Running: ./testmodel.py --libraries=/home/hudson/saved_omc/libraries/.openmodelica/libraries --ompython_omhome=/usr ClaRa_ClaRa.Examples.SteamPowerPlant_CombinedComponents_01.conf.json
loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/TILMedia 1.8.1-main/package.mo", uses=false)
loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.0.0+maint.om/package.mo", uses=false)
loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.0.0+maint.om/package.mo", uses=false)
loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 4.0.0+maint.om/package.mo", uses=false)
loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/ClaRa 1.8.1/package.mo", uses=false)
Using package ClaRa with version 1.8.1 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/ClaRa 1.8.1/package.mo)
Using package Modelica with version 4.0.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 4.0.0+maint.om/package.mo)
Using package Complex with version 4.0.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.0.0+maint.om/package.mo)
Using package ModelicaServices with version 4.0.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.0.0+maint.om/package.mo)
Using package TILMedia with version 1.8.1 ClaRa (/home/hudson/saved_omc/libraries/.openmodelica/libraries/TILMedia 1.8.1-main/package.mo)
Running command: translateModel(ClaRa.Examples.SteamPowerPlant_CombinedComponents_01,tolerance=1e-05,outputFormat="mat",numberOfIntervals=5000,variableFilter="Time|burner1.burner.bulk.h|burner1.pipeFlow_FTW.summary.outline.Q_flow_tot|burner2.burner.bulk.h|burner2.pipeFlow_FTW.summary.outline.Q_flow_tot|burner3.burner.bulk.h|burner3.pipeFlow_FTW.summary.outline.Q_flow_tot|burner4.burner.bulk.h|burner4.pipeFlow_FTW.summary.outline.Q_flow_tot|condenser.shell.summary.outline.Q_flow_tot|condenser.tubes.summary.outline.Q_flow_tot|downComer_feedWaterTank.summary.outline.Q_flow_tot|eco_down.summary.outline.Q_flow_tot|eco_riser.summary.outline.Q_flow_tot|feedWaterTank.volume.summary.outline.Q_flow_tot|flameRoom_eco.flameRoom.bulk.h|flameRoom_eco.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_eco.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_eco.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_evap_1.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_evap_2.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_rh_1.flameRoom.bulk.h|flameRoom_rh_1.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_rh_1.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_rh_1.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_rh_2.flameRoom.bulk.h|flameRoom_rh_2.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_rh_2.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_rh_2.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_sh_1.flameRoom.bulk.h|flameRoom_sh_1.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_sh_1.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_sh_1.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_sh_2.flameRoom.bulk.h|flameRoom_sh_2.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_sh_2.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_sh_2.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_sh_3.flameRoom.bulk.h|flameRoom_sh_3.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_sh_3.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_sh_3.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_sh_4.flameRoom.bulk.h|flameRoom_sh_4.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_sh_4.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_sh_4.pipeFlow_TB.summary.outline.Q_flow_tot|hopper.hopper.bulk.h|hopper.pipeFlow_FTW.summary.outline.Q_flow_tot|preheater_HP.shell.summary.outline.Q_flow_tot|preheater_HP.tubes.summary.outline.Q_flow_tot|preheater_LP1.shell.summary.outline.Q_flow_tot|preheater_LP1.tubes.summary.outline.Q_flow_tot|preheater_LP2.shell.summary.outline.Q_flow_tot|preheater_LP2.tubes.summary.outline.Q_flow_tot|preheater_LP3.shell.summary.outline.Q_flow_tot|preheater_LP3.tubes.summary.outline.Q_flow_tot|preheater_LP4.shell.summary.outline.Q_flow_tot|preheater_LP4.tubes.summary.outline.Q_flow_tot|regenerativeAirPreheater.flueGasCell.summary.outline.Q_flow_tot|regenerativeAirPreheater.freshAirCell.summary.outline.Q_flow_tot|regenerativeAirPreheater.freshAirLeakage_join.bulk.h|rh_pipe.summary.outline.Q_flow_tot|separator.summary.outline.Q_flow_tot|sh_pipe.summary.outline.Q_flow_tot",fileNamePrefix="ClaRa_ClaRa.Examples.SteamPowerPlant_CombinedComponents_01")
translateModel(ClaRa.Examples.SteamPowerPlant_CombinedComponents_01,tolerance=1e-05,outputFormat="mat",numberOfIntervals=5000,variableFilter="Time|burner1.burner.bulk.h|burner1.pipeFlow_FTW.summary.outline.Q_flow_tot|burner2.burner.bulk.h|burner2.pipeFlow_FTW.summary.outline.Q_flow_tot|burner3.burner.bulk.h|burner3.pipeFlow_FTW.summary.outline.Q_flow_tot|burner4.burner.bulk.h|burner4.pipeFlow_FTW.summary.outline.Q_flow_tot|condenser.shell.summary.outline.Q_flow_tot|condenser.tubes.summary.outline.Q_flow_tot|downComer_feedWaterTank.summary.outline.Q_flow_tot|eco_down.summary.outline.Q_flow_tot|eco_riser.summary.outline.Q_flow_tot|feedWaterTank.volume.summary.outline.Q_flow_tot|flameRoom_eco.flameRoom.bulk.h|flameRoom_eco.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_eco.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_eco.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_evap_1.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_evap_2.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_rh_1.flameRoom.bulk.h|flameRoom_rh_1.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_rh_1.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_rh_1.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_rh_2.flameRoom.bulk.h|flameRoom_rh_2.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_rh_2.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_rh_2.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_sh_1.flameRoom.bulk.h|flameRoom_sh_1.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_sh_1.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_sh_1.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_sh_2.flameRoom.bulk.h|flameRoom_sh_2.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_sh_2.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_sh_2.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_sh_3.flameRoom.bulk.h|flameRoom_sh_3.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_sh_3.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_sh_3.pipeFlow_TB.summary.outline.Q_flow_tot|flameRoom_sh_4.flameRoom.bulk.h|flameRoom_sh_4.pipeFlow_CT.summary.outline.Q_flow_tot|flameRoom_sh_4.pipeFlow_FTW.summary.outline.Q_flow_tot|flameRoom_sh_4.pipeFlow_TB.summary.outline.Q_flow_tot|hopper.hopper.bulk.h|hopper.pipeFlow_FTW.summary.outline.Q_flow_tot|preheater_HP.shell.summary.outline.Q_flow_tot|preheater_HP.tubes.summary.outline.Q_flow_tot|preheater_LP1.shell.summary.outline.Q_flow_tot|preheater_LP1.tubes.summary.outline.Q_flow_tot|preheater_LP2.shell.summary.outline.Q_flow_tot|preheater_LP2.tubes.summary.outline.Q_flow_tot|preheater_LP3.shell.summary.outline.Q_flow_tot|preheater_LP3.tubes.summary.outline.Q_flow_tot|preheater_LP4.shell.summary.outline.Q_flow_tot|preheater_LP4.tubes.summary.outline.Q_flow_tot|regenerativeAirPreheater.flueGasCell.summary.outline.Q_flow_tot|regenerativeAirPreheater.freshAirCell.summary.outline.Q_flow_tot|regenerativeAirPreheater.freshAirLeakage_join.bulk.h|rh_pipe.summary.outline.Q_flow_tot|separator.summary.outline.Q_flow_tot|sh_pipe.summary.outline.Q_flow_tot",fileNamePrefix="ClaRa_ClaRa.Examples.SteamPowerPlant_CombinedComponents_01")
Thread is still alive.
OMC died, but the thread is still running? This will end badly. The log-file of omc:
Created ZeroMQ Server.
Dumped server port in file: /tmp/openmodelica.hudson.port.37982809aef54b668a54ab43705b5dc8
Nonlinear iteration variables with predefined start attribute in NLSJac28. (1)
========================================
1: NOM.join_LP_main.m_flow_1:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate of flow 1" type: Real


