Running: ./testmodel.py --libraries=/home/hudson/saved_omc/libraries/.openmodelica/libraries --ompython_omhome=/usr ModelicaTest_3.2.1_ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.conf.json 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 3.2.3+maint.om/package.mo", uses=false) loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaTest 3.2.1+maint.om/package.mo", uses=false) Using package ModelicaTest with version 3.2.1 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaTest 3.2.1+maint.om/package.mo) Using package Modelica with version 3.2.3 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 3.2.3+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) Running command: translateModel(ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph,tolerance=1e-06,outputFormat="empty",numberOfIntervals=5000,variableFilter="",fileNamePrefix="ModelicaTest_3.2.1_ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph") translateModel(ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph,tolerance=1e-06,outputFormat="empty",numberOfIntervals=5000,variableFilter="",fileNamePrefix="ModelicaTest_3.2.1_ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph") Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.0.0+maint.om/package.mo): time 0.001143/0.001143, allocations: 105.8 kB / 16.42 MB, free: 6.465 MB / 14.72 MB Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.0.0+maint.om/package.mo): time 0.00111/0.001111, allocations: 183.2 kB / 17.36 MB, free: 5.699 MB / 14.72 MB Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 3.2.3+maint.om/package.mo): time 1.191/1.191, allocations: 205.1 MB / 223.2 MB, free: 12.22 MB / 190.1 MB Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaTest 3.2.1+maint.om/package.mo): time 0.1631/0.1631, allocations: 38 MB / 308.6 MB, free: 5.984 MB / 254.1 MB Notification: Performance of FrontEnd - Absyn->SCode: time 1.823e-05/1.824e-05, allocations: 2.281 kB / 433.6 MB, free: 14.46 MB / 318.1 MB Notification: Performance of NFInst.instantiate(ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph): time 0.03296/0.03298, allocations: 39.03 MB / 472.7 MB, free: 7.289 MB / 350.1 MB Notification: Performance of NFInst.instExpressions: time 0.02106/0.05407, allocations: 20.16 MB / 492.8 MB, free: 3.059 MB / 366.1 MB Notification: Performance of NFInst.updateImplicitVariability: time 0.0006943/0.05481, allocations: 23.88 kB / 492.9 MB, free: 3.035 MB / 366.1 MB Notification: Performance of NFTyping.typeComponents: time 0.001072/0.0559, allocations: 449.3 kB / 493.3 MB, free: 2.594 MB / 366.1 MB Notification: Performance of NFTyping.typeBindings: time 0.01266/0.06857, allocations: 5.1 MB / 498.4 MB, free: 13.49 MB / 382.1 MB Notification: Performance of NFTyping.typeClassSections: time 0.00635/0.07493, allocations: 2.556 MB / 0.4892 GB, free: 10.93 MB / 382.1 MB Notification: Performance of NFFlatten.flatten: time 0.002498/0.07744, allocations: 2.113 MB / 0.4913 GB, free: 8.809 MB / 382.1 MB Notification: Performance of NFFlatten.resolveConnections: time 0.0006397/0.07809, allocations: 0.4975 MB / 0.4918 GB, free: 8.309 MB / 382.1 MB Notification: Performance of NFEvalConstants.evaluate: time 0.008956/0.08706, allocations: 4.262 MB / 0.4959 GB, free: 3.992 MB / 382.1 MB Notification: Performance of NFSimplifyModel.simplify: time 0.01034/0.09743, allocations: 5.424 MB / 0.5012 GB, free: 14.48 MB / 398.1 MB Notification: Performance of NFPackage.collectConstants: time 0.0002095/0.09766, allocations: 68 kB / 0.5013 GB, free: 14.42 MB / 398.1 MB Notification: Performance of NFFlatten.collectFunctions: time 0.01115/0.1088, allocations: 6.888 MB / 0.508 GB, free: 7.523 MB / 398.1 MB Notification: Performance of combineBinaries: time 0.001498/0.1103, allocations: 1.463 MB / 0.5094 GB, free: 6.047 MB / 398.1 MB Notification: Performance of replaceArrayConstructors: time 0.000655/0.111, allocations: 0.938 MB / 0.5104 GB, free: 5.098 MB / 398.1 MB Notification: Performance of NFVerifyModel.verify: time 0.0002058/0.1112, allocations: 135.6 kB / 0.5105 GB, free: 4.965 MB / 398.1 MB Notification: Performance of