T; TC_299_0.port_b.Q_flow + FixedTemp299.port.Q_flow = 0.0; FixedTemp299.port.T = TC_299_0.port_b.T; TC_298_0.port_b.Q_flow + FixedTemp298.port.Q_flow = 0.0; FixedTemp298.port.T = TC_298_0.port_b.T; TC_297_0.port_b.Q_flow + FixedTemp297.port.Q_flow = 0.0; FixedTemp297.port.T = TC_297_0.port_b.T; TC_296_0.port_b.Q_flow + FixedTemp296.port.Q_flow = 0.0; FixedTemp296.port.T = TC_296_0.port_b.T; TC_295_0.port_b.Q_flow + FixedTemp295.port.Q_flow = 0.0; FixedTemp295.port.T = TC_295_0.port_b.T; TC_294_0.port_b.Q_flow + FixedTemp294.port.Q_flow = 0.0; FixedTemp294.port.T = TC_294_0.port_b.T; TC_293_0.port_b.Q_flow + FixedTemp293.port.Q_flow = 0.0; FixedTemp293.port.T = TC_293_0.port_b.T; TC_292_0.port_b.Q_flow + FixedTemp292.port.Q_flow = 0.0; FixedTemp292.port.T = TC_292_0.port_b.T; TC_291_0.port_b.Q_flow + FixedTemp291.port.Q_flow = 0.0; FixedTemp291.port.T = TC_291_0.port_b.T; TC_290_0.port_b.Q_flow + FixedTemp290.port.Q_flow = 0.0; FixedTemp290.port.T = TC_290_0.port_b.T; TC_289_0.port_b.Q_flow + FixedTemp289.port.Q_flow = 0.0; FixedTemp289.port.T = TC_289_0.port_b.T; TC_288_0.port_b.Q_flow + FixedTemp288.port.Q_flow = 0.0; FixedTemp288.port.T = TC_288_0.port_b.T; TC_287_0.port_b.Q_flow + FixedTemp287.port.Q_flow = 0.0; FixedTemp287.port.T = TC_287_0.port_b.T; TC_286_0.port_b.Q_flow + FixedTemp286.port.Q_flow = 0.0; FixedTemp286.port.T = TC_286_0.port_b.T; TC_285_0.port_b.Q_flow + FixedTemp285.port.Q_flow = 0.0; FixedTemp285.port.T = TC_285_0.port_b.T; TC_284_0.port_b.Q_flow + FixedTemp284.port.Q_flow = 0.0; FixedTemp284.port.T = TC_284_0.port_b.T; TC_283_0.port_b.Q_flow + FixedTemp283.port.Q_flow = 0.0; FixedTemp283.port.T = TC_283_0.port_b.T; TC_282_0.port_b.Q_flow + FixedTemp282.port.Q_flow = 0.0; FixedTemp282.port.T = TC_282_0.port_b.T; TC_281_0.port_b.Q_flow + FixedTemp281.port.Q_flow = 0.0; FixedTemp281.port.T = TC_281_0.port_b.T; TC_280_0.port_b.Q_flow + FixedTemp280.port.Q_flow = 0.0; FixedTemp280.port.T = TC_280_0.port_b.T; TC_279_0.port_b.Q_flow + FixedTemp279.port.Q_flow = 0.0; FixedTemp279.port.T = TC_279_0.port_b.T; TC_278_0.port_b.Q_flow + FixedTemp278.port.Q_flow = 0.0; FixedTemp278.port.T = TC_278_0.port_b.T; TC_277_0.port_b.Q_flow + FixedTemp277.port.Q_flow = 0.0; FixedTemp277.port.T = TC_277_0.port_b.T; TC_276_0.port_b.Q_flow + FixedTemp276.port.Q_flow = 0.0; FixedTemp276.port.T = TC_276_0.port_b.T; TC_275_0.port_b.Q_flow + FixedTemp275.port.Q_flow = 0.0; FixedTemp275.port.T = TC_275_0.port_b.T; TC_274_0.port_b.Q_flow + FixedTemp274.port.Q_flow = 0.0; FixedTemp274.port.T = TC_274_0.port_b.T; TC_273_0.port_b.Q_flow + FixedTemp273.port.Q_flow = 0.0; FixedTemp273.port.T = TC_273_0.port_b.T; TC_272_0.port_b.Q_flow + FixedTemp272.port.Q_flow = 0.0; FixedTemp272.port.T = TC_272_0.port_b.T; TC_271_0.port_b.Q_flow + FixedTemp271.port.Q_flow = 0.0; FixedTemp271.port.T = TC_271_0.port_b.T; TC_270_0.port_b.Q_flow + FixedTemp270.port.Q_flow = 0.0; FixedTemp270.port.T = TC_270_0.port_b.T; TC_269_0.port_b.Q_flow + FixedTemp269.port.Q_flow = 0.0; FixedTemp269.port.T = TC_269_0.port_b.T; TC_268_0.port_b.Q_flow + FixedTemp268.port.Q_flow = 0.0; FixedTemp268.port.T = TC_268_0.port_b.T; TC_267_0.port_b.Q_flow + FixedTemp267.port.Q_flow = 0.0; FixedTemp267.port.T = TC_267_0.port_b.T; TC_266_0.port_b.Q_flow + FixedTemp266.port.Q_flow = 0.0; FixedTemp266.port.T = TC_266_0.port_b.T; TC_265_0.port_b.Q_flow + FixedTemp265.port.Q_flow = 0.0; FixedTemp265.port.T = TC_265_0.port_b.T; TC_264_0.port_b.Q_flow + FixedTemp264.port.Q_flow = 0.0; FixedTemp264.port.T = TC_264_0.port_b.T; TC_263_0.port_b.Q_flow + FixedTemp263.port.Q_flow = 0.0; FixedTemp263.port.T = TC_263_0.port_b.T; TC_262_0.port_b.Q_flow + FixedTemp262.port.Q_flow = 0.0; FixedTemp262.port.T = TC_262_0.port_b.T; TC_261_0.port_b.Q_flow + FixedTemp261.port.Q_flow = 0.0; FixedTemp261.port.T = TC_261_0.port_b.T; TC_260_0.port_b.Q_flow + FixedTemp260.port.Q_flow = 0.0; FixedTemp260.port.T = TC_260_0.port_b.T; TC_259_0.port_b.Q_flow + FixedTemp259.port.Q_flow = 0.0; FixedTemp259.port.T = TC_259_0.port_b.T; TC_258_0.port_b.Q_flow + FixedTemp258.port.Q_flow = 0.0; FixedTemp258.port.T = TC_258_0.port_b.T; TC_257_0.port_b.Q_flow + FixedTemp257.port.Q_flow = 0.0; FixedTemp257.port.T = TC_257_0.port_b.T; TC_256_0.port_b.Q_flow + FixedTemp256.port.Q_flow = 0.0; FixedTemp256.port.T = TC_256_0.port_b.T; TC_255_0.port_b.Q_flow + FixedTemp255.port.Q_flow = 0.0; FixedTemp255.port.T = TC_255_0.port_b.T; TC_254_0.port_b.Q_flow + FixedTemp254.port.Q_flow = 0.0; FixedTemp254.port.T = TC_254_0.port_b.T; TC_253_0.port_b.Q_flow + FixedTemp253.port.Q_flow = 0.0; FixedTemp253.port.T = TC_253_0.port_b.T; TC_252_0.port_b.Q_flow + FixedTemp252.port.Q_flow = 0.0; FixedTemp252.port.T = TC_252_0.port_b.T; TC_251_0.port_b.Q_flow + FixedTemp251.port.Q_flow = 0.0; FixedTemp251.port.T = TC_251_0.port_b.T; TC_250_0.port_b.Q_flow + FixedTemp250.port.Q_flow = 0.0; FixedTemp250.port.T = TC_250_0.port_b.T; TC_249_0.port_b.Q_flow + FixedTemp249.port.Q_flow = 0.0; FixedTemp249.port.T = TC_249_0.port_b.T; TC_248_0.port_b.Q_flow + FixedTemp248.port.Q_flow = 0.0; FixedTemp248.port.T = TC_248_0.port_b.T; TC_247_0.port_b.Q_flow + FixedTemp247.port.Q_flow = 0.0; FixedTemp247.port.T = TC_247_0.port_b.T; TC_246_0.port_b.Q_flow + FixedTemp246.port.Q_flow = 0.0; FixedTemp246.port.T = TC_246_0.port_b.T; TC_245_0.port_b.Q_flow + FixedTemp245.port.Q_flow = 0.0; FixedTemp245.port.T = TC_245_0.port_b.T; TC_244_0.port_b.Q_flow + FixedTemp244.port.Q_flow = 0.0; FixedTemp244.port.T = TC_244_0.port_b.T; TC_243_0.port_b.Q_flow + FixedTemp243.port.Q_flow = 0.0; FixedTemp243.port.T = TC_243_0.port_b.T; TC_242_0.port_b.Q_flow + FixedTemp242.port.Q_flow = 0.0; FixedTemp242.port.T = TC_242_0.port_b.T; TC_241_0.port_b.Q_flow + FixedTemp241.port.Q_flow = 0.0; FixedTemp241.port.T = TC_241_0.port_b.T; TC_240_0.port_b.Q_flow + FixedTemp240.port.Q_flow = 0.0; FixedTemp240.port.T = TC_240_0.port_b.T; TC_239_0.port_b.Q_flow + FixedTemp239.port.Q_flow = 0.0; FixedTemp239.port.T = TC_239_0.port_b.T; TC_238_0.port_b.Q_flow + FixedTemp238.port.Q_flow = 0.0; FixedTemp238.port.T = TC_238_0.port_b.T; TC_237_0.port_b.Q_flow + FixedTemp237.port.Q_flow = 0.0; FixedTemp237.port.T = TC_237_0.port_b.T; TC_236_0.port_b.Q_flow + FixedTemp236.port.Q_flow = 0.0; FixedTemp236.port.T = TC_236_0.port_b.T; TC_235_0.port_b.Q_flow + FixedTemp235.port.Q_flow = 0.0; FixedTemp235.port.T = TC_235_0.port_b.T; TC_234_0.port_b.Q_flow + FixedTemp234.port.Q_flow = 0.0; FixedTemp234.port.T = TC_234_0.port_b.T; TC_233_0.port_b.Q_flow + FixedTemp233.port.Q_flow = 0.0; FixedTemp233.port.T = TC_233_0.port_b.T; TC_232_0.port_b.Q_flow + FixedTemp232.port.Q_flow = 0.0; FixedTemp232.port.T = TC_232_0.port_b.T; TC_231_0.port_b.Q_flow + FixedTemp231.port.Q_flow = 0.0; FixedTemp231.port.T = TC_231_0.port_b.T; TC_230_0.port_b.Q_flow + FixedTemp230.port.Q_flow = 0.0; FixedTemp230.port.T = TC_230_0.port_b.T; TC_229_0.port_b.Q_flow + FixedTemp229.port.Q_flow = 0.0; FixedTemp229.port.T = TC_229_0.port_b.T; TC_228_0.port_b.Q_flow + FixedTemp228.port.Q_flow = 0.0; FixedTemp228.port.T = TC_228_0.port_b.T; TC_227_0.port_b.Q_flow + FixedTemp227.port.Q_flow = 0.0; FixedTemp227.port.T = TC_227_0.port_b.T; TC_226_0.port_b.Q_flow + FixedTemp226.port.Q_flow = 0.0; FixedTemp226.port.T = TC_226_0.port_b.T; TC_225_0.port_b.Q_flow + FixedTemp225.port.Q_flow = 0.0; FixedTemp225.port.T = TC_225_0.port_b.T; TC_224_0.port_b.Q_flow + FixedTemp224.port.Q_flow = 0.0; FixedTemp224.port.T = TC_224_0.port_b.T; TC_223_0.port_b.Q_flow + FixedTemp223.port.Q_flow = 0.0; FixedTemp223.port.T = TC_223_0.port_b.T; TC_222_0.port_b.Q_flow + FixedTemp222.port.Q_flow = 0.0; FixedTemp222.port.T = TC_222_0.port_b.T; TC_221_0.port_b.Q_flow + FixedTemp221.port.Q_flow = 0.0; FixedTemp221.port.T = TC_221_0.port_b.T; TC_220_0.port_b.Q_flow + FixedTemp220.port.Q_flow = 0.0; FixedTemp220.port.T = TC_220_0.port_b.T; TC_219_0.port_b.Q_flow + FixedTemp219.port.Q_flow = 0.0; FixedTemp219.port.T = TC_219_0.port_b.T; TC_218_0.port_b.Q_flow + FixedTemp218.port.Q_flow = 0.0; FixedTemp218.port.T = TC_218_0.port_b.T; TC_217_0.port_b.Q_flow + FixedTemp217.port.Q_flow = 0.0; FixedTemp217.port.T = TC_217_0.port_b.T; TC_216_0.port_b.Q_flow + FixedTemp216.port.Q_flow = 0.0; FixedTemp216.port.T = TC_216_0.port_b.T; TC_215_0.port_b.Q_flow + FixedTemp215.port.Q_flow = 0.0; FixedTemp215.port.T = TC_215_0.port_b.T; TC_214_0.port_b.Q_flow + FixedTemp214.port.Q_flow = 0.0; FixedTemp214.port.T = TC_214_0.port_b.T; TC_213_0.port_b.Q_flow + FixedTemp213.port.Q_flow = 0.0; FixedTemp213.port.T = TC_213_0.port_b.T; TC_212_0.port_b.Q_flow + FixedTemp212.port.Q_flow = 0.0; FixedTemp212.port.T = TC_212_0.port_b.T; TC_211_0.port_b.Q_flow + FixedTemp211.port.Q_flow = 0.0; FixedTemp211.port.T = TC_211_0.port_b.T; TC_210_0.port_b.Q_flow + FixedTemp210.port.Q_flow = 0.0; FixedTemp210.port.T = TC_210_0.port_b.T; TC_209_0.port_b.Q_flow + FixedTemp209.port.Q_flow = 0.0; FixedTemp209.port.T = TC_209_0.port_b.T; TC_208_0.port_b.Q_flow + FixedTemp208.port.Q_flow = 0.0; FixedTemp208.port.T = TC_208_0.port_b.T; TC_207_0.port_b.Q_flow + FixedTemp207.port.Q_flow = 0.0; FixedTemp207.port.T = TC_207_0.port_b.T; TC_206_0.port_b.Q_flow + FixedTemp206.port.Q_flow = 0.0; FixedTemp206.port.T = TC_206_0.port_b.T; TC_205_0.port_b.Q_flow + FixedTemp205.port.Q_flow = 0.0; FixedTemp205.port.T = TC_205_0.port_b.T; TC_204_0.port_b.Q_flow + FixedTemp204.port.Q_flow = 0.0; FixedTemp204.port.T = TC_204_0.port_b.T; TC_203_0.port_b.Q_flow + FixedTemp203.port.Q_flow = 0.0; FixedTemp203.port.T = TC_203_0.port_b.T; TC_202_0.port_b.Q_flow + FixedTemp202.port.Q_flow = 0.0; FixedTemp202.port.T = TC_202_0.port_b.T; TC_201_0.port_b.Q_flow + FixedTemp201.port.Q_flow = 0.0; FixedTemp201.port.T = TC_201_0.port_b.T; TC_200_0.port_b.Q_flow + FixedTemp200.port.Q_flow = 0.0; FixedTemp200.port.T = TC_200_0.port_b.T; TC_199_0.port_b.Q_flow + FixedTemp199.port.Q_flow = 0.0; FixedTemp199.port.T = TC_199_0.port_b.T; TC_198_0.port_b.Q_flow + FixedTemp198.port.Q_flow = 0.0; FixedTemp198.port.T = TC_198_0.port_b.T; TC_197_0.port_b.Q_flow + FixedTemp197.port.Q_flow = 0.0; FixedTemp197.port.T = TC_197_0.port_b.T; TC_196_0.port_b.Q_flow + FixedTemp196.port.Q_flow = 0.0; FixedTemp196.port.T = TC_196_0.port_b.T; TC_195_0.port_b.Q_flow + FixedTemp195.port.Q_flow = 0.0; FixedTemp195.port.T = TC_195_0.port_b.T; TC_194_0.port_b.Q_flow + FixedTemp194.port.Q_flow = 0.0; FixedTemp194.port.T = TC_194_0.port_b.T; TC_193_0.port_b.Q_flow + FixedTemp193.port.Q_flow = 0.0; FixedTemp193.port.T = TC_193_0.port_b.T; TC_192_0.port_b.Q_flow + FixedTemp192.port.Q_flow = 0.0; FixedTemp192.port.T = TC_192_0.port_b.T; TC_191_0.port_b.Q_flow + FixedTemp191.port.Q_flow = 0.0; FixedTemp191.port.T = TC_191_0.port_b.T; TC_190_0.port_b.Q_flow + FixedTemp190.port.Q_flow = 0.0; FixedTemp190.port.T = TC_190_0.port_b.T; TC_189_0.port_b.Q_flow + FixedTemp189.port.Q_flow = 0.0; FixedTemp189.port.T = TC_189_0.port_b.T; TC_188_0.port_b.Q_flow + FixedTemp188.port.Q_flow = 0.0; FixedTemp188.port.T = TC_188_0.port_b.T; TC_187_0.port_b.Q_flow + FixedTemp187.port.Q_flow = 0.0; FixedTemp187.port.T = TC_187_0.port_b.T; TC_186_0.port_b.Q_flow + FixedTemp186.port.Q_flow = 0.0; FixedTemp186.port.T = TC_186_0.port_b.T; TC_185_0.port_b.Q_flow + FixedTemp185.port.Q_flow = 0.0; FixedTemp185.port.T = TC_185_0.port_b.T; TC_184_0.port_b.Q_flow + FixedTemp184.port.Q_flow = 0.0; FixedTemp184.port.T = TC_184_0.port_b.T; TC_183_0.port_b.Q_flow + FixedTemp183.port.Q_flow = 0.0; FixedTemp183.port.T = TC_183_0.port_b.T; TC_182_0.port_b.Q_flow + FixedTemp182.port.Q_flow = 0.0; FixedTemp182.port.T = TC_182_0.port_b.T; TC_181_0.port_b.Q_flow + FixedTemp181.port.Q_flow = 0.0; FixedTemp181.port.T = TC_181_0.port_b.T; TC_180_0.port_b.Q_flow + FixedTemp180.port.Q_flow = 0.0; FixedTemp180.port.T = TC_180_0.port_b.T; TC_179_0.port_b.Q_flow + FixedTemp179.port.Q_flow = 0.0; FixedTemp179.port.T = TC_179_0.port_b.T; TC_178_0.port_b.Q_flow + FixedTemp178.port.Q_flow = 0.0; FixedTemp178.port.T = TC_178_0.port_b.T; TC_177_0.port_b.Q_flow + FixedTemp177.port.Q_flow = 0.0; FixedTemp177.port.T = TC_177_0.port_b.T; TC_176_0.port_b.Q_flow + FixedTemp176.port.Q_flow = 0.0; FixedTemp176.port.T = TC_176_0.port_b.T; TC_175_0.port_b.Q_flow + FixedTemp175.port.Q_flow = 0.0; FixedTemp175.port.T = TC_175_0.port_b.T; TC_174_0.port_b.Q_flow + FixedTemp174.port.Q_flow = 0.0; FixedTemp174.port.T = TC_174_0.port_b.T; TC_173_0.port_b.Q_flow + FixedTemp173.port.Q_flow = 0.0; FixedTemp173.port.T = TC_173_0.port_b.T; TC_172_0.port_b.Q_flow + FixedTemp172.port.Q_flow = 0.0; FixedTemp172.port.T = TC_172_0.port_b.T; TC_171_0.port_b.Q_flow + FixedTemp171.port.Q_flow = 0.0; FixedTemp171.port.T = TC_171_0.port_b.T; TC_170_0.port_b.Q_flow + FixedTemp170.port.Q_flow = 0.0; FixedTemp170.port.T = TC_170_0.port_b.T; TC_169_0.port_b.Q_flow + FixedTemp169.port.Q_flow = 0.0; FixedTemp169.port.T = TC_169_0.port_b.T; TC_168_0.port_b.Q_flow + FixedTemp168.port.Q_flow = 0.0; FixedTemp168.port.T = TC_168_0.port_b.T; TC_167_0.port_b.Q_flow + FixedTemp167.port.Q_flow = 0.0; FixedTemp167.port.T = TC_167_0.port_b.T; TC_166_0.port_b.Q_flow + FixedTemp166.port.Q_flow = 0.0; FixedTemp166.port.T = TC_166_0.port_b.T; TC_165_0.port_b.Q_flow + FixedTemp165.port.Q_flow = 0.0; FixedTemp165.port.T = TC_165_0.port_b.T; TC_164_0.port_b.Q_flow + FixedTemp164.port.Q_flow = 0.0; FixedTemp164.port.T = TC_164_0.port_b.T; TC_163_0.port_b.Q_flow + FixedTemp163.port.Q_flow = 0.0; FixedTemp163.port.T = TC_163_0.port_b.T; TC_162_0.port_b.Q_flow + FixedTemp162.port.Q_flow = 0.0; FixedTemp162.port.T = TC_162_0.port_b.T; TC_161_0.port_b.Q_flow + FixedTemp161.port.Q_flow = 0.0; FixedTemp161.port.T = TC_161_0.port_b.T; TC_160_0.port_b.Q_flow + FixedTemp160.port.Q_flow = 0.0; FixedTemp160.port.T = TC_160_0.port_b.T; TC_159_0.port_b.Q_flow + FixedTemp159.port.Q_flow = 0.0; FixedTemp159.port.T = TC_159_0.port_b.T; TC_158_0.port_b.Q_flow + FixedTemp158.port.Q_flow = 0.0; FixedTemp158.port.T = TC_158_0.port_b.T; TC_157_0.port_b.Q_flow + FixedTemp157.port.Q_flow = 0.0; FixedTemp157.port.T = TC_157_0.port_b.T; TC_156_0.port_b.Q_flow + FixedTemp156.port.Q_flow = 0.0; FixedTemp156.port.T = TC_156_0.port_b.T; TC_155_0.port_b.Q_flow + FixedTemp155.port.Q_flow = 0.0; FixedTemp155.port.T = TC_155_0.port_b.T; TC_154_0.port_b.Q_flow + FixedTemp154.port.Q_flow = 0.0; FixedTemp154.port.T = TC_154_0.port_b.T; TC_153_0.port_b.Q_flow + FixedTemp153.port.Q_flow = 0.0; FixedTemp153.port.T = TC_153_0.port_b.T; TC_152_0.port_b.Q_flow + FixedTemp152.port.Q_flow = 0.0; FixedTemp152.port.T = TC_152_0.port_b.T; TC_151_0.port_b.Q_flow + FixedTemp151.port.Q_flow = 0.0; FixedTemp151.port.T = TC_151_0.port_b.T; TC_150_0.port_b.Q_flow + FixedTemp150.port.Q_flow = 0.0; FixedTemp150.port.T = TC_150_0.port_b.T; TC_149_0.port_b.Q_flow + FixedTemp149.port.Q_flow = 0.0; FixedTemp149.port.T = TC_149_0.port_b.T; TC_148_0.port_b.Q_flow + FixedTemp148.port.Q_flow = 0.0; FixedTemp148.port.T = TC_148_0.port_b.T; TC_147_0.port_b.Q_flow + FixedTemp147.port.Q_flow = 0.0; FixedTemp147.port.T = TC_147_0.port_b.T; TC_146_0.port_b.Q_flow + FixedTemp146.port.Q_flow = 0.0; FixedTemp146.port.T = TC_146_0.port_b.T; TC_145_0.port_b.Q_flow + FixedTemp145.port.Q_flow = 0.0; FixedTemp145.port.T = TC_145_0.port_b.T; TC_144_0.port_b.Q_flow + FixedTemp144.port.Q_flow = 0.0; FixedTemp144.port.T = TC_144_0.port_b.T; TC_143_0.port_b.Q_flow + FixedTemp143.port.Q_flow = 0.0; FixedTemp143.port.T = TC_143_0.port_b.T; TC_142_0.port_b.Q_flow + FixedTemp142.port.Q_flow = 0.0; FixedTemp142.port.T = TC_142_0.port_b.T; TC_141_0.port_b.Q_flow + FixedTemp141.port.Q_flow = 0.0; FixedTemp141.port.T = TC_141_0.port_b.T; TC_140_0.port_b.Q_flow + FixedTemp140.port.Q_flow = 0.0; FixedTemp140.port.T = TC_140_0.port_b.T; TC_139_0.port_b.Q_flow + FixedTemp139.port.Q_flow = 0.0; FixedTemp139.port.T = TC_139_0.port_b.T; TC_138_0.port_b.Q_flow + FixedTemp138.port.Q_flow = 0.0; FixedTemp138.port.T = TC_138_0.port_b.T; TC_137_0.port_b.Q_flow + FixedTemp137.port.Q_flow = 0.0; FixedTemp137.port.T = TC_137_0.port_b.T; TC_136_0.port_b.Q_flow + FixedTemp136.port.Q_flow = 0.0; FixedTemp136.port.T = TC_136_0.port_b.T; TC_135_0.port_b.Q_flow + FixedTemp135.port.Q_flow = 0.0; FixedTemp135.port.T = TC_135_0.port_b.T; TC_134_0.port_b.Q_flow + FixedTemp134.port.Q_flow = 0.0; FixedTemp134.port.T = TC_134_0.port_b.T; TC_133_0.port_b.Q_flow + FixedTemp133.port.Q_flow = 0.0; FixedTemp133.port.T = TC_133_0.port_b.T; TC_132_0.port_b.Q_flow + FixedTemp132.port.Q_flow = 0.0; FixedTemp132.port.T = TC_132_0.port_b.T; TC_131_0.port_b.Q_flow + FixedTemp131.port.Q_flow = 0.0; FixedTemp131.port.T = TC_131_0.port_b.T; TC_130_0.port_b.Q_flow + FixedTemp130.port.Q_flow = 0.0; FixedTemp130.port.T = TC_130_0.port_b.T; TC_129_0.port_b.Q_flow + FixedTemp129.port.Q_flow = 0.0; FixedTemp129.port.T = TC_129_0.port_b.T; TC_128_0.port_b.Q_flow + FixedTemp128.port.Q_flow = 0.0; FixedTemp128.port.T = TC_128_0.port_b.T; TC_127_0.port_b.Q_flow + FixedTemp127.port.Q_flow = 0.0; FixedTemp127.port.T = TC_127_0.port_b.T; TC_126_0.port_b.Q_flow + FixedTemp126.port.Q_flow = 0.0; FixedTemp126.port.T = TC_126_0.port_b.T; TC_125_0.port_b.Q_flow + FixedTemp125.port.Q_flow = 0.0; FixedTemp125.port.T = TC_125_0.port_b.T; TC_124_0.port_b.Q_flow + FixedTemp124.port.Q_flow = 0.0; FixedTemp124.port.T = TC_124_0.port_b.T; TC_123_0.port_b.Q_flow + FixedTemp123.port.Q_flow = 0.0; FixedTemp123.port.T = TC_123_0.port_b.T; TC_122_0.port_b.Q_flow + FixedTemp122.port.Q_flow = 0.0; FixedTemp122.port.T = TC_122_0.port_b.T; TC_121_0.port_b.Q_flow + FixedTemp121.port.Q_flow = 0.0; FixedTemp121.port.T = TC_121_0.port_b.T; TC_120_0.port_b.Q_flow + FixedTemp120.port.Q_flow = 0.0; FixedTemp120.port.T = TC_120_0.port_b.T; TC_119_0.port_b.Q_flow + FixedTemp119.port.Q_flow = 0.0; FixedTemp119.port.T = TC_119_0.port_b.T; TC_118_0.port_b.Q_flow + FixedTemp118.port.Q_flow = 0.0; FixedTemp118.port.T = TC_118_0.port_b.T; TC_117_0.port_b.Q_flow + FixedTemp117.port.Q_flow = 0.0; FixedTemp117.port.T = TC_117_0.port_b.T; TC_116_0.port_b.Q_flow + FixedTemp116.port.Q_flow = 0.0; FixedTemp116.port.T = TC_116_0.port_b.T; TC_115_0.port_b.Q_flow + FixedTemp115.port.Q_flow = 0.0; FixedTemp115.port.T = TC_115_0.port_b.T; TC_114_0.port_b.Q_flow + FixedTemp114.port.Q_flow = 0.0; FixedTemp114.port.T = TC_114_0.port_b.T; TC_113_0.port_b.Q_flow + FixedTemp113.port.Q_flow = 0.0; FixedTemp113.port.T = TC_113_0.port_b.T; TC_112_0.port_b.Q_flow + FixedTemp112.port.Q_flow = 0.0; FixedTemp112.port.T = TC_112_0.port_b.T; TC_111_0.port_b.Q_flow + FixedTemp111.port.Q_flow = 0.0; FixedTemp111.port.T = TC_111_0.port_b.T; TC_110_0.port_b.Q_flow + FixedTemp110.port.Q_flow = 0.0; FixedTemp110.port.T = TC_110_0.port_b.T; TC_109_0.port_b.Q_flow + FixedTemp109.port.Q_flow = 0.0; FixedTemp109.port.T = TC_109_0.port_b.T; TC_108_0.port_b.Q_flow + FixedTemp108.port.Q_flow = 0.0; FixedTemp108.port.T = TC_108_0.port_b.T; TC_107_0.port_b.Q_flow + FixedTemp107.port.Q_flow = 0.0; FixedTemp107.port.T = TC_107_0.port_b.T; TC_106_0.port_b.Q_flow + FixedTemp106.port.Q_flow = 0.0; FixedTemp106.port.T = TC_106_0.port_b.T; TC_105_0.port_b.Q_flow + FixedTemp105.port.Q_flow = 0.0; FixedTemp105.port.T = TC_105_0.port_b.T; TC_104_0.port_b.Q_flow + FixedTemp104.port.Q_flow = 0.0; FixedTemp104.port.T = TC_104_0.port_b.T; TC_103_0.port_b.Q_flow + FixedTemp103.port.Q_flow = 0.0; FixedTemp103.port.T = TC_103_0.port_b.T; TC_102_0.port_b.Q_flow + FixedTemp102.port.Q_flow = 0.0; FixedTemp102.port.T = TC_102_0.port_b.T; TC_101_0.port_b.Q_flow + FixedTemp101.port.Q_flow = 0.0; FixedTemp101.port.T = TC_101_0.port_b.T; TC_100_0.port_b.Q_flow + FixedTemp100.port.Q_flow = 0.0; FixedTemp100.port.T = TC_100_0.port_b.T; TC_99_0.port_b.Q_flow + FixedTemp099.port.Q_flow = 0.0; FixedTemp099.port.T = TC_99_0.port_b.T; TC_98_0.port_b.Q_flow + FixedTemp098.port.Q_flow = 0.0; FixedTemp098.port.T = TC_98_0.port_b.T; TC_97_0.port_b.Q_flow + FixedTemp097.port.Q_flow = 0.0; FixedTemp097.port.T = TC_97_0.port_b.T; TC_96_0.port_b.Q_flow + FixedTemp096.port.Q_flow = 0.0; FixedTemp096.port.T = TC_96_0.port_b.T; TC_95_0.port_b.Q_flow + FixedTemp095.port.Q_flow = 0.0; FixedTemp095.port.T = TC_95_0.port_b.T; TC_94_0.port_b.Q_flow + FixedTemp094.port.Q_flow = 0.0; FixedTemp094.port.T = TC_94_0.port_b.T; TC_93_0.port_b.Q_flow + FixedTemp093.port.Q_flow = 0.0; FixedTemp093.port.T = TC_93_0.port_b.T; TC_92_0.port_b.Q_flow + FixedTemp092.port.Q_flow = 0.0; FixedTemp092.port.T = TC_92_0.port_b.T; TC_91_0.port_b.Q_flow + FixedTemp091.port.Q_flow = 0.0; FixedTemp091.port.T = TC_91_0.port_b.T; TC_90_0.port_b.Q_flow + FixedTemp090.port.Q_flow = 0.0; FixedTemp090.port.T = TC_90_0.port_b.T; TC_89_0.port_b.Q_flow + FixedTemp089.port.Q_flow = 0.0; FixedTemp089.port.T = TC_89_0.port_b.T; TC_88_0.port_b.Q_flow + FixedTemp088.port.Q_flow = 0.0; FixedTemp088.port.T = TC_88_0.port_b.T; TC_87_0.port_b.Q_flow + FixedTemp087.port.Q_flow = 0.0; FixedTemp087.port.T = TC_87_0.port_b.T; TC_86_0.port_b.Q_flow + FixedTemp086.port.Q_flow = 0.0; FixedTemp086.port.T = TC_86_0.port_b.T; TC_85_0.port_b.Q_flow + FixedTemp085.port.Q_flow = 0.0; FixedTemp085.port.T = TC_85_0.port_b.T; TC_84_0.port_b.Q_flow + FixedTemp084.port.Q_flow = 0.0; FixedTemp084.port.T = TC_84_0.port_b.T; TC_83_0.port_b.Q_flow + FixedTemp083.port.Q_flow = 0.0; FixedTemp083.port.T = TC_83_0.port_b.T; TC_82_0.port_b.Q_flow + FixedTemp082.port.Q_flow = 0.0; FixedTemp082.port.T = TC_82_0.port_b.T; TC_81_0.port_b.Q_flow + FixedTemp081.port.Q_flow = 0.0; FixedTemp081.port.T = TC_81_0.port_b.T; TC_80_0.port_b.Q_flow + FixedTemp080.port.Q_flow = 0.0; FixedTemp080.port.T = TC_80_0.port_b.T; TC_79_0.port_b.Q_flow + FixedTemp079.port.Q_flow = 0.0; FixedTemp079.port.T = TC_79_0.port_b.T; TC_78_0.port_b.Q_flow + FixedTemp078.port.Q_flow = 0.0; FixedTemp078.port.T = TC_78_0.port_b.T; TC_77_0.port_b.Q_flow + FixedTemp077.port.Q_flow = 0.0; FixedTemp077.port.T = TC_77_0.port_b.T; TC_76_0.port_b.Q_flow + FixedTemp076.port.Q_flow = 0.0; FixedTemp076.port.T = TC_76_0.port_b.T; TC_75_0.port_b.Q_flow + FixedTemp075.port.Q_flow = 0.0; FixedTemp075.port.T = TC_75_0.port_b.T; TC_74_0.port_b.Q_flow + FixedTemp074.port.Q_flow = 0.0; FixedTemp074.port.T = TC_74_0.port_b.T; TC_73_0.port_b.Q_flow + FixedTemp073.port.Q_flow = 0.0; FixedTemp073.port.T = TC_73_0.port_b.T; TC_72_0.port_b.Q_flow + FixedTemp072.port.Q_flow = 0.0; FixedTemp072.port.T = TC_72_0.port_b.T; TC_71_0.port_b.Q_flow + FixedTemp071.port.Q_flow = 0.0; FixedTemp071.port.T = TC_71_0.port_b.T; TC_70_0.port_b.Q_flow + FixedTemp070.port.Q_flow = 0.0; FixedTemp070.port.T = TC_70_0.port_b.T; TC_69_0.port_b.Q_flow + FixedTemp069.port.Q_flow = 0.0; FixedTemp069.port.T = TC_69_0.port_b.T; TC_68_0.port_b.Q_flow + FixedTemp068.port.Q_flow = 0.0; FixedTemp068.port.T = TC_68_0.port_b.T; TC_67_0.port_b.Q_flow + FixedTemp067.port.Q_flow = 0.0; FixedTemp067.port.T = TC_67_0.port_b.T; TC_66_0.port_b.Q_flow + FixedTemp066.port.Q_flow = 0.0; FixedTemp066.port.T = TC_66_0.port_b.T; TC_65_0.port_b.Q_flow + FixedTemp065.port.Q_flow = 0.0; FixedTemp065.port.T = TC_65_0.port_b.T; TC_64_0.port_b.Q_flow + FixedTemp064.port.Q_flow = 0.0; FixedTemp064.port.T = TC_64_0.port_b.T; TC_63_0.port_b.Q_flow + FixedTemp063.port.Q_flow = 0.0; FixedTemp063.port.T = TC_63_0.port_b.T; TC_62_0.port_b.Q_flow + FixedTemp062.port.Q_flow = 0.0; FixedTemp062.port.T = TC_62_0.port_b.T; TC_61_0.port_b.Q_flow + FixedTemp061.port.Q_flow = 0.0; FixedTemp061.port.T = TC_61_0.port_b.T; TC_60_0.port_b.Q_flow + FixedTemp060.port.Q_flow = 0.0; FixedTemp060.port.T = TC_60_0.port_b.T; TC_59_0.port_b.Q_flow + FixedTemp059.port.Q_flow = 0.0; FixedTemp059.port.T = TC_59_0.port_b.T; TC_58_0.port_b.Q_flow + FixedTemp058.port.Q_flow = 0.0; FixedTemp058.port.T = TC_58_0.port_b.T; TC_57_0.port_b.Q_flow + FixedTemp057.port.Q_flow = 0.0; FixedTemp057.port.T = TC_57_0.port_b.T; TC_56_0.port_b.Q_flow + FixedTemp056.port.Q_flow = 0.0; FixedTemp056.port.T = TC_56_0.port_b.T; TC_55_0.port_b.Q_flow + FixedTemp055.port.Q_flow = 0.0; FixedTemp055.port.T = TC_55_0.port_b.T; TC_54_0.port_b.Q_flow + FixedTemp054.port.Q_flow = 0.0; FixedTemp054.port.T = TC_54_0.port_b.T; TC_53_0.port_b.Q_flow + FixedTemp053.port.Q_flow = 0.0; FixedTemp053.port.T = TC_53_0.port_b.T; TC_52_0.port_b.Q_flow + FixedTemp052.port.Q_flow = 0.0; FixedTemp052.port.T = TC_52_0.port_b.T; TC_51_0.port_b.Q_flow + FixedTemp051.port.Q_flow = 0.0; FixedTemp051.port.T = TC_51_0.port_b.T; TC_50_0.port_b.Q_flow + FixedTemp050.port.Q_flow = 0.0; FixedTemp050.port.T = TC_50_0.port_b.T; TC_49_0.port_b.Q_flow + FixedTemp049.port.Q_flow = 0.0; FixedTemp049.port.T = TC_49_0.port_b.T; TC_48_0.port_b.Q_flow + FixedTemp048.port.Q_flow = 0.0; FixedTemp048.port.T = TC_48_0.port_b.T; TC_47_0.port_b.Q_flow + FixedTemp047.port.Q_flow = 0.0; FixedTemp047.port.T = TC_47_0.port_b.T; TC_46_0.port_b.Q_flow + FixedTemp046.port.Q_flow = 0.0; FixedTemp046.port.T = TC_46_0.port_b.T; TC_45_0.port_b.Q_flow + FixedTemp045.port.Q_flow = 0.0; FixedTemp045.port.T = TC_45_0.port_b.T; TC_44_0.port_b.Q_flow + FixedTemp044.port.Q_flow = 0.0; FixedTemp044.port.T = TC_44_0.port_b.T; TC_43_0.port_b.Q_flow + FixedTemp043.port.Q_flow = 0.0; FixedTemp043.port.T = TC_43_0.port_b.T; TC_42_0.port_b.Q_flow + FixedTemp042.port.Q_flow = 0.0; FixedTemp042.port.T = TC_42_0.port_b.T; TC_41_0.port_b.Q_flow + FixedTemp041.port.Q_flow = 0.0; FixedTemp041.port.T = TC_41_0.port_b.T; TC_40_0.port_b.Q_flow + FixedTemp040.port.Q_flow = 0.0; FixedTemp040.port.T = TC_40_0.port_b.T; TC_39_0.port_b.Q_flow + FixedTemp039.port.Q_flow = 0.0; FixedTemp039.port.T = TC_39_0.port_b.T; TC_38_0.port_b.Q_flow + FixedTemp038.port.Q_flow = 0.0; FixedTemp038.port.T = TC_38_0.port_b.T; TC_37_0.port_b.Q_flow + FixedTemp037.port.Q_flow = 0.0; FixedTemp037.port.T = TC_37_0.port_b.T; TC_36_0.port_b.Q_flow + FixedTemp036.port.Q_flow = 0.0; FixedTemp036.port.T = TC_36_0.port_b.T; TC_35_0.port_b.Q_flow + FixedTemp035.port.Q_flow = 0.0; FixedTemp035.port.T = TC_35_0.port_b.T; TC_34_0.port_b.Q_flow + FixedTemp034.port.Q_flow = 0.0; FixedTemp034.port.T = TC_34_0.port_b.T; TC_33_0.port_b.Q_flow + FixedTemp033.port.Q_flow = 0.0; FixedTemp033.port.T = TC_33_0.port_b.T; TC_32_0.port_b.Q_flow + FixedTemp032.port.Q_flow = 0.0; FixedTemp032.port.T = TC_32_0.port_b.T; TC_31_0.port_b.Q_flow + FixedTemp031.port.Q_flow = 0.0; FixedTemp031.port.T = TC_31_0.port_b.T; TC_30_0.port_b.Q_flow + FixedTemp030.port.Q_flow = 0.0; FixedTemp030.port.T = TC_30_0.port_b.T; TC_29_0.port_b.Q_flow + FixedTemp029.port.Q_flow = 0.0; FixedTemp029.port.T = TC_29_0.port_b.T; TC_28_0.port_b.Q_flow + FixedTemp028.port.Q_flow = 0.0; FixedTemp028.port.T = TC_28_0.port_b.T; TC_27_0.port_b.Q_flow + FixedTemp027.port.Q_flow = 0.0; FixedTemp027.port.T = TC_27_0.port_b.T; TC_26_0.port_b.Q_flow + FixedTemp026.port.Q_flow = 0.0; FixedTemp026.port.T = TC_26_0.port_b.T; TC_25_0.port_b.Q_flow + FixedTemp025.port.Q_flow = 0.0; FixedTemp025.port.T = TC_25_0.port_b.T; TC_24_0.port_b.Q_flow + FixedTemp024.port.Q_flow = 0.0; FixedTemp024.port.T = TC_24_0.port_b.T; TC_23_0.port_b.Q_flow + FixedTemp023.port.Q_flow = 0.0; FixedTemp023.port.T = TC_23_0.port_b.T; TC_22_0.port_b.Q_flow + FixedTemp022.port.Q_flow = 0.0; FixedTemp022.port.T = TC_22_0.port_b.T; TC_21_0.port_b.Q_flow + FixedTemp021.port.Q_flow = 0.0; FixedTemp021.port.T = TC_21_0.port_b.T; TC_20_0.port_b.Q_flow + FixedTemp020.port.Q_flow = 0.0; FixedTemp020.port.T = TC_20_0.port_b.T; TC_19_0.port_b.Q_flow + FixedTemp019.port.Q_flow = 0.0; FixedTemp019.port.T = TC_19_0.port_b.T; TC_18_0.port_b.Q_flow + FixedTemp018.port.Q_flow = 0.0; FixedTemp018.port.T = TC_18_0.port_b.T; TC_17_0.port_b.Q_flow + FixedTemp017.port.Q_flow = 0.0; FixedTemp017.port.T = TC_17_0.port_b.T; TC_16_0.port_b.Q_flow + FixedTemp016.port.Q_flow = 0.0; FixedTemp016.port.T = TC_16_0.port_b.T; TC_15_0.port_b.Q_flow + FixedTemp015.port.Q_flow = 0.0; FixedTemp015.port.T = TC_15_0.port_b.T; TC_14_0.port_b.Q_flow + FixedTemp014.port.Q_flow = 0.0; FixedTemp014.port.T = TC_14_0.port_b.T; TC_13_0.port_b.Q_flow + FixedTemp013.port.Q_flow = 0.0; FixedTemp013.port.T = TC_13_0.port_b.T; TC_12_0.port_b.Q_flow + FixedTemp012.port.Q_flow = 0.0; FixedTemp012.port.T = TC_12_0.port_b.T; TC_11_0.port_b.Q_flow + FixedTemp011.port.Q_flow = 0.0; FixedTemp011.port.T = TC_11_0.port_b.T; TC_10_0.port_b.Q_flow + FixedTemp010.port.Q_flow = 0.0; FixedTemp010.port.T = TC_10_0.port_b.T; TC_9_0.port_b.Q_flow + FixedTemp009.port.Q_flow = 0.0; FixedTemp009.port.T = TC_9_0.port_b.T; TC_8_0.port_b.Q_flow + FixedTemp008.port.Q_flow = 0.0; FixedTemp008.port.T = TC_8_0.port_b.T; TC_7_0.port_b.Q_flow + FixedTemp007.port.Q_flow = 0.0; FixedTemp007.port.T = TC_7_0.port_b.T; TC_6_0.port_b.Q_flow + FixedTemp006.port.Q_flow = 0.0; FixedTemp006.port.T = TC_6_0.port_b.T; TC_5_0.port_b.Q_flow + FixedTemp005.port.Q_flow = 0.0; FixedTemp005.port.T = TC_5_0.port_b.T; TC_4_0.port_b.Q_flow + FixedTemp004.port.Q_flow = 0.0; FixedTemp004.port.T = TC_4_0.port_b.T; TC_3_0.port_b.Q_flow + FixedTemp003.port.Q_flow = 0.0; FixedTemp003.port.T = TC_3_0.port_b.T; TC_2_0.port_b.Q_flow + FixedTemp002.port.Q_flow = 0.0; FixedTemp002.port.T = TC_2_0.port_b.T; TC_1_0.port_b.Q_flow + FixedTemp001.port.Q_flow = 0.0; FixedTemp001.port.T = TC_1_0.port_b.T; end Model; " "" [BENCH: 4037.76 seconds total from which 22.82 seconds GC, 13739 minor collections, 67 major collections]