Linear iteration variables with predefined start attributes that are unrelevant in NLSJac28. (6)
========================================
1: NOM.Turbine_LP4.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
2: NOM.Turbine_LP3.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
3: NOM.Turbine_LP2.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
4: NOM.Turbine_LP1.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
5: NOM.Turbine_IP3.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
6: NOM.join_preheater_LP3.m_flow_1:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate of flow 1" type: Real

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac229. (1)
========================================
1: feedWaterTank.volume.pressureLoss.Delta_p[2]:VARIABLE(start = 1.0 unit = "Pa" nominal = 100000.0 )  "Pressure difference du to friction" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac232. (1)
========================================
1: INIT.join_preheater_LP3.m_flow_1:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate of flow 1" type: Real


Linear iteration variables with predefined start attributes that are unrelevant in NLSJac232. (6)
========================================
1: INIT.join_LP_main.m_flow_1:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate of flow 1" type: Real
2: INIT.Turbine_IP3.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
3: INIT.Turbine_LP1.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
4: INIT.Turbine_LP2.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
5: INIT.Turbine_LP3.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
6: INIT.Turbine_LP4.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Linear iteration variables with predefined start attributes that are unrelevant in NLSJac301. (1)
========================================
1: $DER.separator.h:VARIABLE(start = separator.h_start unit = "J/kg" nominal = 1000.0 protected = true )  "spec. enthalpy state" type: Real

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac323. (1)
========================================
1: hopper.wall_FTW.summary.T_o[4]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0)))))))))))))) start = hopper.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [4]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Linear iteration variables with predefined start attributes that are unrelevant in NLSJac326. (1)
========================================
1: $DER.splitGas_L2_flex.bulk.h:VARIABLE(start = splitGas_L2_flex.h_start unit = "J/kg" nominal = 1000.0 stateSelect=StateSelect.prefer protected = true )  "Specific enthalpy" type: Real