FrontEnd: time 0.0001722/0.1114, allocations: 23.86 kB / 0.5105 GB, free: 4.941 MB / 398.1 MB Notification: Model statistics after passing the front-end and creating the data structures used by the back-end: * Number of equations: 160 (122) * Number of variables: 170 (131) Notification: Performance of Bindings: time 0.003832/0.1152, allocations: 4.289 MB / 0.5147 GB, free: 0.5078 MB / 398.1 MB Notification: Performance of FunctionAlias: time 0.0002075/0.1154, allocations: 179.7 kB / 0.5149 GB, free: 340 kB / 398.1 MB Notification: Performance of Early Inline: time 0.00206/0.1175, allocations: 2.089 MB / 0.5169 GB, free: 14.2 MB / 414.1 MB Notification: Performance of simplify1: time 0.0001362/0.1177, allocations: 123.8 kB / 0.517 GB, free: 14.08 MB / 414.1 MB Notification: Performance of Alias: time 0.001918/0.1196, allocations: 1.899 MB / 0.5189 GB, free: 11.97 MB / 414.1 MB Notification: Performance of simplify2: time 0.0001116/0.1197, allocations: 115.8 kB / 0.519 GB, free: 11.86 MB / 414.1 MB Notification: Performance of Events: time 0.0004771/0.1202, allocations: 407.5 kB / 0.5194 GB, free: 11.46 MB / 414.1 MB Notification: Performance of Detect States: time 0.0005557/0.1208, allocations: 0.5959 MB / 0.52 GB, free: 10.84 MB / 414.1 MB Notification: Performance of Partitioning: time 0.0009078/0.1217, allocations: 0.9884 MB / 0.5209 GB, free: 9.68 MB / 414.1 MB Error: Internal error NBSlice.fillDependencyArray failed because number of flattened indices 1 for dependency shortPipe.port_b.m_flow could not be divided by the body size 2 without rest. Error: Internal error NBAdjacency.Matrix.createPseudo failed for: [ARRY] (2) shortPipe.flowModel.vs = {-shortPipe.port_b.m_flow / (shortPipe.flowModel.crossAreas[1] * shortPipe.flowModel.states.d), -shortPipe.port_b.m_flow / (shortPipe.flowModel.states.d * shortPipe.flowModel.crossAreas[2])} / shortPipe.nParallel ($RES_BND_147) Error: Internal error NBAdjacency.Matrix.create failed to create adjacency matrix for system: System Variables (107/143) **************************** (1) [ALGB] (1) Real ambient.medium.state.p (start = 5e6, min = 611.657, max = 1e8, nominal = 1e6) (2) [ALGB] (4) input Real[2, 2] shortPipe.flowModel.states.T (start = {500.0 for $i1 in 1:2}, min = {273.15 for $i1 in 1:2}, max = {2273.15 for $i1 in 1:2}, nominal = {500.0 for $i1 in 1:2}) (3) [ALGB] (1) Real fixedMassFlowRate.medium.h (StateSelect = default) (4) [ALGB] (1) Real fixedMassFlowRate.medium.state.h (start = 1e5, min = -1e10, max = 1e10, nominal = 5e5) (5) [ALGB] (1) Real volume.medium.T_degC = Modelica.SIunits.Conversions.to_degC(-((-273.15) - volume.medium.T_degC)) (6) [ALGB] (1) Real[1] shortPipe.flowModel.Ib_flows (7) [ALGB] (1) Real fixedMassFlowRate.medium.d (start = 150.0, min = 0.0, max = 1e5, nominal = 500.0, StateSelect = default) (8) [ALGB] (1) Real fixedMassFlowRate.medium.state.d (start = 150.0, min = 0.0, max = 1e5, nominal = 500.0) (9) [ALGB] (1) Real volume.medium.sat.psat (start = 5e6, min = 611.657, max = 1e8, nominal = 1e6) (10) [ALGB] (1) Real ambient.medium.p_bar = Modelica.SIunits.Conversions.to_bar(99999.99999999999 * ambient.medium.p_bar) (11) [ALGB] (1) Real[1] volume.heatTransfer.Q_flows (12) [ALGB] (2) Real[2] volume.portInDensities (start = {150.0 for $i1 in 1:2}, min = {0.0 for $i1 in 1:2}, max = {1e5 for $i1 in 1:2}, nominal = {500.0 for $i1 in 1:2}) (13) [ALGB] (1) Real[1] shortPipe.flowModel.Is (14) [ALGB] (2) Real[2] shortPipe.flowModel.mus = {shortPipe.flowModel.mu_nominal for $i1 in 1:2} (start = {0.001 for $i1 in 1:2}, min = {0.0 for $i1 in 1:2}, max = {1e8 for $i1 in 1:2}, nominal = {0.001 for $i1 in 1:2}) (15) [ALGB] (1) final input Real[1, 1] volume.heatTransfer.states.T = {volume.medium.state.T} (start = {500.0 for $i1 in 1:1}, min = {273.15 for $i1 in 1:1}, max = {2273.15 for $i1 in 1:1}, nominal = {500.0 for $i1 in 1:1}) (16) [ALGB] (2) protected Real[2] volume.portsData_height (17) [ALGB] (2) Real[2] shortPipe.flowModel.rhos = {ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.shortPipe.flowModel.Medium.density(shortPipe.flowModel.states[$i1]) for $i1 in 1:2} (start = {150.0 for $i1 in 1:2}, min = {0.0 for $i1 in 1:2}, max = {1e5 for $i1 in 1:2}, nominal = {500.0 for $i1 in 1:2}) (18) [ALGB] (1) Real ambient.medium.T_degC = Modelica.SIunits.Conversions.to_degC(-((-273.15) - ambient.medium.T_degC)) (19) [ALGB] (1) stream Real[1] fixedMassFlowRate.ports.h_outflow (start = {1e5 for $i1 in 1:1}, min = {-1e10 for $i1 in 1:1}, max = {1e10 for $i1 in 1:1}, nominal = {5e5 for $i1 in 1:1}) (20) [DISC] (1) final input Integer[1, 1] volume.heatTransfer.states.phase = {volume.medium.state.phase} (min = {0 for $i1 in 1:1}, max = {2 for $i1 in 1:1}) (21) [ALGB] (1) Real volume.medium.sat.Tsat (start = 500.0, min = 273.15, max = 2273.15, nominal = 500.0) (22) [DISC] (2) Boolean[2] $SEV_11[$i1] (23) [ALGB] (1) Real fixedMassFlowRate.medium.state.T (start = 500.0, min = 273.15, max = 2273.15, nominal = 500.0) (24) [ALGB] (1) Real[1] shortPipe.flowModel.Fs_fg (25) [ALGB] (2) Real[2] volume.portVelocities (26) [ALGB] (1) stream Real shortPipe.port_a.h_outflow (start = 1e5, min = -1e10, max = 1e10, nominal = 5e5) (27) [ALGB] (1) Real shortPipe.port_a.p (start = 5e6, min = 611.657, max = 1e8, nominal = 1e6) (28) [ALGB] (1) Real[1] volume.heatTransfer.heatPorts.T (start = {288.15 for $i1 in 1:1}, min = {0.0 for $i1 in 1:1}, nominal = {300.0 for $i1 in 1:1}) (29) [ALGB] (2) Real[2] volume.vessel_ps_static (start = {5e6 for $i1 in 1:2}, min = {611.657 for $i1 in 1:2}, max = {1e8 for $i1 in 1:2}, nominal = {1e6 for $i1 in 1:2}) (30) [ALGB] (1) Real[1] shortPipe.flowModel.mus_act (start = {0.001 for $i1 in 1:1}, min = {0.0 for $i1 in 1:1}, max = {1e8 for $i1 in 1:1}, nominal = {0.001 for $i1 in 1:1}) (31) [ALGB] (1) final input Real[1, 1] volume.heatTransfer.states.d = {volume.medium.state.d} (start = {150.0 for $i1 in 1:1}, min = {0.0 for $i1 in 1:1}, max = {1e5 for $i1 in 1:1}, nominal = {500.0 for $i1 in 1:1}) (32) [ALGB] (1) final input Real[1, 1] volume.heatTransfer.states.h = {volume.medium.state.h} (start = {1e5 for $i1 in 1:1}, min = {-1e10 for $i1 in 1:1}, max = {1e10 for $i1 in 1:1}, nominal = {5e5 for $i1 in 1:1}) (33) [ALGB] (1) protected Real ambient.state.p (start = 5e6, min = 611.657, max = 1e8, nominal = 1e6) (34) [ALGB] (1) Real[1] shortPipe.flowModel.dps_fg (start = {shortPipe.flowModel.p_a_start - shortPipe.flowModel.p_b_start for $i1 in 1:1}) (35) [ALGB] (1) Real[1] shortPipe.flowModel.m_flows (start = {0.0 for $i1 in 1:1}, min = {-1e60 for $i1 in 1:1}, max = {1e5 for $i1 in 1:1}, StateSelect = default) (36) [DISC] (1) Boolean $SEV_20 (37) [ALGB] (1) Real volume.mb_flow (38) [DISC] (2) protected Boolean[2] volume.regularFlow (start = {true for $i1 in 1:2}) (39) [ALGB] (1) stream Real[1] ambient.ports.h_outflow (start = {1e5 for $i1 in 1:1}, min = {-1e10 for $i1 in 1:1}, max = {1e10 for $i1 in 1:1}, nominal = {5e5 for $i1 in 1:1}) (40) [ALGB] (1) Real $FUN_3 (41) [ALGB] (1) final input Real[1, 1] volume.heatTransfer.states.p = {volume.medium.state.p} (start = {5e6 for $i1 in 1:1}, min = {611.657 for $i1 in 1:1}, max = {1e8 for $i1 in 1:1}, nominal = {1e6 for $i1 in 1:1}) (42) [ALGB] (1) protected Real ambient.state.h (start = 1e5, min = -1e10, max = 1e10, nominal = 5e5) (43) [ALGB] (1) Real $FUN_2 (44) [ALGB] (1) final Real[1] shortPipe.flowModel.pathLengths = {shortPipe.length} (45) [DISC] (2) Boolean[2] $SEV_9[$i1] (46) [ALGB] (1) flow Real[1] fixedMassFlowRate.ports.m_flow (min = {-1e60}, max = {1e60}) (47) [ALGB] (2) Real[2] volume.ports_H_flow (min = {-1e8 for $i1 in 1:2}, max = {1e8 for $i1 in 1:2}, nominal = {1000.0 for $i1 in 1:2}) (48) [ALGB] (1) Real[1] fixedMassFlowRate.ports.p (start = {5e6 for $i1 in 1:1}, min = {611.657 for $i1 in 1:1}, max = {1e8 for $i1 in 1:1}, nominal = {1e6 for $i1 in 1:1}) (49) [DISC] (2) Boolean[2] $SEV_10[$i1] (50) [DISC] (1) Boolean $SEV_18 (51) [ALGB] (2) Real[2] volume.ports_E_flow (52) [DISC] (1) Boolean $SEV_15 (53) [ALGB] (1) stream Real shortPipe.port_b.h_outflow (start = 1e5, min = -1e10, max = 1e10, nominal = 5e5) (54) [DISC] (1) Boolean $SEV_14 (55) [DISC] (2) Boolean[2] $SEV_13[$i1] (56) [ALGB] (1) final Real[1] shortPipe.flowModel.dheights = {shortPipe.height_ab} (57) [ALGB] (2) Real[2] volume.s (start = {volume.fluidLevel_max for $i1 in 1:2}) (58) [ALGB] (1) Real ambient.medium.sat.psat (start = 5e6, min = 611.657, max = 1e8, nominal = 1e6) (59) [ALGB] (1) Real fixedMassFlowRate.medium.p_bar = Modelica.SIunits.Conversions.to_bar(99999.99999999999 * fixedMassFlowRate.medium.p_bar) (60) [ALGB] (1) Real volume.medium.state.T (start = 500.0, min = 273.15, max = 2273.15, nominal = 500.0) (61) [ALGB] (1) Real[1] shortPipe.flowModel.Fs_p (62) [ALGB] (1) Real volume.Hb_flow (63) [ALGB] (2) flow Real[2] volume.ports.m_flow (min = {-1e5 for $i1 in 1:2}, max = {1e5 for $i1 in 1:2}) (64) [DER-] (1) Real $DER.volume.U (65) [ALGB] (1) Real volume.medium.d (start = 150.0, min = 0.0, max = 1e5, nominal = 500.0, StateSelect = default) (66) [ALGB] (2) Real[2] volume.ports.p (start = {5e6 for $i1 in 1:2}, min = {611.657 for $i1 in 1:2}, max = {1e8 for $i1 in 1:2}, nominal = {1e6 for $i1 in 1:2}) (67) [DISC] (4) input Integer[2, 2] shortPipe.flowModel.states.phase (min = {0 for $i1 in 1:2}, max = {2 for $i1 in 1:2}) (68) [DISC] (1) Boolean $SEV_8 (69) [ALGB] (2) final Real[2] shortPipe.flowModel.crossAreas = {shortPipe.crossArea, shortPipe.crossArea} (70) [ALGB] (1) Real ambient.medium.sat.Tsat (start = 500.0, min = 273.15, max = 2273.15, nominal = 500.0) (71) [ALGB] (1) Real volume.medium.h (fixed = true, start = volume.h_start, StateSelect = prefer) (72) [DISC] (1) Boolean $SEV_5 (73) [DISC] (1) Boolean $SEV_4 (74) [ALGB] (1) Real fixedMassFlowRate.medium.T_degC = Modelica.SIunits.Conversions.to_degC(-((-273.15) - fixedMassFlowRate.medium.T_degC)) (75) [ALGB] (1) flow Real shortPipe.port_b.m_flow (min = -1e5, max = 1e60) (76) [ALGB] (1) Real ambient.medium.state.T (start = 500.0, min = 273.15, max = 2273.15, nominal = 500.0) (77) [ALGB] (1) Real shortPipe.port_b.p (start = 5e6, min = 611.657, max = 1e8, nominal = 1e6) (78) [ALGB] (4) input Real[2, 2] shortPipe.flowModel.states.p (start = {5e6 for $i1 in 1:2}, min = {611.657 for $i1 in 1:2}, max = {1e8 for $i1 in 1:2}, nominal = {1e6 for $i1 in 1:2}) (79) [DISC] (1) Boolean $SEV_1 (80) [ALGB] (2) Real[2] shortPipe.flowModel.vs = {(-shortPipe.port_b.m_flow) / (shortPipe.flowModel.crossAreas[1] * ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.shortPipe.Medium.density(shortPipe.flowModel.states[1])), -shortPipe.port_b.m_flow / (ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.shortPipe.Medium.density(shortPipe.flowModel.states[2]) * shortPipe.flowModel.crossAreas[2])} / shortPipe.nParallel (81) [ALGB] (1) Real volume.medium.state.d (start = 150.0, min = 0.0, max = 1e5, nominal = 500.0) (82) [ALGB] (1) Real[1] ambient.ports.p (start = {5e6 for $i1 in 1:1}, min = {611.657 for $i1 in 1:1}, max = {1e8 for $i1 in 1:1}, nominal = {1e6 for $i1 in 1:1}) (83) [ALGB] (1) Real volume.medium.p (fixed = true, start = volume.p_start, min = 0.0, nominal = 1e5, StateSelect = prefer) (84) [ALGB] (1) Real volume.Qb_flow (85) [ALGB] (1) Real fixedMassFlowRate.medium.sat.psat (start = 5e6, min = 611.657, max = 1e8, nominal = 1e6) (86) [ALGB] (1) Real ambient.medium.d (start = 150.0, min = 0.0, max = 1e5, nominal = 500.0, StateSelect = default) (87) [ALGB] (1) Real volume.medium.state.h (start = 1e5, min = -1e10, max = 1e10, nominal = 5e5) (88) [ALGB] (1) flow Real[1] ambient.ports.m_flow (min = {-1e60}, max = {1e60}) (89) [ALGB] (4) input Real[2, 2] shortPipe.flowModel.states.h (start = {1e5 for $i1 in 1:2}, min = {-1e10 for $i1 in 1:2}, max = {1e10 for $i1 in 1:2}, nominal = {5e5 for $i1 in 1:2}) (90) [DISC] (1) Integer volume.medium.state.phase (min = 0, max = 2) (91) [ALGB] (1) Real volume.medium.u (min = -1e8, max = 1e8, nominal = 1e6) (92) [ALGB] (1) Real ambient.medium.h (StateSelect = default) (93) [ALGB] (4) input Real[2, 2] shortPipe.flowModel.states.d (start = {150.0 for $i1 in 1:2}, min = {0.0 for $i1 in 1:2}, max = {1e5 for $i1 in 1:2}, nominal = {500.0 for $i1 in 1:2}) (94) [DISC] (2) Boolean[2] $SEV_12[$i1] (95) [DER-] (1) Real $DER.volume.m (96) [ALGB] (1) Real volume.medium.state.p (start = 5e6, min = 611.657, max = 1e8, nominal = 1e6) (97) [ALGB] (1) Real