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac327. (1)
========================================
1: burner1.wall_FTW.summary.T_o[3]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))) start = burner1.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac329. (1)
========================================
1: burner2.wall_FTW.summary.T_o[3]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))) start = burner2.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac331. (1)
========================================
1: burner3.wall_FTW.summary.T_o[3]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))) start = burner3.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac333. (1)
========================================
1: burner4.wall_FTW.summary.T_o[3]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))) start = burner4.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac335. (1)
========================================
1: flameRoom_evap_1.wall_FTW.summary.T_o[3]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))) start = flameRoom_evap_1.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac336. (1)
========================================
1: flameRoom_evap_2.wall_FTW.summary.T_o[4]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0)))))))))))))) start = flameRoom_evap_2.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [4]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac387. (1)
========================================
1: NOM.join_LP_main.m_flow_1:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate of flow 1" type: Real


Linear iteration variables with predefined start attributes that are unrelevant in NLSJac387. (6)
========================================
1: NOM.Turbine_LP4.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
2: NOM.Turbine_LP3.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
3: NOM.Turbine_LP2.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
4: NOM.Turbine_LP1.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
5: NOM.Turbine_IP3.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
6: NOM.join_preheater_LP3.m_flow_1:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate of flow 1" type: Real

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Linear iteration variables with predefined start attributes that are unrelevant in NLSJac539. (2)
========================================
1: PI_feedwaterPump.I.y:VARIABLE(flow=false start = PI_feedwaterPump.I.y_start_const )  "Connector of Real output signal" type: Real
2: preheater_HP.tubes.pressureLoss.Delta_p:VARIABLE(min = 0.0 start = 0.0 unit = "Pa" nominal = 100000.0 )  type: Real

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac585. (1)
========================================
1: feedWaterTank.volume.pressureLoss.Delta_p[2]:VARIABLE(start = 1.0 unit = "Pa" nominal = 100000.0 )  "Pressure difference du to friction" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Linear iteration variables with predefined start attributes that are unrelevant in NLSJac586. (1)
========================================
1: join_preheater_LP3.pressureLossIn2.m_flow:VARIABLE(start = Pump_preheater_LP3.m_flow_start unit = "kg/s" nominal = 1.0 )  type: Real

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac587. (1)
========================================
1: INIT.join_preheater_LP3.m_flow_1:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate of flow 1" type: Real


Linear iteration variables with predefined start attributes that are unrelevant in NLSJac587. (6)
========================================
1: INIT.Turbine_LP4.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
2: INIT.Turbine_LP3.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
3: INIT.Turbine_LP2.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
4: INIT.Turbine_LP1.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
5: INIT.Turbine_IP3.m_flow:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate" type: Real
6: INIT.join_LP_main.m_flow_1:VARIABLE(start = 1.0 unit = "kg/s" fixed = false nominal = 1.0 final = true )  "Mass flow rate of flow 1" type: Real

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac676. (1)
========================================
1: hopper.wall_FTW.summary.T_o[4]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0)))))))))))))) start = hopper.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [4]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac680. (1)
========================================
1: burner1.wall_FTW.summary.T_o[3]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))) start = burner1.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac682. (1)
========================================
1: burner2.wall_FTW.summary.T_o[3]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))) start = burner2.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac684. (1)
========================================
1: burner3.wall_FTW.summary.T_o[3]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))) start = burner3.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac686. (1)
========================================
1: burner4.wall_FTW.summary.T_o[3]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))) start = burner4.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac688. (1)
========================================
1: flameRoom_evap_1.wall_FTW.summary.T_o[3]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))) start = flameRoom_evap_1.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [3]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac689. (1)
========================================
1: flameRoom_evap_2.wall_FTW.summary.T_o[4]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0)))))))))))))) start = flameRoom_evap_2.wall_FTW.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [4]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac690. (1)
========================================
1: flameRoom_sh_1.wall_TB.summary.T_o[5]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))))))))) start = flameRoom_sh_1.wall_TB.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [5]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac691. (1)
========================================
1: flameRoom_sh_2.wall_TB.summary.T_o[5]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))))))))) start = flameRoom_sh_2.wall_TB.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [5]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac692. (1)
========================================
1: flameRoom_sh_4.wall_TB.summary.T_o[5]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))))))))) start = flameRoom_sh_4.wall_TB.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [5]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac693. (1)
========================================
1: flameRoom_rh_2.wall_TB.summary.T_o[5]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))))))))) start = flameRoom_rh_2.wall_TB.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [5]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")


Nonlinear iteration variables with predefined start attribute in NLSJac694. (1)
========================================
1: flameRoom_sh_3.wall_TB.summary.T_o[5]:VARIABLE(min = max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, max(0.0, 0.0))))))))))))))))) start = flameRoom_sh_3.wall_TB.T_start[1] unit = "K" nominal = 300.0 )  "Outer phase temperature" type: Real [5]

Info: Only non-linear iteration variables in non-linear eqation systems require start values. All other start values have no influence on convergence and are ignored. Use "-d=dumpLoops" to show all loops. In OMEdit Tools->Options->Simulation->Additional Translation Flags, in OMNotebook call setCommandLineOptions("-d=dumpLoops")

mmap(PROT_NONE) failed
Aborted (core dumped)
Aborted the command.
Failed to read output from testmodel.py, exit status != 0:
OMC died, but the thread is still running? This will end badly.