ambient.medium.state.d (start = 150.0, min = 0.0, max = 1e5, nominal = 500.0) (98) [ALGB] (1) Real fixedMassFlowRate.medium.u (min = -1e8, max = 1e8, nominal = 1e6) (99) [ALGB] (2) stream Real[2] volume.ports.h_outflow (start = {1e5 for $i1 in 1:2}, min = {-1e10 for $i1 in 1:2}, max = {1e10 for $i1 in 1:2}, nominal = {5e5 for $i1 in 1:2}) (100) [ALGB] (1) Real[1] volume.heatTransfer.Ts = {ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.volume.heatTransfer.Medium.temperature(volume.heatTransfer.states[1])} (start = {288.15 for $i1 in 1:1}, min = {0.0 for $i1 in 1:1}, nominal = {300.0 for $i1 in 1:1}) (101) [DISC] (2) protected Boolean[2] volume.inFlow (start = {false for $i1 in 1:2}) (102) [ALGB] (1) Real ambient.medium.state.h (start = 1e5, min = -1e10, max = 1e10, nominal = 5e5) (103) [ALGB] (1) Real fixedMassFlowRate.medium.sat.Tsat (start = 500.0, min = 273.15, max = 2273.15, nominal = 500.0) (104) [ALGB] (1) Real[1] shortPipe.flowModel.rhos_act (start = {150.0 for $i1 in 1:1}, min = {0.0 for $i1 in 1:1}, max = {1e5 for $i1 in 1:1}, nominal = {500.0 for $i1 in 1:1}) (105) [ALGB] (1) Real fixedMassFlowRate.medium.state.p (start = 5e6, min = 611.657, max = 1e8, nominal = 1e6) (106) [ALGB] (1) Real ambient.medium.u (min = -1e8, max = 1e8, nominal = 1e6) (107) [ALGB] (1) flow Real[1] volume.heatTransfer.heatPorts.Q_flow System Equations (102/133) **************************** (1) [SCAL] (1) volume.ports[2].p = shortPipe.port_a.p ($RES_SIM_132) (2) [SCAL] (1) ambient.medium.h = ambient.state.h ($RES_SIM_15) (3) [SCAL] (1) volume.ports[1].m_flow + fixedMassFlowRate.ports[1].m_flow = 0.0 ($RES_SIM_133) (4) [SCAL] (1) fixedMassFlowRate.medium.d = fixedMassFlowRate.medium.state.d ($RES_SIM_51) (5) [SCAL] (1) 99999.99999999999 * ambient.medium.p_bar = ambient.state.p ($RES_SIM_16) (6) [SCAL] (1) fixedMassFlowRate.ports[1].p = volume.ports[1].p ($RES_SIM_134) (7) [SCAL] (1) -((-273.15) - fixedMassFlowRate.medium.T_degC) = fixedMassFlowRate.medium.state.T ($RES_SIM_52) (8) [ARRY] (2) shortPipe.flowModel.vs = {-shortPipe.port_b.m_flow / (shortPipe.flowModel.crossAreas[1] * shortPipe.flowModel.states.d), -shortPipe.port_b.m_flow / (shortPipe.flowModel.states.d * shortPipe.flowModel.crossAreas[2])} / shortPipe.nParallel ($RES_BND_147) (9) [SCAL] (1) 99999.99999999999 * fixedMassFlowRate.medium.p_bar = fixedMassFlowRate.medium.state.p ($RES_SIM_53) (10) [ARRY] (2) shortPipe.flowModel.crossAreas = {shortPipe.crossArea, shortPipe.crossArea} ($RES_BND_148) (11) [SCAL] (1) fixedMassFlowRate.medium.h = fixedMassFlowRate.medium.state.h ($RES_SIM_54) (12) [FOR-] (2) ($RES_SIM_90) (12) [----] for $i1 in 1:2 loop (12) [----] [SCAL] (1) volume.ports_E_flow[$i1] = volume.ports[$i1].m_flow * (volume.portVelocities[$i1] * 0.5 * volume.portVelocities[$i1] + system.g * volume.portsData_height[$i1]) ($RES_SIM_91) (12) [----] end for; (13) [SCAL] (1) fixedMassFlowRate.medium.u = fixedMassFlowRate.medium.h - (99999.99999999999 * fixedMassFlowRate.medium.p_bar) / fixedMassFlowRate.medium.d ($RES_SIM_56) (14) [SCAL] (1) volume.ports_H_flow[2] = smooth(0, volume.ports[2].m_flow * (if $SEV_14 then shortPipe.port_a.h_outflow else volume.ports[2].h_outflow)) ($RES_SIM_92) (15) [SCAL] (1) fixedMassFlowRate.medium.sat.psat = 99999.99999999999 * fixedMassFlowRate.medium.p_bar ($RES_SIM_57) (16) [SCAL] (1) volume.portInDensities[2] = Modelica.Media.Water.IF97_Utilities.rho_ph(volume.vessel_ps_static[2], shortPipe.port_a.h_outflow, 0, 0) ($RES_SIM_93) (17) [SCAL] (1) fixedMassFlowRate.medium.sat.Tsat = Modelica.Media.Water.IF97_Utilities.BaseIF97.Basic.tsat(99999.99999999999 * fixedMassFlowRate.medium.p_bar) ($RES_SIM_58) (18) [SCAL] (1) volume.ports_H_flow[1] = smooth(0, volume.ports[1].m_flow * (if $SEV_15 then fixedMassFlowRate.ports[1].h_outflow else volume.ports[1].h_outflow)) ($RES_SIM_94) (19) [SCAL] (1) -((-273.15) - fixedMassFlowRate.medium.T_degC) = Modelica.Media.Water.IF97_Utilities.T_props_ph(99999.99999999999 * fixedMassFlowRate.medium.p_bar, fixedMassFlowRate.medium.h, Modelica.Media.Water.IF97_Utilities.waterBaseProp_ph(99999.99999999999 * fixedMassFlowRate.medium.p_bar, fixedMassFlowRate.medium.h, 1, 0)) ($RES_SIM_59) (20) [SCAL] (1) volume.portInDensities[1] = Modelica.Media.Water.IF97_Utilities.rho_ph(volume.vessel_ps_static[1], fixedMassFlowRate.ports[1].h_outflow, 0, 0) ($RES_SIM_95) (21) [ARRY] (2) volume.portsData_height = {0.0 for $i1 in 1:2} ($RES_SIM_98) (22) [SCAL] (1) $SEV_1 = shortPipe.flowModel.m_flows[1] > 0.0 ($RES_EVT_175) (23) [SCAL] (1) $SEV_4 = (ambient.medium.h < ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.ambient.Medium.bubbleEnthalpy(ambient.medium.sat) or ambient.medium.h > ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.ambient.Medium.dewEnthalpy(ambient.medium.sat)) or ambient.medium.p > 2.2064e7 ($RES_EVT_178) (24) [SCAL] (1) $SEV_5 = abs(sum({abs(fixedMassFlowRate.ports[1].m_flow)}) - abs(fixedMassFlowRate.ports[1].m_flow)) <= 1e-60 ($RES_EVT_179) (25) [SCAL] (1) volume.Qb_flow = volume.heatTransfer.Q_flows[1] ($RES_SIM_102) (26) [SCAL] (1) volume.Hb_flow = $FUN_2 + $FUN_3 ($RES_SIM_103) (27) [ARRY] (1) shortPipe.flowModel.dheights = {shortPipe.height_ab} ($RES_BND_151) (28) [ARRY] (1) shortPipe.flowModel.pathLengths = {shortPipe.length} ($RES_BND_152) (29) [FOR-] (2) ($RES_SIM_105) (29) [----] for $i1 in 1:2 loop (29) [----] [SCAL] (1) volume.vessel_ps_static[$i1] = volume.medium.p ($RES_SIM_106) (29) [----] end for; (30) [FOR-] (2) ($RES_BND_153) (30) [----] for $i1 in 1:2 loop (30) [----] [SCAL] (1) shortPipe.flowModel.rhos[$i1] = shortPipe.flowModel.states.d ($RES_BND_154) (30) [----] end for; (31) [SCAL] (1) ambient.medium.d = ambient.medium.state.d ($RES_SIM_24) (32) [SCAL] (1) fixedMassFlowRate.medium.d = Modelica.Media.Water.IF97_Utilities.rho_props_ph(99999.99999999999 * fixedMassFlowRate.medium.p_bar, fixedMassFlowRate.medium.h, Modelica.Media.Water.IF97_Utilities.waterBaseProp_ph(99999.99999999999 * fixedMassFlowRate.medium.p_bar, fixedMassFlowRate.medium.h, 1, 0)) ($RES_SIM_60) (33) [SCAL] (1) -((-273.15) - ambient.medium.T_degC) = ambient.medium.state.T ($RES_SIM_25) (34) [FOR-] (2) ($RES_BND_155) (34) [----] for $i1 in 1:2 loop (34) [----] [SCAL] (1) shortPipe.flowModel.mus[$i1] = shortPipe.flowModel.mu_nominal ($RES_BND_156) (34) [----] end for; (35) [SCAL] (1) 99999.99999999999 * ambient.medium.p_bar = ambient.medium.state.p ($RES_SIM_26) (36) [ARRY] (1) volume.heatTransfer.Q_flows = volume.heatTransfer.heatPorts.Q_flow ($RES_SIM_108) (37) [SCAL] (1) ambient.medium.h = ambient.medium.state.h ($RES_SIM_27) (38) [ARRY] (1) volume.heatTransfer.Ts = volume.heatTransfer.heatPorts.T ($RES_SIM_109) (39) [ARRY] (5) volume.heatTransfer.states = {volume.medium.state} ($RES_BND_157) (40) [ARRY] (10) shortPipe.flowModel.states = {ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.shortPipe.Medium.ThermodynamicState(0, volume.ports[2].h_outflow, Modelica.Media.Water.IF97_Utilities.rho_ph(shortPipe.port_a.p, volume.ports[2].h_outflow, 0, 0), Modelica.Media.Water.IF97_Utilities.T_ph(shortPipe.port_a.p, volume.ports[2].h_outflow, 0, 0), shortPipe.port_a.p), ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.shortPipe.Medium.ThermodynamicState(0, ambient.ports[1].h_outflow, Modelica.Media.Water.IF97_Utilities.rho_ph(shortPipe.port_b.p, ambient.ports[1].h_outflow, 0, 0), Modelica.Media.Water.IF97_Utilities.T_ph(shortPipe.port_b.p, ambient.ports[1].h_outflow, 0, 0), shortPipe.port_b.p)} ($RES_BND_158) (41) [SCAL] (1) $DER.volume.m = volume.mb_flow ($RES_SIM_64) (42) [SCAL] (1) ambient.medium.u = ambient.medium.h - (99999.99999999999 * ambient.medium.p_bar) / ambient.medium.d ($RES_SIM_29) (43) [SCAL] (1) $DER.volume.U = volume.Qb_flow + volume.Hb_flow ($RES_SIM_65) (44) [SCAL] (1) volume.U = volume.m * volume.medium.u ($RES_SIM_66) (45) [SCAL] (1) volume.m = volume.V * volume.medium.d ($RES_SIM_67) (46) [FOR-] (2) ($RES_SIM_68) (46) [----] for $i1 in 1:2 loop (46) [----] [SCAL] (1) volume.portVelocities[$i1] = 0.0 ($RES_SIM_69) (46) [----] end for; (47) [SCAL] (1) $SEV_8 = (fixedMassFlowRate.medium.h < ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.fixedMassFlowRate.Medium.bubbleEnthalpy(fixedMassFlowRate.medium.sat) or fixedMassFlowRate.medium.h > ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.fixedMassFlowRate.Medium.dewEnthalpy(fixedMassFlowRate.medium.sat)) or fixedMassFlowRate.medium.p > 2.2064e7 ($RES_EVT_182) (48) [FOR-] (2) ($RES_EVT_183) (48) [----] for $i1 in 1:2 loop (48) [----] [SCAL] (1) $SEV_9[$i1] = 0.0 >= volume.portsData_height[$i1] ($RES_EVT_184) (48) [----] end for; (49) [FOR-] (2) ($RES_EVT_185) (49) [----] for $i1 in 1:2 loop (49) [----] [SCAL] (1) $SEV_10[$i1] = volume.s[$i1] > 0.0 ($RES_EVT_186) (49) [----] end for; (50) [FOR-] (2) ($RES_EVT_187) (50) [----] for $i1 in 1:2 loop (50) [----] [SCAL] (1) $SEV_11[$i1] = volume.portsData_height[$i1] >= volume.fluidLevel_max ($RES_EVT_188) (50) [----] end for; (51) [FOR-] (2) ($RES_EVT_189) (51) [----] for $i1 in 1:2 loop (51) [----] [SCAL] (1) $SEV_12[$i1] = $SEV_10[$i1] or $SEV_11[$i1] ($RES_EVT_190) (51) [----] end for; (52) [SCAL] (1) ambient.medium.sat.psat = 99999.99999999999 * ambient.medium.p_bar ($RES_SIM_30) (53) [SCAL] (1) ambient.medium.sat.Tsat = Modelica.Media.Water.IF97_Utilities.BaseIF97.Basic.tsat(99999.99999999999 * ambient.medium.p_bar) ($RES_SIM_31) (54) [SCAL] (1) 1 = volume.medium.state.phase ($RES_SIM_114) (55) [SCAL] (1) -((-273.15) - ambient.medium.T_degC) = Modelica.Media.Water.IF97_Utilities.T_props_ph(99999.99999999999 * ambient.medium.p_bar, ambient.medium.h, Modelica.Media.Water.IF97_Utilities.waterBaseProp_ph(99999.99999999999 * ambient.medium.p_bar, ambient.medium.h, 1, 0)) ($RES_SIM_32) (56) [SCAL] (1) volume.mb_flow = sum(volume.ports.m_flow) ($RES_$AUX_162) (57) [SCAL] (1) volume.medium.d = volume.medium.state.d ($RES_SIM_115) (58) [SCAL] (1) ambient.medium.d = Modelica.Media.Water.IF97_Utilities.rho_props_ph(99999.99999999999 * ambient.medium.p_bar, ambient.medium.h, Modelica.Media.Water.IF97_Utilities.waterBaseProp_ph(99999.99999999999 * ambient.medium.p_bar, ambient.medium.h, 1, 0)) ($RES_SIM_33) (59) [SCAL] (1) $FUN_2 = sum(volume.ports_H_flow) ($RES_$AUX_161) (60) [SCAL] (1) -((-273.15) - volume.medium.T_degC) = volume.medium.state.T ($RES_SIM_116) (61) [SCAL] (1) $FUN_3 = sum(volume.ports_E_flow) ($RES_$AUX_160) (62) [SCAL] (1) volume.medium.p = volume.medium.state.p ($RES_SIM_117) (63) [SCAL] (1) volume.medium.h = volume.medium.state.h ($RES_SIM_118) (64) [SCAL] (1) fixedMassFlowRate.ports[1].p = 99999.99999999999 * fixedMassFlowRate.medium.p_bar ($RES_SIM_37) (65) [SCAL] (1) fixedMassFlowRate.ports[1].h_outflow = fixedMassFlowRate.medium.h ($RES_SIM_38) (66) [FOR-] (2) ($RES_SIM_74) (66) [----] for $i1 in 1:2 loop (66) [----] [SCAL] (1) volume.regularFlow[$i1] = $SEV_9[$i1] ($RES_SIM_75) (66) [----] end for; (67) [FOR-] (2) ($RES_SIM_76) (67) [----] for $i1 in 1:2 loop (67) [----] [SCAL] (1) volume.inFlow[$i1] = $SEV_13[$i1] ($RES_SIM_77) (67) [----] end for; (68) [FOR-] (2) ($RES_SIM_78) (68) [----] for $i1 in 1:2 loop (68) [----] [-IF-] (1)if volume.regularFlow[$i1] then (68) [----] [----] [SCAL] (1) volume.ports[$i1].p = volume.vessel_ps_static[$i1] ($RES_SIM_80) (68) [----] [----] elseif volume.inFlow[$i1] then (68) [----] [----] [SCAL] (1) volume.ports[$i1].p = volume.vessel_ps_static[$i1] ($RES_SIM_81) (68) [----] [----] else (68) [----] [----] [SCAL] (1) volume.ports[$i1].m_flow = 0.0 ($RES_SIM_82) (68) [----] [----] end if; (68) [----] end for; (69) [FOR-] (2) ($RES_EVT_191) (69) [----] for $i1 in 1:2 loop (69) [----] [SCAL] (1) $SEV_13[$i1] = not volume.regularFlow[$i1] and $SEV_12[$i1] ($RES_EVT_192) (69) [----] end for; (70) [SCAL] (1) $SEV_14 = volume.ports[2].m_flow > 0.0 ($RES_EVT_193) (71) [SCAL] (1) $SEV_15 = volume.ports[1].m_flow > 0.0 ($RES_EVT_194) (72) [SCAL] (1) $SEV_18 = volume.medium.p >= 0.0 ($RES_EVT_197) (73) [SCAL] (1) $SEV_20 = (volume.medium.h < ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.volume.Medium.bubbleEnthalpy(volume.medium.sat) or volume.medium.h > ModelicaTest.Media.TestsWithFluid.MediaTestModels.Water.WaterIF97OnePhase_ph.volume.Medium.dewEnthalpy(volume.medium.sat)) or volume.medium.p > 2.2064e7 ($RES_EVT_199) (74) [SCAL] (1) -fixedMassFlowRate.m_flow = sum(fixedMassFlowRate.ports.m_flow) ($RES_$AUX_159) (75) [SCAL] (1) volume.medium.u = volume.medium.h - volume.medium.p / volume.medium.d ($RES_SIM_120) (76) [SCAL] (1) volume.medium.sat.psat = volume.medium.p ($RES_SIM_121) (77) [SCAL] (1) volume.medium.sat.Tsat = Modelica.Media.Water.IF97_Utilities.BaseIF97.Basic.tsat(volume.medium.p) ($RES_SIM_122) (78) [SCAL] (1) fixedMassFlowRate.medium.h = Modelica.Media.Water.IF97_Utilities.h_pT(99999.99999999999 * fixedMassFlowRate.medium.p_bar, fixedMassFlowRate.T, 0) ($RES_SIM_41) (79) [SCAL] (1) -((-273.15) - volume.medium.T_degC) = Modelica.Media.Water.IF97_Utilities.T_props_ph(volume.medium.p, volume.medium.h, Modelica.Media.Water.IF97_Utilities.waterBaseProp_ph(volume.medium.p, volume.medium.h, 1, 0)) ($RES_SIM_123) (80) [SCAL] (1) volume.medium.d = Modelica.Media.Water.IF97_Utilities.rho_props_ph(volume.medium.p, volume.medium.h, Modelica.Media.Water.IF97_Utilities.waterBaseProp_ph(volume.medium.p, volume.medium.h, 1, 0)) ($RES_SIM_124) (81) [ARRY] (1) volume.heatTransfer.Ts = {volume.heatTransfer.states.h} ($RES_BND_139) (82) [SCAL] (1) shortPipe.port_b.m_flow + ambient.ports[1].m_flow = 0.0 ($RES_SIM_128) (83) [SCAL] (1) volume.heatTransfer.heatPorts[1].Q_flow = 0.0 ($RES_SIM_129) (84) [SCAL] (1) ambient.state.h = Modelica.Media.Water.IF97_Utilities.h_pT(ambient.p, ambient.T, 0) ($RES_SIM_164) (85) [FOR-] (2) ($RES_SIM_83) (85) [----] for $i1 in 1:2 loop (85) [----] [-IF-] (1)if volume.regularFlow[$i1] then (85) [----] [----] [SCAL] (1) volume.s[$i1] = 0.0 - volume.portsData_height[$i1] ($RES_SIM_85) (85) [----] [----] elseif volume.inFlow[$i1] then (85) [----] [----] [SCAL] (1) volume.s[$i1] = volume.ports[$i1].m_flow ($RES_SIM_86) (85) [----] [----] else (85) [----] [----] [SCAL] (1) volume.s[$i1] = ((volume.ports[$i1].p - volume.vessel_ps_static[$i1]) / 101325.0) * (volume.portsData_height[$i1] - 0.0) ($RES_SIM_87) (85) [----] [----] end if; (85) [----] end for; (86) [SCAL] (1) ambient.state.p = ambient.p ($RES_SIM_167) (87) [FOR-] (2) ($RES_SIM_88) (87) [----] for $i1 in 1:2 loop (87) [----] [SCAL] (1) volume.ports[$i1].h_outflow = volume.medium.h ($RES_SIM_89) (87) [----] end for; (88) [ARRY] (1) shortPipe.flowModel.Ib_flows = {0.0} ($RES_SIM_9) (89) [ARRY] (1) shortPipe.flowModel.Fs_p = shortPipe.flowModel.nParallel * {0.5 * (shortPipe.flowModel.crossAreas[1] + shortPipe.flowModel.crossAreas[2]) * (shortPipe.flowModel.states.phase - shortPipe.flowModel.states.phase)} ($RES_SIM_8) (90) [ARRY] (1) shortPipe.flowModel.dps_fg = {(2.0 * (shortPipe.flowModel.Fs_fg[1] / shortPipe.flowModel.nParallel)) / (shortPipe.flowModel.crossAreas[1] + shortPipe.flowModel.crossAreas[2])} ($RES_SIM_7) (91) [ARRY] (1) shortPipe.flowModel.Is = {shortPipe.flowModel.m_flows[1] * shortPipe.flowModel.pathLengths[1]} ($RES_SIM_6) (92) [ARRY] (1) {0.0} = shortPipe.flowModel.Ib_flows - (shortPipe.flowModel.Fs_fg + shortPipe.flowModel.Fs_p) ($RES_SIM_5) (93) [SCAL] (1) -shortPipe.port_b.m_flow = shortPipe.flowModel.m_flows[1] ($RES_SIM_4) (94) [SCAL] (1) shortPipe.port_b.h_outflow = volume.ports[2].h_outflow - system.g * shortPipe.height_ab ($RES_SIM_2) (95) [SCAL] (1) shortPipe.port_a.h_outflow = ambient.ports[1].h_outflow + system.g * shortPipe.height_ab ($RES_SIM_1) (96) [SCAL] (1) shortPipe.flowModel.rhos_act[1] = noEvent(if $SEV_1 then shortPipe.flowModel.rhos[1] else shortPipe.flowModel.rhos[2]) ($RES_SIM_10) (97) [SCAL] (1) shortPipe.flowModel.mus_act[1] = noEvent(if $SEV_1 then shortPipe.flowModel.mus[1] else shortPipe.flowModel.mus[2]) ($RES_SIM_11) (98) [ARRY] (1) shortPipe.flowModel.dps_fg = {shortPipe.flowModel.dheights[1] * shortPipe.flowModel.g * (if $SEV_1 then shortPipe.flowModel.rhos[1] else shortPipe.flowModel.rhos[2])} + shortPipe.flowModel.dp_nominal / shortPipe.flowModel.m_flow_nominal * shortPipe.flowModel.m_flows ($RES_SIM_12) (99) [SCAL] (1) volume.ports[2].m_flow - shortPipe.port_b.m_flow = 0.0 ($RES_SIM_130) (100) [SCAL] (1) ambient.ports[1].p = 99999.99999999999 * ambient.medium.p_bar ($RES_SIM_13) (101) [SCAL] (1) shortPipe.port_b.p = ambient.ports[1].p ($RES_SIM_131) (102) [SCAL] (1) ambient.ports[1].h_outflow = ambient.medium.h ($RES_SIM_14)